Your search keyword '"Oxidoreductases metabolism"' showing total 1,269 results

1. Unraveling the genetic potential of nitrous oxide reduction in wastewater treatment: insights from metagenome-assembled genomes.

Author

Schacksen PS and Nielsen JL

Subjects

Bacteria genetics, Bacteria metabolism, Bacteria classification, Bacteria isolation & purification, Oxidation-Reduction, Oxidoreductases genetics, Oxidoreductases metabolism, Genome, Bacterial, Waste Disposal, Fluid, Denmark, Phylogeny, Nitrous Oxide metabolism, Wastewater microbiology, Metagenome

Abstract

This study explores the genetic landscape of nitrous oxide (N 2 O) reduction in wastewater treatment plants (WWTPs) by profiling 1,083 high-quality metagenome-assembled genomes (HQ MAGs) from 23 Danish full-scale WWTPs. The focus is on the distribution and diversity of nitrous oxide reductase ( nosZ ) genes and their association with other nitrogen metabolism pathways. A custom pipeline for clade-specific nosZ gene identification with higher sensitivity revealed 503 nosZ sequences in 489 of these HQ MAGs, outperforming existing Kyoto Encyclopedia of Genes and Genomes (KEGG) module-based methods. Notably, 48.7% of the total 1,083 HQ MAGs harbored nosZ genes, with clade II being predominant, accounting for 93.7% of these genes. Taxonomic profiling highlighted the prevalence of nosZ -containing taxa within Bacteroidota and Pseudomonadota. Chloroflexota exhibited unexpected affiliations with both the sec and tat secretory pathways, and all were found to contain the accessory nosB gene, underscoring the importance of investigating the secretory pathway. The majority of non-denitrifying N 2 O reducers were found within Bacteroidota and Chloroflexota . Additionally, HQ MAGs with genes for dissimilatory nitrate reduction to ammonium and assimilatory nitrate reduction frequently co-occurred with the nosZ gene. Traditional primers targeting nosZ often focus on short-length amplicons. Therefore, we introduced custom-designed primer sets targeting near-full-length nosZ sequences. These new primers demonstrate efficacy in capturing diverse and well-characterized sequences, providing a valuable tool with higher resolution for future research. In conclusion, this comprehensive analysis enhances our understanding of N 2 O-reducing organisms in WWTPs, highlighting their potential as N 2 O sinks with the potential for optimizing wastewater treatment processes and mitigating greenhouse gas emissions., Importance: This study provides critical insights into the genetic diversity of nitrous oxide reductase (nosZ) genes and the microorganisms harboring them in wastewater treatment plants (WWTPs) by exploring 1,083 high-quality metagenome-assembled genomes (MAGs) from 23 Danish full-scale WWTPs. Despite the pivotal role of nosZ-containing organisms, their diversity remains largely unexplored in WWTPs. Our custom pipeline for detecting nosZ provides near-full-length genes with detailed information on secretory pathways and accessory nos genes. Using these genes as templates, we developed taxonomically diverse clade-specific primers that generate nosZ amplicons for phylogenetic annotation and gene-to-MAG linkage. This approach improves detection and expands the discovery of novel sequences, highlighting the prevalence of non-denitrifying N 2 O reducers and their potential as N 2 O sinks. These findings have the potential to optimize nitrogen removal processes and mitigate greenhouse gas emissions from WWTPs by fully harnessing the capabilities of the microbial communities., Competing Interests: The authors declare no conflict of interest.

Published

2024

2. Clostridioides difficile superoxide reductase mitigates oxygen sensitivity.

Author

Kochanowsky R, Carothers K, Roxas BAP, Anwar F, Viswanathan VK, and Vedantam G

Subjects

Bacterial Proteins metabolism, Bacterial Proteins genetics, Oxidoreductases metabolism, Oxidoreductases genetics, Gene Expression Regulation, Bacterial, Clostridioides difficile genetics, Clostridioides difficile enzymology, Clostridioides difficile metabolism, Oxidative Stress, Oxygen metabolism, Superoxides metabolism

Abstract

Clostridioides difficile causes a serious diarrheal disease and is a common healthcare-associated bacterial pathogen. Although it has a major impact on human health, the mechanistic details of C. difficile intestinal colonization remain undefined. C. difficile is highly sensitive to oxygen and requires anaerobic conditions for in vitro growth. However, the mammalian gut is not devoid of oxygen, and C. difficile tolerates moderate oxidative stress in vivo . The C. difficile genome encodes several antioxidant proteins, including a predicted superoxide reductase (SOR) that is upregulated upon exposure to antimicrobial peptides. The goal of this study was to establish SOR enzymatic activity and assess its role in protecting C. difficile against oxygen exposure. Insertional inactivation of sor rendered C. difficile more sensitive to superoxide, indicating that SOR contributes to antioxidant defense. Heterologous C. difficile sor expression in Escherichia coli conferred protection against superoxide-dependent growth inhibition, and the corresponding cell lysates showed superoxide scavenging activity. Finally, a C. difficile SOR mutant exhibited global proteome changes under oxygen stress when compared to the parent strain. Collectively, our data establish the enzymatic activity of C. difficile SOR, confirm its role in protection against oxidative stress, and demonstrate SOR's broader impacts on the C. difficile vegetative cell proteome.IMPORTANCE Clostridioides difficile is an important pathogen strongly associated with healthcare settings and capable of causing severe diarrheal disease. While considered a strict anaerobe in vitro , C. difficile has been shown to tolerate low levels of oxygen in the mammalian host. Among other well-characterized antioxidant proteins, the C. difficile genome encodes a predicted superoxide reductase (SOR), an understudied component of antioxidant defense in pathogens. The significance of the research reported herein is the characterization of SOR's enzymatic activity, including confirmation of its role in protecting C. difficile against oxidative stress. This furthers our understanding of C. difficile pathogenesis and presents a potential new avenue for targeted therapies., Competing Interests: The authors declare no conflict of interest.

Published

2024

3. Expansion of Auxiliary Activity Family 5 sequence space via biochemical characterization of six new copper radical oxidases.

Author

Fong JK, Mathieu Y, Vo MT, Bellemare A, Tsang A, and Brumer H

Subjects

Saccharomycetales genetics, Saccharomycetales enzymology, Substrate Specificity, Fungal Proteins genetics, Fungal Proteins metabolism, Fungal Proteins chemistry, Alcohol Oxidoreductases genetics, Alcohol Oxidoreductases metabolism, Alcohol Oxidoreductases chemistry, Galactose Oxidase genetics, Galactose Oxidase metabolism, Galactose Oxidase chemistry, Sequence Alignment, Amino Acid Sequence, Recombinant Proteins genetics, Recombinant Proteins metabolism, Recombinant Proteins chemistry, Catalytic Domain, Phylogeny, Oxidoreductases genetics, Oxidoreductases metabolism, Oxidoreductases chemistry, Copper metabolism

Abstract

Bacterial and fungal copper radical oxidases (CROs) from Auxiliary Activity Family 5 (AA5) are implicated in morphogenesis and pathogenesis. The unique catalytic properties of CROs also make these enzymes attractive biocatalysts for the transformation of small molecules and biopolymers. Despite a recent increase in the number of characterized AA5 members, especially from subfamily 2 (AA5_2), the catalytic diversity of the family as a whole remains underexplored. In the present study, phylogenetic analysis guided the selection of six AA5_2 members from diverse fungi for recombinant expression in Komagataella pfaffii (syn. Pichia pastoris ) and biochemical characterization in vitro . Five of the targets displayed predominant galactose 6-oxidase activity (EC 1.1.3.9), and one was a broad-specificity aryl alcohol oxidase (EC 1.1.3.7) with maximum activity on the platform chemical 5-hydroxymethyl furfural (EC 1.1.3.47). Sequence alignment comparing previously characterized AA5_2 members to those from this study indicated various amino acid substitutions at active site positions implicated in the modulation of specificity.IMPORTANCEEnzyme discovery and characterization underpin advances in microbial biology and the application of biocatalysts in industrial processes. On one hand, oxidative processes are central to fungal saprotrophy and pathogenesis. On the other hand, controlled oxidation of small molecules and (bio)polymers valorizes these compounds and introduces versatile functional groups for further modification. The biochemical characterization of six new copper radical oxidases further illuminates the catalytic diversity of these enzymes, which will inform future biological studies and biotechnological applications., Competing Interests: The authors declare no conflict of interest.

Published

2024

4. Physiological and transcriptomic response to methyl-coenzyme M reductase limitation in Methanosarcina acetivorans .

Author

Chadwick GL, Dury GA, and Nayak DD

Subjects

Methane metabolism, Archaeal Proteins genetics, Archaeal Proteins metabolism, Gene Expression Regulation, Archaeal, Operon, Methanosarcina genetics, Methanosarcina enzymology, Methanosarcina metabolism, Oxidoreductases metabolism, Oxidoreductases genetics, Transcriptome

Abstract

Methyl-coenzyme M reductase (MCR) catalyzes the final step of methanogenesis, the microbial metabolism responsible for nearly all biological methane emissions to the atmosphere. Decades of biochemical and structural research studies have generated detailed insights into MCR function in vitro , yet very little is known about the interplay between MCR and methanogen physiology. For instance, while it is routinely stated that MCR catalyzes the rate-limiting step of methanogenesis, this has not been categorically tested. In this study, to gain a more direct understanding of MCR's control on the growth of Methanosarcina acetivorans, we generate a strain with an inducible mcr operon on the chromosome, allowing for careful control of MCR expression. We show that MCR is not growth rate-limiting in substrate-replete batch cultures. However, through careful titration of MCR expression, growth-limiting state(s) can be obtained. Transcriptomic analysis of M. acetivorans experiencing MCR limitation reveals a global response with hundreds of differentially expressed genes across diverse functional categories. Notably, MCR limitation leads to strong induction of methylsulfide methyltransferases, likely due to insufficient recycling of metabolic intermediates. In addition, the mcr operon is not transcriptionally regulated, i.e., it is constitutively expressed, suggesting that the overabundance of MCR might be beneficial when cells experience nutrient limitation or stressful conditions. Altogether, we show that there is a wide range of cellular MCR concentrations that can sustain optimal growth, suggesting that other factors such as anabolic reactions might be rate-limiting for methanogenic growth., Importance: Methane is a potent greenhouse gas that has contributed to ca. 25% of global warming in the post-industrial era. Atmospheric methane is primarily of biogenic origin, mostly produced by microorganisms called methanogens. Methyl-coenzyme M reductase (MCR) catalyzes methane formatio in methanogens. Even though MCR comprises ca. 10% of the cellular proteome, it is hypothesized to be growth-limiting during methanogenesis. In this study, we show that Methanosarcina acetivorans cells grown in substrate-replicate batch cultures produce more MCR than its cellular demand for optimal growth. The tools outlined in this study can be used to refine metabolic models of methanogenesis and assay lesions in MCR in a higher-throughput manner than isolation and biochemical characterization of pure protein., Competing Interests: The authors declare no conflict of interest.

Published

2024

5. Functional characterization of a novel flavin reductase from a deep-sea sediment metagenomic library and its application for indirubin production.

Author

Du J, Li Y, Chen Z, Wang C, Huang Y, and Li L

Subjects

Geologic Sediments microbiology, Metagenomics, Bacterial Proteins genetics, Bacterial Proteins metabolism, Metagenome, Gene Library, Oxidoreductases genetics, Oxidoreductases metabolism, Indoles metabolism, Escherichia coli genetics, Escherichia coli metabolism, FMN Reductase metabolism, FMN Reductase genetics

Abstract

Microbial synthesis is a desirable approach to produce indirubin but suffers from low synthetic efficiency. Insufficient supply of reduced flavins is one major factor limiting synthetic efficiency. To address this, a novel flavin reductase, MoxB, was discovered through screening of the metagenomic library. MoxB showed a strong preference for NADH over NADPH as the electron source for FMN/FAD reduction and exhibited the highest activity at pH 8.0 and 30°C. It displayed remarkable thermostability by maintaining 80% of full activity after incubation at 60°C for 1 h. Furthermore, MoxB showed great organic solvent tolerance and its activity could be significantly increased by bivalent metal ions. In addition, heterologous expression of the moxB gene in the indirubin-producing E. coli significantly improved indirubin production up to 15.12-fold. This discovery expands the understanding of flavin reductases and provides a promising catalytic tool for microbial indirubin production.IMPORTANCEMuch effort has been exerted to produce indirubin using engineered Escherichia coli , but high-level production has not been achieved so far. Insufficient supply of reduced flavins is one key factor limiting the catalytic efficiency. However, the flavin reductases involved in indirubin biosynthesis have not been hitherto reported. Discovery of the novel flavin reductase MoxB provides a useful tool for enhancing indirubin production by E. coli . Overexpression of MoxB in indirubin-producing E. coli increased indirubin production by 15.12-fold in comparison to the control strain. Our results document the function of flavin reductase that reduces flavins during indirubin biosynthesis and provide an important foundation for using the flavin reductases to improve indirubin production by engineered microorganisms., Competing Interests: The authors declare no conflict of interests.

Published

2024

6. The novel regulator HdrR controls the transcription of the heterodisulfide reductase operon hdrBCA in Methanosarcina barkeri .

Author

Zhang S, Chen Y, Wang S, Yang Q, Leng H, Zhao P, Guo L, Dai L, Bai L, and Cha G

Subjects

Gene Expression Regulation, Archaeal, Transcription, Genetic, Methane metabolism, Methanol metabolism, Carbon Dioxide metabolism, Acetates metabolism, Hydrogen metabolism, Methanosarcina barkeri genetics, Methanosarcina barkeri metabolism, Operon, Oxidoreductases genetics, Oxidoreductases metabolism, Archaeal Proteins genetics, Archaeal Proteins metabolism

Abstract

Methanogenic archaea play a key role in the global carbon cycle because these microorganisms remineralize organic compounds in various anaerobic environments. The microorganism Methanosarcina barkeri is a metabolically versatile methanogen, which can utilize acetate, methanol, and H 2 /CO 2 to synthesize methane. However, the regulatory mechanisms underlying methanogenesis for different substrates remain unknown. In this study, RNA-seq analysis was used to investigate M. barkeri growth and gene transcription under different substrate regimes. According to the results, M. barkeri showed the best growth under methanol, followed by H 2 /CO 2 and acetate, and these findings corresponded well with the observed variations in genes transcription abundance for different substrates. In addition, we identified a novel regulator, MSBRM_RS03855 (designated as HdrR), which specifically activates the transcription of the heterodisulfide reductase hdrBCA operon in M. barkeri . HdrR was able to bind to the hdrBCA operon promoter to regulate transcription. Furthermore, the structural model analyses revealed a helix-turn-helix domain, which is likely involved in DNA binding. Taken together, HdrR serves as a model to reveal how certain regulatory factors control the expression of key enzymes in the methanogenic pathway.IMPORTANCEThe microorganism Methanosarcina barkeri has a pivotal role in the global carbon cycle and contributes to global temperature homeostasis. The consequences of biological methanogenesis are far-reaching, including impacts on atmospheric methane and CO 2 concentrations, agriculture, energy production, waste treatment, and human health. As such, reducing methane emissions is crucial to meeting set climate goals. The methanogenic activity of certain microorganisms can be drastically reduced by inhibiting the transcription of the hdrBCA operon, which encodes heterodisulfide reductases. Here, we provide novel insight into the mechanisms regulating hdrBCA operon transcription in the model methanogen M. barkeri . The results clarified that HdrR serves as a regulator of heterodisulfide reductase hdrBCA operon transcription during methanogenesis, which expands our understanding of the unique regulatory mechanisms that govern methanogenesis. The findings presented in this study can further our understanding of how genetic regulation can effectively reduce the methane emissions caused by methanogens., Competing Interests: The authors declare no conflict of interest.

Published

2024

7. A gold speciation that adds a second layer to synergistic gold-copper toxicity in Cupriavidus metallidurans .

Author

Hirth N, Wiesemann N, Krüger S, Gerlach M-S, Preußner K, Galea D, Herzberg M, Große C, and Nies DH

Subjects

Copper metabolism, Gold toxicity, Gold metabolism, Bacterial Proteins metabolism, Ions metabolism, Soil, Glutathione metabolism, Oxidoreductases metabolism, Metal Nanoparticles toxicity, Metal Nanoparticles chemistry, Cupriavidus genetics, Cupriavidus metabolism

Abstract

The metal-resistant bacterium Cupriavidus metallidurans occurs in metal-rich environments. In auriferous soils, the bacterium is challenged by a mixture of copper ions and gold complexes, which exert synergistic toxicity. The previously used, self-made Au(III) solution caused a synergistic toxicity of copper and gold that was based on the inhibition of the CupA-mediated efflux of cytoplasmic Cu(I) by Au(I) in this cellular compartment. In this publication, the response of the bacterium to gold and copper was investigated by using a commercially available Au(III) solution instead of the self-made solution. The new solution was five times more toxic than the previously used one. Increased toxicity was accompanied by greater accumulation of gold atoms by the cells. The contribution of copper resistance determinants to the commercially available Au(III) solution and synergistic gold-copper toxicity was studied using single- and multiple-deletion mutants. The commercially available Au(III) solution inhibited periplasmic Cu(I) homeostasis, which is required for the allocation of copper ions to copper-dependent proteins in this compartment. The presence of the gene for the periplasmic Cu(I) and Au(I) oxidase, CopA, decreased the cellular copper and gold content. Transcriptional reporter gene fusions showed that up-regulation of gig , encoding a minor contributor to copper resistance, was strictly glutathione dependent. Glutathione was also required to resist synergistic gold-copper toxicity. The new data indicated a second layer of synergistic copper-gold toxicity caused by the commercial Au(III) solution, inhibition of the periplasmic copper homeostasis in addition to the cytoplasmic one.IMPORTANCEWhen living in auriferous soils, Cupriavidus metallidurans is not only confronted with synergistic toxicity of copper ions and gold complexes but also by different gold species. A previously used gold solution made by using aqua regia resulted in the formation of periplasmic gold nanoparticles, and the cells were protected against gold toxicity by the periplasmic Cu(I) and Au(I) oxidase CopA. To understand the role of different gold species in the environment, another Au(III) solution was commercially acquired. This compound was more toxic due to a higher accumulation of gold atoms by the cells and inhibition of periplasmic Cu(I) homeostasis. Thus, the geo-biochemical conditions might influence Au(III) speciation. The resulting Au(III) species may subsequently interact in different ways with C. metallidurans and its copper homeostasis system in the cytoplasm and periplasm. This study reveals that the geochemical conditions may decide whether bacteria are able to form gold nanoparticles or not., Competing Interests: The authors declare no conflict of interest.

Published

2024

8. Exploring functional genes' correlation with ( S )-equol concentration and new daidzein racemase identification.

Author

Hu Y-F, Luo S, Wang S-Q, Chen K-X, Zhong W-X, Li B-Y, Cao L-Y, Chen H-H, and Yin Y-S

Subjects

Animals, Humans, Mice, Rats, Swine, Racemases and Epimerases, Chickens metabolism, Oxidoreductases metabolism, Equol genetics, Equol metabolism, Isoflavones metabolism

Abstract

With its estrogenic activity, ( S )-equol plays an important role in maintaining host health and preventing estrogen-related diseases. Exclusive production occurs through the transformation of soy isoflavones by intestinal bacteria, but the reasons for variations in ( S )-equol production among different individuals and species remain unclear. Here, fecal samples from humans, pigs, chickens, mice, and rats were used as research objects. The concentrations of ( S )-equol, along with the genetic homology and evolutionary relationships of ( S )-equol production-related genes [daidzein reductase (DZNR), daidzein racemase (DDRC), dihydrodaidzein reductase (DHDR), tetrahydrodaidzein reductase (THDR)], were analyzed. Additionally, in vitro functional verification of the newly identified DDRC gene was conducted. It was found that approximately 40% of human samples contained ( S )-equol, whereas 100% of samples from other species contained ( S )-equol. However, there were significant variations in ( S)- equol content among the different species: rats > pigs > chickens > mice > humans. The distributions of the four genes displayed species-specific patterns. High detection rates across various species were exhibited by DHDR , THDR , and DDRC . In contrast, substantial variations in detection rates among different species and individuals were observed with respect to DZNR . It appears that various types of DZNR may be associated with different concentrations of ( S)- equol, which potentially correspond to the regulatory role during ( S)- equol synthesis. This enhances our understanding of individual variations in ( S )-equol production and their connection with functional genes in vitro . Moreover, the newly identified DDRC exhibits higher potential for ( S)- equol synthesis compared to the known DDRC, providing valuable resources for advancing in vitro ( S)- equol production., Importance: ( S )-equol (( S )-EQ) plays a crucial role in maintaining human health, along with its known capacity to prevent and treat various diseases, including cardiovascular diseases, metabolic syndromes, osteoporosis, diabetes, brain-related diseases, high blood pressure, hyperlipidemia, obesity, and inflammation. However, factors affecting individual variations in ( S )-EQ production and the underlying regulatory mechanisms remain elusive. This study examines the association between functional genes and ( S )-EQ production, highlighting a potential correlation between the DZNR gene and ( S )-EQ content. Various types of DZNR may be linked to the regulation of ( S )-EQ synthesis. Furthermore, the identification of a new DDRC gene offers promising prospects for enhancing in vitro ( S )-EQ production., Competing Interests: The authors declare no conflict of interest.

Published

2024

9. Identification of bacterial dissimilatory antimonate reductase AnrA: genes and proteins involved in antimonate respiration and resistance in Geobacter sp. strain SVR.

Author

Kambara R, Yamamura S, and Amachi S

Subjects

Dimethyl Sulfoxide metabolism, Proteomics, Bacteria genetics, Oxidoreductases genetics, Oxidoreductases metabolism, Oxidation-Reduction, Respiration, Antimony pharmacology, Geobacter genetics, Geobacter metabolism

Abstract

Geobacter sp. strain SVR uses antimonate [Sb(V)] as a terminal electron acceptor for anaerobic respiration. Here, we visualized a possible key enzyme, periplasmic Sb(V) reductase (Anr), via active staining and non-denaturing gel electrophoresis. Liquid chromatography-tandem mass spectrometry analysis revealed that a novel dimethyl sulfoxide (DMSO) reductase family protein, WP_173201954.1, is involved in Anr. This protein was closely related with AnrA, a protein suggested to be the catalytic subunit of a respiratory Sb(V) reductase in Desulfuribacillus stibiiarsenatis . The anr genes of strain SVR ( anrXSRBAD ) formed an operon-like structure, and their transcription was upregulated under Sb(V)-respiring conditions. The expression of anrA gene was induced by more than 1 µM of antimonite [Sb(III)]; however, arsenite [As(III)] did not induce the expression of anrA gene. Tandem mass tag-based proteomic analysis revealed that, in addition to Anr proteins, proteins in the following categories were upregulated under Sb(V)-respiring conditions: (i) Sb(III) efflux systems such as Ant and Ars; (ii) antioxidizing proteins such as ferritin, rubredoxin, and thioredoxin; (iii) protein quality control systems such as HspA, HslO, and DnaK; and (iv) DNA repair proteins such as UspA and UvrB. These results suggest that strain SVR copes with antimony stress by modulating pleiotropic processes to resist and actively metabolize antimony. To the best of our knowledge, this is the first report to demonstrate the involvement of AnrA in Sb(V) respiration at the protein level. Furthermore, this is the first example to show high expression of the Ant system proteins in the Sb(V)-respiring bacterium.IMPORTANCEAntimony (Sb) exists mainly as antimonite [Sb(III)] or antimonate [Sb(V)] in the environment, and Sb(III) is more toxic than Sb(V). Recently, microbial involvement in Sb redox reactions has received attention. Although more than 90 Sb(III)-oxidizing bacteria have been reported, information on Sb(V)-reducing bacteria is limited. Especially, the enzyme involved in dissimilatory Sb(V) reduction, or Sb(V) respiration, is unclear, despite this pathway being very important for the circulation of Sb in nature. In this study, we demonstrated that the Sb(V) reductase (Anr) of an Sb(V)-respiring bacterium ( Geobacter sp. SVR) is a novel member of the dimethyl sulfoxide (DMSO) reductase family. In addition, we found that strain SVR copes with Sb stress by modulating pleiotropic processes, including the Ant and Ars systems, and upregulating the antioxidant and quality control protein levels. Considering the abundance and diversity of putative anr genes in the environment, Anr may play a significant role in global Sb cycling in both marine and terrestrial environments., Competing Interests: The authors declare no conflict of interest.

Published

2024

10. Rhodobacteraceae methanethiol oxidases catalyze methanethiol degradation to produce sulfane sulfur other than hydrogen sulfide.

Author

Cao Q, Liu X, Wang Q, Liu Z, Xia Y, Xun L, and Liu H

Subjects

Cysteine, Hydrogen Peroxide, Sulfur metabolism, Sulfur Compounds, Oxidoreductases metabolism, Hydrogen Sulfide, Rhodobacteraceae metabolism, Sulfhydryl Compounds, Sulfonium Compounds

Abstract

Methanethiol (MT) is a sulfur-containing compound produced during dimethylsulfoniopropionate (DMSP) degradation by marine bacteria. The C-S bond of MT can be cleaved by methanethiol oxidases (MTOs) to release a sulfur atom. However, the cleaving process remains unclear, and the species of sulfur product is uncertain. It has long been assumed that MTOs produce hydrogen sulfide (H 2 S) from MT. Herein, we studied the MTOs in the Rhodobacteraceae family-whose members are important DMSP degraders ubiquitous in marine environments. We identified 57 MTOs from 1,904 Rhodobacteraceae genomes. These MTOs were grouped into two major clusters. Cluster 1 members share three conserved cysteine residues, while cluster 2 members contain one conserved cysteine residue. We examined the products of three representative MTOs both in vitro and in vivo . All of them produced sulfane sulfur other than H 2 S from MT. Their conserved cysteines are substrate-binding sites in which the MTO-S-S-CH 3 complex is formed. This finding clarified the sulfur product of MTOs and enlightened the MTO-catalyzing process. Moreover, this study connected DMSP degradation with sulfane sulfur metabolism, filling a critical gap in the DMSP degradation pathway and representing new knowledge in the marine sulfur cycle field., Importance: This study overthrows a long-time assumption that methanethiol oxidases (MTOs) cleave the C-S bond of methanethiol to produce both H 2 S and H 2 O 2 -the former is a strong reductant and the latter is a strong oxidant. From a chemistry viewpoint, this reaction is difficult to happen. Investigations on three representative MTOs indicated that sulfane sulfur (S 0 ) was the direct product, and no H 2 O 2 was produced. Finally, the products of MTOs were corrected to be S 0 and H 2 O. This finding connected dimethylsulfoniopropionate (DMSP) degradation with sulfane sulfur metabolism, filling a critical gap in the DMSP degradation pathway and representing new knowledge in the marine sulfur cycle field., Competing Interests: The authors declare no conflict of interest.

Published

2024

11. Functional characterization of the dbu locus for D-branched-chain amino acid catabolism in Pseudomonas putida .

Author

Fulton RL and Downs DM

Subjects

Amino Acids, Branched-Chain metabolism, Oxidoreductases metabolism, Amino Acids metabolism, Arginine metabolism, Pseudomonas putida genetics, Pseudomonas putida metabolism

Abstract

Pseudomonas putida is a metabolically robust soil bacterium that employs a diverse set of pathways to utilize a wide range of nutrients. The versatility of this microorganism contributes to both its environmental ubiquity and its rising popularity as a bioengineering chassis. In P. putida , the newly named dbu locus encodes a transcriptional regulator (DbuR), D-amino acid oxidase (DbuA), Rid2 protein (DbuB), and a putative transporter (DbuC). Current annotation implicates this locus in the utilization of D-arginine. However, data obtained in this study showed that genes in the dbu locus are not required for D-arginine utilization, but, rather, this locus is involved in the catabolism of multiple D-branched-chain amino acids (D-BCAA). The oxidase DbuA was required for catabolism of each D-BCAA and D-phenylalanine, while the requirements for DbuC and DbuB were less stringent. The functional characterization of the dbu locus contributes to our understanding of the metabolic network of P. putida and proposes divergence in function between proteins annotated as D-arginine oxidases across the Pseudomonas genus.IMPORTANCE Pseudomonas putida is a non-pathogenic bacterium that is broadly utilized as a host for bioengineering and bioremediation efforts. The popularity of P. putida as a chassis for such efforts is attributable to its physiological versatility and ability to metabolize a wide variety of compounds. Pathways for L-amino acid metabolism in this microbe have been rather well studied, primarily because of their relevance to efforts in foundational physiology research, as well as the commercial production of economically pertinent compounds. However, comparatively little is known about the metabolism of D-amino acids despite evidence showing the ability of P. putida to metabolize these enantiomers. In this work, we characterize the D-BCAA catabolic pathway of P. putida and its integration with the essential L-BCAA biosynthetic pathway. This work expands our understanding of the metabolic network of Pseudomonas putida , which has potential applications in efforts to model and engineer the metabolic network of this organism., Competing Interests: The authors declare that there are no conflicts of interest.

Published

2024

12. The critical roles of propanethiol oxidoreductase and sulfide-quinone oxidoreductase in the propanethiol catabolism pathway in Pseudomonas putida S-1.

Author

Qiao P, Ning L, Chen J, Tang Y, Zhao R, Chen G, Ye Q, Zhou T, Chen J, and Zhong W

Subjects

Humans, Hydrogen Peroxide metabolism, Sulfhydryl Compounds metabolism, Biodegradation, Environmental, Sulfur metabolism, Carbon metabolism, Oxidoreductases metabolism, Pseudomonas putida genetics, Pseudomonas putida metabolism, Quinone Reductases

Abstract

Propanethiol (PT) is a hazardous pollutant that poses risks to both the environment and human well-being. Pseudomonas putida S-1 has been identified as a microorganism capable of utilizing PT as its sole carbon source. However, the metabolic pathway responsible for PT degradation in P. putida S-1 has remained poorly understood, impeding its optimization and practical application. In this study, we investigated the catabolic network involved in PT desulfurization with P. putida S-1 and identified key gene modules crucial to this process. Notably, propanethiol oxidoreductase (PTO) catalyzes the initial degradation of PT, a pivotal step for P. putida S-1's survival on PT. PTO facilitates the oxidation of PT, resulting H 2 S, H 2 O 2 , and propionaldehyde (PA). Catalase-peroxidase catalyzes the conversion of H 2 O 2 to oxygen and water, while PA undergoes gradual conversion to Succinyl-CoA, which is subsequently utilized in the tricarboxylic acid cycle. H 2 S is digested in a comprehensive desulfurization network where sulfide-quinone oxidoreductase (SQOR) predominantly converts it to sulfane sulfur. The transcriptome analysis suggests that sulfur can be finally converted to sulfite or sulfate and exported out of the cell. The PT degradation capacity of P. putida S-1 was enhanced by increasing the transcription level of PTO and SQOR genes in vivo .IMPORTANCEThis work investigated the PT catabolism pathway in Pseudomonas putida S-1, a microorganism capable of utilizing PT as the sole carbon source. Critical genes that control the initiation of PT degradation were identified and characterized, such as pto and sqor . By increasing the transcription level of pto and sqor genes in vivo , we have successfully enhanced the PT degradation efficiency and growth rate of P. putida S-1. This work does not only reveal a unique PT degradation pathway but also highlights the potential of enhancing the microbial desulfurization process in the bioremediation of thiol-contaminated environment., Competing Interests: The authors declare no conflict of interest.

Published

2024

13. Marinomonas mediterranea synthesizes an R-type bacteriocin.

Author

Lucas-Elío P, ElAlami T, Martínez A, and Sanchez-Amat A

Subjects

Oxidoreductases metabolism, Marinomonas genetics, Marinomonas metabolism, Bacteriocins metabolism, Anti-Infective Agents

Abstract

Prophages integrated into bacterial genomes can become cryptic or defective prophages, which may evolve to provide various traits to bacterial cells. Previous research on Marinomonas mediterranea MMB-1 demonstrated the production of defective particles. In this study, an analysis of the genomes of three different strains (MMB-1, MMB-2, and MMB-3) revealed the presence of a region named MEDPRO1, spanning approximately 52 kb, coding for a defective prophage in strains MMB-1 and MMB-2. This prophage seems to have been lost in strain MMB-3, possibly due to the presence of spacers recognizing this region in an I-F CRISPR array in this strain. However, all three strains produce remarkably similar defective particles. Using strain MMB-1 as a model, mass spectrometry analyses indicated that the structural proteins of the defective particles are encoded by a second defective prophage situated within the MEDPRO2 region, spanning approximately 13 kb. This finding was further validated through the deletion of this second defective prophage. Genomic region analyses and the detection of antimicrobial activity of the defective prophage against other Marinomonas species suggest that it is an R-type bacteriocin. Marinomonas mediterranea synthesizes antimicrobial proteins with lysine oxidase activity, and the synthesis of an R-type bacteriocin constitutes an additional mechanism in microbial competition for the colonization of habitats such as the surface of marine plants.IMPORTANCEThe interactions between bacterial strains inhabiting the same environment determine the final composition of the microbiome. In this study, it is shown that some extracellular defective phage particles previously observed in Marinomonas mediterranea are in fact R-type bacteriocins showing antimicrobial activity against other Marinomonas strains. The operon coding for the R-type bacteriocin has been identified., Competing Interests: The authors declare no conflict of interest.

Published

2024

14. Evolution and separation of actinobacterial pyranose and C -glycoside-3-oxidases.

Author

Kostelac A, Taborda A, Martins LO, and Haltrich D

Subjects

Phylogeny, Monosaccharides, Glucose metabolism, Oxidoreductases metabolism, Glycosides

Abstract

FAD-dependent pyranose oxidase (POx) and C -glycoside-3-oxidase (CGOx) are both members of the glucose-methanol-choline superfamily of oxidoreductases and belong to the same sequence space. Pyranose oxidases had been studied for their oxidation of monosaccharides such as D-glucose, but recently, a bacterial C -glycoside-3-oxidase that is phylogenetically related to POx and that reacts with C -glycosides such as carminic acid, mangiferin or puerarin has been described. Since these actinobacterial CGOx enzymes belong to the same sequence space as bacterial POx, they must have evolved from the same ancestor. Here, we performed a phylogenetic analysis of actinobacterial sequences and resurrected seven ancestral enzymes of the POx/CGOx sequence space to study the evolutionary trajectory of substrate preferences for monosaccharides and C -glycosides. Clade I, with its dimeric member POx from Kitasatospora aureofaciens , shows strict preference for monosaccharides (D-glucose and D-xylose) and does not react with any of the glycosides tested. No extant member of clade II has been studied to date. The two extant members of clades III and IV, monomeric POx/CGOx from Pseudoarthrobacter siccitolerans and Streptomyces canus , oxidized both monosaccharides as well as various C -glycosides (homoorientin, isovitexin, mangiferin, and puerarin). Steady-state kinetic parameters of several clades III and IV ancestral enzymes indicate that the generalist ancestor N35 slowly evolved to present-day enzymes with a much higher preference for C -glycosides than monosaccharides. Based on structural predictions of ancestors, we hypothesize that the strict specificity of bacterial clade I POx (and also fungal POx) is the result of oligomerization, which in turn results from the evolution of protein segments that were shown to be important for oligomerization, the arm, and the head domain.IMPORTANCE C -Glycosides often form active compounds in various plants. Breakage of the C-C bond in these glycosides to release the aglycone is challenging and proceeds via a two-step reaction, the oxidation of the sugar and subsequent cleavage of the C-C bond. Recently, an enzyme from a soil bacterium, FAD-dependent C -glycoside-3-oxidase (CGOx), was shown to catalyze the initial oxidation reaction. Here, we show that CGOx belongs to the same sequence space as pyranose oxidase (POx), and that an actinobacterial ancestor of the POx/CGOx family evolved into four clades, two of which show a high preference for C -glycosides., Competing Interests: The authors declare no conflict of interest.

Published

2024

15. Nitrous oxide reduction by two partial denitrifying bacteria requires denitrification intermediates that cannot be respired.

Author

LaSarre B, Morlen R, Neumann GC, Harwood CS, and McKinlay JB

Subjects

Denitrification, Nitrates metabolism, Nitrogen Dioxide metabolism, Nitrogen Dioxide pharmacology, Bacteria genetics, Nitric Oxide metabolism, Oxidoreductases metabolism, Nitrous Oxide metabolism, Greenhouse Gases metabolism

Abstract

Denitrification is a form of anaerobic respiration wherein nitrate (NO 3 - ) is sequentially reduced via nitrite (NO 2 - ), nitric oxide, and nitrous oxide (N 2 O) to dinitrogen gas (N 2 ) by four reductase enzymes. Partial denitrifying bacteria possess only one or some of these four reductases and use them as independent respiratory modules. However, it is unclear if partial denitrifiers sense and respond to denitrification intermediates outside of their reductase repertoire. Here, we tested the denitrifying capabilities of two purple nonsulfur bacteria, Rhodopseudomonas palustris CGA0092 and Rhodobacter capsulatus SB1003. Each had denitrifying capabilities that matched their genome annotation; CGA0092 reduced NO 2 - to N 2 , and SB1003 reduced N 2 O to N 2 . For each bacterium, N 2 O reduction could be used both for electron balance during growth on electron-rich organic compounds in light and for energy transformation via respiration in darkness. However, N 2 O reduction required supplementation with a denitrification intermediate, including those for which there was no associated denitrification enzyme. For CGA0092, NO 3 - served as a stable, non-catalyzable molecule that was sufficient to activate N 2 O reduction. Using a β-galactosidase reporter, we found that NO 3 - acted, at least in part, by stimulating N 2 O reductase gene expression. In SB1003, NO 2 - but not NO 3 - activated N 2 O reduction, but NO 2 - was slowly removed, likely by a promiscuous enzyme activity. Our findings reveal that partial denitrifiers can still be subject to regulation by denitrification intermediates that they cannot use.IMPORTANCEDenitrification is a form of microbial respiration wherein nitrate is converted via several nitrogen oxide intermediates into harmless dinitrogen gas. Partial denitrifying bacteria, which individually have some but not all denitrifying enzymes, can achieve complete denitrification as a community by cross-feeding nitrogen oxide intermediates. However, the last intermediate, nitrous oxide (N2O), is a potent greenhouse gas that often escapes, motivating efforts to understand and improve the efficiency of denitrification. Here, we found that at least some partial denitrifying N2O reducers can sense and respond to nitrogen oxide intermediates that they cannot otherwise use. The regulatory effects of nitrogen oxides on partial denitrifiers are thus an important consideration in understanding and applying denitrifying bacterial communities to combat greenhouse gas emissions., Competing Interests: The authors declare no conflict of interest.

Published

2024

16. MpaR-driven expression of an orphan terminal oxidase subunit supports Pseudomonas aeruginosa biofilm respiration and development during cyanogenesis.

Author

Smiley MK, Sekaran DC, Forouhar F, Wolin E, Jovanovic M, Price-Whelan A, and Dietrich LEP

Subjects

Cyanides metabolism, Respiration, Biofilms, Heme metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Pseudomonas aeruginosa metabolism, Oxidoreductases genetics, Oxidoreductases metabolism

Abstract

Importance: Cyanide is an inhibitor of heme-copper oxidases, which are required for aerobic respiration in all eukaryotes and many prokaryotes. This fast-acting poison can arise from diverse sources, but mechanisms by which bacteria sense it are poorly understood. We investigated the regulatory response to cyanide in the pathogenic bacterium Pseudomonas aeruginosa , which produces cyanide as a virulence factor. Although P. aeruginosa has the capacity to produce a cyanide-resistant oxidase, it relies primarily on heme-copper oxidases and even makes additional heme-copper oxidase proteins specifically under cyanide-producing conditions. We found that the protein MpaR controls expression of cyanide-inducible genes in P. aeruginosa and elucidated the molecular details of this regulation. MpaR contains a DNA-binding domain and a domain predicted to bind pyridoxal phosphate (vitamin B6), a compound that is known to react spontaneously with cyanide. These observations provide insight into the understudied phenomenon of cyanide-dependent regulation of gene expression in bacteria., Competing Interests: The authors declare no conflict of interest.

Published

2024

17. Suggested role of NosZ in preventing N 2 O inhibition of dissimilatory nitrite reduction to ammonium.

Author

Yoon S, Heo H, Han H, Song D-U, Bakken LR, Frostegård Å, and Yoon S

Subjects

Nitrates metabolism, Nitrous Oxide metabolism, Oxidoreductases metabolism, Denitrification, Nitrites metabolism, Ammonium Compounds metabolism

Abstract

Importance: Dissimilatory nitrate/nitrite reduction to ammonium (DNRA) is a microbial energy-conserving process that reduces NO 3 - and/or NO 2 - to NH 4 + . Interestingly, DNRA-catalyzing microorganisms possessing nrfA genes are occasionally found harboring nosZ genes encoding nitrous oxide reductases, i.e., the only group of enzymes capable of removing the potent greenhouse gas N 2 O. Here, through a series of physiological experiments examining DNRA metabolism in one of such microorganisms, Bacillus sp. DNRA2, we have discovered that N 2 O may delay the transition to DNRA upon an oxic-to-anoxic transition, unless timely removed by the nitrous oxide reductases. These observations suggest a novel explanation as to why some nrfA -possessing microorganisms have retained nosZ genes: to remove N 2 O that may otherwise interfere with the transition from O 2 respiration to DNRA., Competing Interests: The authors declare no conflict of interest.

Published

2023

18. Comprehensive summary of steroid metabolism in Comamonas testosteroni TA441: entire degradation process of basic four rings and removal of C12 hydroxyl group.

Author

Horinouchi M and Hayashi T

Subjects

Humans, Oxidoreductases metabolism, Steroids metabolism, Cholic Acid metabolism, Ketones metabolism, Comamonas testosteroni genetics, Comamonas testosteroni metabolism

Abstract

Comamonas testosteroni is one of the representative aerobic steroid-degrading bacteria. We previously revealed the mechanism of steroidal A,B,C,D-ring degradation by C. testosteroni TA441. The corresponding genes are located in two clusters at both ends of a mega-cluster of steroid degradation genes. ORF7 and ORF6 are the only two genes in these clusters, whose function has not been determined. Here, we characterized ORF7 as encoding the dehydrase responsible for converting the C12β hydroxyl group to the C10(12) double bond on the C-ring (SteC), and ORF6 as encoding the hydrogenase responsible for converting the C10(12) double bond to a single bond (SteD). SteA and SteB, encoded just upstream of SteC and SteD, are in charge of oxidizing the C12α hydroxyl group to a ketone group and of reducing the latter to the C12β hydroxyl group, respectively. Therefore, the C12α hydroxyl group in steroids is removed with SteABCD via the C12 ketone and C12β hydroxyl groups. Given the functional characterization of ORF6 and ORF7, we disclose the entire pathway of steroidal A,B,C,D-ring breakdown by C. testosteroni TA441.IMPORTANCEStudies on bacterial steroid degradation were initiated more than 50 years ago, primarily to obtain materials for steroid drugs. Now, their implications for the environment and humans, especially in relation to the infection and the brain-gut-microbiota axis, are attracting increasing attention. Comamonas testosteroni TA441 is the leading model of bacterial aerobic steroid degradation with the ability to break down cholic acid, the main component of bile acids. Bile acids are known for their variety of physiological activities according to their substituent group(s). In this study, we identified and functionally characterized the genes for the removal of C12 hydroxyl groups and provided a comprehensive summary of the entire A,B,C,D-ring degradation pathway by C. testosteroni TA441 as the representable bacterial aerobic degradation process of the steroid core structure., Competing Interests: The authors declare no conflict of interest.

Published

2023

19. Structural basis of a bi-functional malonyl-CoA reductase (MCR) from the photosynthetic green non-sulfur bacterium Roseiflexus castenholzii .

Author

Zhang X, Xin J, Wang Z, Wu W, Liu Y, Min Z, Xin Y, Liu B, He J, Zhang X, and Xu X

Subjects

NADP metabolism, Cryoelectron Microscopy, Oxidoreductases metabolism, Aldehyde Dehydrogenase, Malonyl Coenzyme A metabolism, Alcohol Dehydrogenase, Chloroflexi metabolism

Abstract

Malonyl-CoA reductase (MCR) is a NADPH-dependent bi-functional enzyme that performs alcohol dehydrogenase and aldehyde dehydrogenase (CoA-acylating) activities in the N- and C-terminal fragments, respectively. It catalyzes the two-step reduction of malonyl-CoA to 3-hydroxypropionate (3-HP), a key reaction in the autotrophic CO 2 fixation cycles of Chloroflexaceae green non-sulfur bacteria and the archaea Crenarchaeota . However, the structural basis underlying substrate selection, coordination, and the subsequent catalytic reactions of full-length MCR is largely unknown. For the first time, we here determined the structure of full-length MCR from the photosynthetic green non-sulfur bacterium Roseiflexus castenholzii ( Rfx MCR) at 3.35 Å resolution. Furthermore, we determined the crystal structures of the N- and C-terminal fragments bound with reaction intermediates NADP + and malonate semialdehyde (MSA) at 2.0 Å and 2.3 Å, respectively, and elucidated the catalytic mechanisms using a combination of molecular dynamics simulations and enzymatic analyses. Full-length Rfx MCR was a homodimer of two cross-interlocked subunits, each containing four tandemly arranged short-chain dehydrogenase/reductase (SDR) domains. Only the catalytic domains SDR1 and SDR3 incorporated additional secondary structures that changed with NADP + -MSA binding. The substrate, malonyl-CoA, was immobilized in the substrate-binding pocket of SDR3 through coordination with Arg1164 and Arg799 of SDR4 and the extra domain, respectively. Malonyl-CoA was successively reduced through protonation by the Tyr743-Arg746 pair in SDR3 and the catalytic triad (Thr165-Tyr178-Lys182) in SDR1 after nucleophilic attack from NADPH hydrides. IMPORTANCE The bi-functional MCR catalyzes NADPH-dependent reduction of malonyl-CoA to 3-HP, an important metabolic intermediate and platform chemical, from biomass. The individual MCR-N and MCR-C fragments, which contain the alcohol dehydrogenase and aldehyde dehydrogenase (CoA-acylating) activities, respectively, have previously been structurally investigated and reconstructed into a malonyl-CoA pathway for the biosynthetic production of 3-HP. However, no structural information for full-length MCR has been available to illustrate the catalytic mechanism of this enzyme, which greatly limits our capacity to increase the 3-HP yield of recombinant strains. Here, we report the cryo-electron microscopy structure of full-length MCR for the first time and elucidate the mechanisms underlying substrate selection, coordination, and catalysis in the bi-functional MCR. These findings provide a structural and mechanistic basis for enzyme engineering and biosynthetic applications of the 3-HP carbon fixation pathways., Competing Interests: The authors declare no conflict of interest.

Published

2023

20. " Candidatus Subterrananammoxibiaceae," a New Anammox Bacterial Family in Globally Distributed Marine and Terrestrial Subsurfaces.

Author

Zhao R, Le Moine Bauer S, and Babbin AR

Subjects

Humans, Nitrates metabolism, Anaerobic Ammonia Oxidation, Phylogeny, Geologic Sediments microbiology, Bacteria, Oxidoreductases metabolism, Nitrite Reductases genetics, Oxidation-Reduction, Nitrogen metabolism, Anaerobiosis, RNA, Ribosomal, 16S genetics, Nitrites metabolism, Ammonium Compounds metabolism

Abstract

Bacteria specialized in anaerobic ammonium oxidation (anammox) are widespread in many anoxic habitats and form an important functional guild in the global nitrogen cycle by consuming bio-available nitrogen for energy rather than biomass production. Due to their slow growth rates, cultivation-independent approaches have been used to decipher their diversity across environments. However, their full diversity has not been well recognized. Here, we report a new family of putative anammox bacteria, " Candidatus Subterrananammoxibiaceae," existing in the globally distributed terrestrial and marine subsurface (groundwater and sediments of estuary, deep-sea, and hadal trenches). We recovered a high-quality metagenome-assembled genome of this family, tentatively named " Candidatus Subterrananammoxibius californiae," from a California groundwater site. The " Ca. Subterrananammoxibius californiae" genome not only contains genes for all essential components of anammox metabolism (e.g., hydrazine synthase, hydrazine oxidoreductase, nitrite reductase, and nitrite oxidoreductase) but also has the capacity for urea hydrolysis. In an Arctic ridge sediment core where redox zonation is well resolved, " Ca. Subterrananammoxibiaceae" is confined within the nitrate-ammonium transition zone where the anammox rate maximum occurs, providing environmental proof of the anammox activity of this new family. Phylogenetic analysis of nitrite oxidoreductase suggests that a horizontal transfer facilitated the spreading of the nitrite oxidation capacity between anammox bacteria (in the Planctomycetota phylum) and nitrite-oxidizing bacteria from Nitrospirota and Nitrospinota . By recognizing this new anammox family, we propose that all lineages within the " Ca. Brocadiales" order have anammox capacity. IMPORTANCE Microorganisms called anammox bacteria are efficient in removing bioavailable nitrogen from many natural and human-made environments. They exist in almost every anoxic habitat where both ammonium and nitrate/nitrite are present. However, only a few anammox bacteria have been cultured in laboratory settings, and their full phylogenetic diversity has not been recognized. Here, we present a new bacterial family whose members are present across both the terrestrial and marine subsurface. By reconstructing a high-quality genome from the groundwater environment, we demonstrate that this family has all critical enzymes of anammox metabolism and, notably, also urea utilization. This bacterium family in marine sediments is also preferably present in the niche where the anammox process occurs. These findings suggest that this novel family, named " Candidatus Subterrananammoxibiaceae," is an overlooked group of anammox bacteria, which should have impacts on nitrogen cycling in a range of environments., Competing Interests: The authors declare no conflict of interest.

Published

2023

21. High Lethality of Mycobacterium tuberculosis Infection in Mice Lacking the Phagocyte Oxidase and Caspase1/11.

Author

Thomas SM and Olive AJ

Subjects

Animals, Mice, Oxidoreductases metabolism, Phagocytes, Cytokines metabolism, Tuberculosis genetics, Mycobacterium tuberculosis, Tuberculosis, Pulmonary

Abstract

Immune networks that control antimicrobial and inflammatory mechanisms have overlapping regulation and functions to ensure effective host responses. Genetic interaction studies of immune pathways that compare host responses in single and combined knockout backgrounds are a useful tool to identify new mechanisms of immune control during infection. For disease caused by pulmonary Mycobacterium tuberculosis (Mtb) infections, which currently lacks an effective vaccine, understanding the genetic interactions between protective immune pathways may identify new therapeutic targets or disease-associated genes. Previous studies have suggested a direct link between the activation of NLRP3-Caspase1 inflammasome and the NADPH-dependent phagocyte oxidase complex during Mtb infection. Loss of the phagocyte oxidase complex alone resulted in increased activation of Caspase1 and IL-1β production during Mtb infection, resulting in failed disease tolerance during the chronic stages of disease. To better understand this interaction, we generated mice lacking both Cybb , a key subunit of the phagocyte oxidase, and Caspase1/11 . We found that ex vivo Mtb infection of Cybb -/- Caspase1/11 -/- macrophages resulted in the expected loss of IL-1β secretion but an unexpected change in other inflammatory cytokines and bacterial control. Mtb infected Cybb -/- Caspase1/11 -/- mice rapidly progressed to severe TB, succumbing within 4 weeks to disease characterized by high bacterial burden, increased inflammatory cytokines, and the recruitment of granulocytes that associated with Mtb in the lungs. These results uncover a key genetic interaction between the phagocyte oxidase complex and Caspase1/11 that controls protection against TB and highlight the need for a better understanding of the regulation of fundamental immune networks during Mtb infection., Competing Interests: The authors declare no conflict of interest.

Published

2023

22. Core and auxiliary functions of one-carbon metabolism in Pseudomonas putida exposed by a systems-level analysis of transcriptional and physiological responses.

Author

Turlin J, Puiggené Ò, Donati S, Wirth NT, and Nikel PI

Subjects

Methanol metabolism, Carbon metabolism, Formaldehyde metabolism, Formates metabolism, Oxidoreductases metabolism, Pseudomonas putida genetics

Abstract

The soil bacterium Pseudomonas putida is a robust biomanufacturing host that assimilates a broad range of substrates while efficiently coping with adverse environmental conditions. P. putida is equipped with functions related to one-carbon (C1) compounds (e.g. methanol, formaldehyde, and formate) oxidation-yet pathways to assimilate these carbon sources are largely absent. In this work, we adopted a systems-level approach to study the genetic and molecular basis of C1 metabolism in P. putida . RNA sequencing identified two oxidoreductases, encoded by PP_0256 and PP_4596 , transcriptionally active in the presence of formate. Quantitative physiology of deletion mutants revealed growth defects at high formate concentrations, pointing to an important role of these oxidoreductases in C1 tolerance. Moreover, we describe a concerted detoxification process for methanol and formaldehyde, the C1 intermediates upstream formate. Alcohol oxidation to highly-reactive formaldehyde by PedEH and other broad-substrate-range dehydrogenases underpinned the (apparent) suboptimal methanol tolerance of P. putida . Formaldehyde was mostly processed by a glutathione-dependent mechanism encoded in the frmAC operon, and thiol-independent FdhAB and AldB-II overtook detoxification at high aldehyde concentrations. Deletion strains were constructed and characterized towards unveiling these biochemical mechanisms, underscoring the worth of P. putida for emergent biotechnological applications-e.g. engineering synthetic formatotrophy and methylotrophy. IMPORTANCE C1 substrates continue to attract interest in biotechnology, as their use is both cost-effective and ultimately expected to mitigate the impact of greenhouse gas emissions. However, our current understanding of bacterial C1 metabolism remains relatively limited in species that cannot grow on (i.e., assimilate) these substrates. Pseudomonas putida , a model Gram-negative environmental bacterium, constitutes a prime example of this sort. The biochemical pathways active in response to methanol, formaldehyde, and formate have been largely overlooked-although the ability of P. putida to process C1 molecules has been previously alluded to in the literature. By using a systems-level strategy, this study bridges such knowledge gap through the identification and characterization of mechanisms underlying methanol, formaldehyde, and formate detoxification-including hitherto unknown enzymes that act on these substrates. The results reported herein both expand our understanding of microbial metabolism and lay a solid foundation for engineering efforts toward valorizing C1 feedstocks., Competing Interests: The authors declare no conflict of interest.

Published

2023

23. Metabolic Sensing of Extracytoplasmic Copper Availability via Translational Control by a Nascent Exported Protein.

Author

Öztürk Y, Andrei A, Blaby-Haas CE, Daum N, Daldal F, and Koch HG

Subjects

Binding Sites, Ribosomes metabolism, Gene Expression Regulation, Copper metabolism, Oxidoreductases metabolism

Abstract

Metabolic sensing is a crucial prerequisite for cells to adjust their physiology to rapidly changing environments. In bacteria, the response to intra- and extracellular ligands is primarily controlled by transcriptional regulators, which activate or repress gene expression to ensure metabolic acclimation. Translational control, such as ribosomal stalling, can also contribute to cellular acclimation and has been shown to mediate responses to changing intracellular molecules. In the current study, we demonstrate that the cotranslational export of the Rhodobacter capsulatus protein CutF regulates the translation of the downstream cutO -encoded multicopper oxidase CutO in response to extracellular copper (Cu). Our data show that CutF, acting as a Cu sensor, is cotranslationally exported by the signal recognition particle pathway. The binding of Cu to the periplasmically exposed Cu-binding motif of CutF delays its cotranslational export via its C-terminal ribosome stalling-like motif. This allows for the unfolding of an mRNA stem-loop sequence that shields the ribosome-binding site of cutO , which favors its subsequent translation. Bioinformatic analyses reveal that CutF-like proteins are widely distributed in bacteria and are often located upstream of genes involved in transition metal homeostasis. Our overall findings illustrate a highly conserved control mechanism using the cotranslational export of a protein acting as a sensor to integrate the changing availability of extracellular nutrients into metabolic acclimation. IMPORTANCE Metabolite sensing is a fundamental biological process, and the perception of dynamic changes in the extracellular environment is of paramount importance for the survival of organisms. Bacteria usually adjust their metabolisms to changing environments via transcriptional regulation. Here, using Rhodobacter capsulatus, we describe an alternative translational mechanism that controls the bacterial response to the presence of copper, a toxic micronutrient. This mechanism involves a cotranslationally secreted protein that, in the presence of copper, undergoes a process resembling ribosomal stalling. This allows for the unfolding of a downstream mRNA stem-loop and enables the translation of the adjacent Cu-detoxifying multicopper oxidase. Bioinformatic analyses reveal that such proteins are widespread, suggesting that metabolic sensing using ribosome-arrested nascent secreted proteins acting as sensors may be a common strategy for the integration of environmental signals into metabolic adaptations.

Published

2023

24. Denitrification by Bradyrhizobia under Feast and Famine and the Role of the bc1 Complex in Securing Electrons for N 2 O Reduction.

Author

Gao Y, Øverlie Arntzen M, Kjos M, Bakken LR, and Frostegård Å

Subjects

Electrons, Denitrification, Oxidoreductases metabolism, Nitrates chemistry, Nitrate Reductase, Bacteria metabolism, Vegetables metabolism, Nitrous Oxide, Soil chemistry, Bradyrhizobium genetics, Fabaceae

Abstract

Rhizobia living as microsymbionts inside nodules have stable access to carbon substrates, but also must survive as free-living bacteria in soil where they are starved for carbon and energy most of the time. Many rhizobia can denitrify, thus switch to anaerobic respiration under low O 2 tension using N -oxides as electron acceptors. The cellular machinery regulating this transition is relatively well known from studies under optimal laboratory conditions, while little is known about this regulation in starved organisms. It is, for example, not known if the strong preference for N 2 O- over NO 3 - reduction in bradyrhizobia is retained under carbon limitation. Here, we show that starved cultures of a Bradyrhizobium strain with respiration rates 1 to 18% of well-fed cultures reduced all available N 2 O before touching provided NO 3 - . These organisms, which carry out complete denitrification, have the periplasmic nitrate reductase NapA but lack the membrane-bound nitrate reductase NarG. Proteomics showed similar levels of NapA and NosZ (N 2 O reductase), excluding that the lack of NO 3 - reduction was due to low NapA abundance. Instead, this points to a metabolic-level phenomenon where the bc1 complex, which channels electrons to NosZ via cytochromes, is a much stronger competitor for electrons from the quinol pool than the NapC enzyme, which provides electrons to NapA via NapB. The results contrast the general notion that NosZ activity diminishes under carbon limitation and suggest that bradyrhizobia carrying NosZ can act as strong sinks for N 2 O under natural conditions, implying that this criterion should be considered in the development of biofertilizers. IMPORTANCE Legume cropped farmlands account for substantial N 2 O emissions globally. Legumes are commonly inoculated with N 2 -fixing bacteria, rhizobia, to improve crop yields. Rhizobia belonging to Bradyrhizobium , the microsymbionts of several economically important legumes, are generally capable of denitrification but many lack genes encoding N 2 O reductase and will be N 2 O sources. Bradyrhizobia with complete denitrification will instead act as sinks since N 2 O-reduction efficiently competes for electrons over nitrate reduction in these organisms. This phenomenon has only been demonstrated under optimal conditions and it is not known how carbon substrate limitation, which is the common situation in most soils, affects the denitrification phenotype. Here, we demonstrate that bradyrhizobia retain their strong preference for N 2 O under carbon starvation. The findings add basic knowledge about mechanisms controlling denitrification and support the potential for developing novel methods for greenhouse gas mitigation based on legume inoculants with the dual capacity to optimize N 2 fixation and minimize N 2 O emission.

Published

2023

25. Nonredundant Dimethyl Sulfoxide Reductases Influence Salmonella enterica Serotype Typhimurium Anaerobic Growth and Virulence.

Author

Cruz E, Haeberle AL, Westerman TL, Durham ME, Suyemoto MM, Knodler LA, and Elfenbein JR

Subjects

Animals, Virulence, Anaerobiosis, Serogroup, Oxidoreductases metabolism, Salmonella typhimurium, Mammals, Type III Secretion Systems metabolism, Dimethyl Sulfoxide pharmacology, Dimethyl Sulfoxide metabolism

Abstract

Facultative anaerobic enteric pathogens can utilize a diverse array of alternate electron acceptors to support anaerobic metabolism and thrive in the hypoxic conditions within the mammalian gut. Dimethyl sulfoxide (DMSO) is produced by methionine catabolism and can act as an alternate electron acceptor to support anaerobic respiration. The DMSO reductase complex consists of three subunits, DmsA, DmsB, and DmsC, and allows bacteria to grow anaerobically with DMSO as an electron acceptor. The genomes of nontyphoidal Salmonella enterica encode three putative dmsABC operons, but the impact of the apparent genetic redundancy in DMSO reduction on the fitness of nontyphoidal S. enterica during infection remains unknown. We hypothesized that DMSO reduction would be needed for S. enterica serotype Typhimurium to colonize the mammalian gut. We demonstrate that an S. Typhimurium mutant with loss of function in all three putative DMSO reductases (Δ dmsA 3 ) poorly colonizes the mammalian intestine when the microbiota is intact and when inflammation is absent. DMSO reduction enhances anaerobic growth through nonredundant contributions of two of the DMSO reductases. Furthermore, DMSO reduction influences virulence by increasing expression of the type 3 secretion system 2 and reducing expression of the type 3 secretion system 1. Collectively, our data demonstrate that the DMSO reductases of S. Typhimurium are functionally nonredundant and suggest DMSO is a physiologically relevant electron acceptor that supports S. enterica fitness in the gut.

Published

2023

26. Molecular Mechanism of Chloramphenicol and Thiamphenicol Resistance Mediated by a Novel Oxidase, CmO, in Sphingomonadaceae .

Author

Ma X, Zhang L, Ren Y, Yun H, Cui H, Li Q, Guo Y, Gao S, Zhang F, Wang A, and Liang B

Subjects

Humans, Molecular Docking Simulation, Anti-Bacterial Agents metabolism, Anti-Bacterial Agents pharmacology, Chloramphenicol metabolism, Chloramphenicol pharmacology, Oxidoreductases genetics, Oxidoreductases metabolism, Sphingomonadaceae genetics, Sphingomonadaceae metabolism, Thiamphenicol metabolism, Thiamphenicol pharmacology, Drug Resistance, Bacterial genetics

Abstract

Antibiotic resistance mediated by bacterial enzyme inactivation plays a crucial role in the degradation of antibiotics in the environment. Chloramphenicol (CAP) resistance by enzymatic inactivation comprises nitro reduction, amide bond hydrolysis, and acetylation modification. However, the molecular mechanism of enzymatic oxidation of CAP remains unknown. Here, a novel oxidase gene, cmO , was identified and confirmed biochemically. The encoded CmO oxidase could catalyze the oxidation at the C-1' and C-3' positions of CAP and thiamphenicol (TAP) in Sphingobium sp. strain CAP-1. CmO is highly conserved in members of the family Sphingomonadaceae and shares the highest amino acid similarity of 41.05% with the biochemically identified glucose methanol choline (GMC) oxidoreductases. Molecular docking and site-directed mutagenesis analyses demonstrated that CAP was anchored inside the protein pocket of CmO with the hydrogen bonding of key residues glycine (G) 99, asparagine (N) 518, methionine (M) 474, and tyrosine (Y) 380. CAP sensitivity tests demonstrated that the acetyltransferase and CmO could enable a higher level of resistance to CAP than the amide bond-hydrolyzing esterase and nitroreductase. This study provides a better theoretical basis and a novel diagnostic gene for understanding and assessing the fate and resistance risk of CAP and TAP in the environment. IMPORTANCE Rising levels of antibiotic resistance are undermining ecological and human health as a result of the indiscriminate usage of antibiotics. Various resistance mechanisms have been characterized-for example, genes encoding proteins that degrade antibiotics-and yet, this requires further exploration. In this study, we report a novel gene encoding an oxidase involved in the inactivation of typical amphenicol antibiotics (chloramphenicol and thiamphenicol), and the molecular mechanism is elucidated. The findings provide novel data with which to understand the capabilities of bacteria to tackle antibiotic stress, as well as the complex function of enzymes in the contexts of antibiotic resistance development and antibiotic removal. The reported gene can be further employed as an indicator to monitor amphenicol's fate in the environment, thus benefiting risk assessment in this era of antibiotic resistance.

Published

2023

27. Metabolic Mechanism and Physiological Role of Glycerol 3-Phosphate in Pseudomonas aeruginosa PAO1.

Author

Liu Y, Sun W, Ma L, Xu R, Yang C, Xu P, Ma C, and Gao C

Subjects

Humans, Pseudomonas aeruginosa genetics, Glycerol metabolism, Virulence Factors genetics, Anti-Bacterial Agents metabolism, Kanamycin metabolism, Oxidoreductases metabolism, Cystic Fibrosis microbiology, Pseudomonas Infections microbiology

Abstract

Pseudomonas aeruginosa is an important opportunistic pathogen that is lethal to cystic fibrosis (CF) patients. Glycerol generated during the degradation of phosphatidylcholine, the major lung surfactant in CF patients, could be utilized by P. aeruginosa. Previous studies have indicated that metabolism of glycerol by this bacterium contributes to its adaptation to and persistence in the CF lung environment. Here, we investigated the metabolic mechanisms of glycerol and its important metabolic intermediate glycerol 3-phosphate (G3P) in P. aeruginosa PAO1. We found that G3P homeostasis plays an important role in the growth and virulence factor production of P. aeruginosa PAO1. The G3P accumulation caused by the mutation of G3P dehydrogenase (GlpD) and exogenous glycerol led to impaired growth and reductions in pyocyanin synthesis, motilities, tolerance to oxidative stress, and resistance to kanamycin. Transcriptomic analysis indicates that the growth retardation caused by G3P stress is associated with reduced glycolysis and adenosine triphosphate (ATP) generation. Furthermore, two haloacid dehalogenase-like phosphatases (PA0562 and PA3172) that play roles in the dephosphorylation of G3P in strain PAO1 were identified, and their enzymatic properties were characterized. Our findings reveal the importance of G3P homeostasis and indicate that GlpD, the key enzyme for G3P catabolism, is a potential therapeutic target for the prevention and treatment of infections by this pathogen. IMPORTANCE In view of the intrinsic resistance of Pseudomonas aeruginosa to antibiotics and its potential to acquire resistance to current antibiotics, there is an urgent need to develop novel therapeutic options for the treatment of infections caused by this bacterium. Bacterial metabolic pathways have recently become a focus of interest as potential targets for the development of new antibiotics. In this study, we describe the mechanism of glycerol utilization in P. aeruginosa PAO1, which is an available carbon source in the lung environment. Our results reveal that the homeostasis of glycerol 3-phosphate (G3P), a pivotal intermediate in glycerol catabolism, is important for the growth and virulence factor production of P. aeruginosa PAO1. The mutation of G3P dehydrogenase (GlpD) and the addition of glycerol were found to reduce the tolerance of P. aeruginosa PAO1 to oxidative stress and to kanamycin. The findings highlight the importance of G3P homeostasis and suggest that GlpD is a potential drug target for the treatment of P. aeruginosa infections.

Published

2022

28. Anaerobic Biohydrogenation of Isoprene by Acetobacterium wieringae Strain Y.

Author

Jin H, Li X, Wang H, Cápiro NL, Li X, Löffler FE, Yan J, and Yang Y

Subjects

Anaerobiosis, Proteomics, Oxidoreductases metabolism, Acetobacterium genetics, Acetobacterium metabolism

Abstract

Isoprene is a ubiquitously distributed, biogenic, and climate-active organic compound. Microbial isoprene degradation in oxic environments is fairly well understood; however, studies exploring anaerobic isoprene metabolism remain scarce, with no isolates for study available. Here, we obtained an acetogenic isolate, designated Acetobacterium wieringae strain Y, which hydrogenated isoprene to a mixture of methyl-1-butenes at an overall rate of 288.8 ± 20.9 μM day -1 with concomitant acetate production at a rate of 478.4 ± 5.6 μM day -1 . Physiological characterization demonstrated that isoprene was not utilized in a respiratory process; rather, isoprene promoted acetogenesis kinetically. Bioinformatic analysis and proteomics experiments revealed the expression of candidate ene-reductases responsible for isoprene biohydrogenation. Notably, the addition of isoprene to strain Y cultures stimulated the expression of proteins associated with the Wood-Ljungdahl pathway, indicating unresolved impacts of isoprene on carbon cycling and microbial ecology in anoxic environments (e.g., promoting CO 2 plus H 2 reductive acetogenesis while inhibiting methanogenesis). Our new findings advance understanding of microbial transformation of isoprene under anoxic conditions and suggest that anoxic environments are isoprene sinks. IMPORTANCE Isoprene is the most abundant, biologically generated, volatile organic compound on Earth, with estimated emissions in the same magnitude as methane. Nonetheless, a comprehensive knowledge of isoprene turnover in the environment is lacking, impacting global isoprene flux models and our understanding of the environmental fate and longevity of isoprene. A critical knowledge gap that has remained largely unexplored until recently is the microbiology and associated molecular mechanisms involved in the anaerobic biotransformation of isoprene. By integrating culture-dependent approaches with omics techniques, we isolated an acetogen, Acetobacterium wieringae strain Y, capable of anaerobic biohydrogenation of isoprene. We obtained the complete genome of strain Y, and proteomic experiments identified candidate ene-reductases for catalyzing the asymmetric reduction of the electronically activated carbon-carbon double bond of isoprene. We also demonstrated that isoprene biohydrogenation stimulates the expression of Wood-Ljungdahl pathway enzymes. This study emphasizes the ecological roles of specialized Acetobacterium on the natural cycling of isoprene in anoxic environments and the potential effects of isoprene biohydrogenation on acetogens and methanogens, which have implications for global climate change and bioenergy production.

Published

2022

29. The Maize Pathogen Ustilago maydis Secretes Glycoside Hydrolases and Carbohydrate Oxidases Directed toward Components of the Fungal Cell Wall.

Author

Reyre JL, Grisel S, Haon M, Navarro D, Ropartz D, Le Gall S, Record E, Sciara G, Tranquet O, Berrin JG, and Bissaro B

Subjects

Zea mays metabolism, Oxidoreductases metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, Phylogeny, Cell Wall metabolism, Fungi metabolism, Plants metabolism, Carbohydrates, Glucans metabolism, Glycoside Hydrolases metabolism, Ustilago

Abstract

Filamentous fungi are keystone microorganisms in the regulation of many processes occurring on Earth, such as plant biomass decay and pathogenesis as well as symbiotic associations. In many of these processes, fungi secrete carbohydrate-active enzymes (CAZymes) to modify and/or degrade carbohydrates. Ten years ago, while evaluating the potential of a secretome from the maize pathogen Ustilago maydis to supplement lignocellulolytic cocktails, we noticed it contained many unknown or poorly characterized CAZymes. Here, and after reannotation of this data set and detailed phylogenetic analyses, we observed that several CAZymes (including glycoside hydrolases and carbohydrate oxidases) are predicted to act on the fungal cell wall (FCW), notably on β-1,3-glucans. We heterologously produced and biochemically characterized two new CAZymes, called Um GH16_1-A and Um AA3_2-A. We show that Um GH16_1-A displays β-1,3-glucanase activity, with a preference for β-1,3-glucans with short β-1,6 substitutions, and Um AA3_2-A is a dehydrogenase catalyzing the oxidation of β-1,3- and β-1,6-gluco-oligosaccharides into the corresponding aldonic acids. Working on model β-1,3-glucans, we show that the linear oligosaccharide products released by Um GH16_1-A are further oxidized by Um AA3_2-A, bringing to light a putative biocatalytic cascade. Interestingly, analysis of available transcriptomics data indicates that both Um GH16_1-A and Um AA3_2-A are coexpressed, only during early stages of U. maydis infection cycle. Altogether, our results suggest that both enzymes are connected and that additional accessory activities still need to be uncovered to fully understand the biocatalytic cascade at play and its physiological role. IMPORTANCE Filamentous fungi play a central regulatory role on Earth, notably in the global carbon cycle. Regardless of their lifestyle, filamentous fungi need to remodel their own cell wall (mostly composed of polysaccharides) to grow and proliferate. To do so, they must secrete a large arsenal of enzymes, most notably carbohydrate-active enzymes (CAZymes). However, research on fungal CAZymes over past decades has mainly focused on finding efficient plant biomass conversion processes while CAZymes directed at the fungus itself have remained little explored. In the present study, using the maize pathogen Ustilago maydis as model, we set off to evaluate the prevalence of CAZymes directed toward the fungal cell wall during growth of the fungus on plant biomass and characterized two new CAZymes active on fungal cell wall components. Our results suggest the existence of a biocatalytic cascade that remains to be fully understood.

Published

2022

30. Bioconversion of Phytosterols to 9-Hydroxy-3-Oxo-4,17-Pregadiene-20-Carboxylic Acid Methyl Ester by Enoyl-CoA Deficiency and Modifying Multiple Genes in Mycolicibacterium neoaurum.

Author

Yuan C, Song S, He J, Zhang J, Liu X, Pena EL, Sun J, Shi J, Su Z, and Zhang B

Subjects

Oxidoreductases metabolism, Enoyl-CoA Hydratase genetics, Enoyl-CoA Hydratase metabolism, Steroids metabolism, Acyl Coenzyme A, Carboxylic Acids, Ketosteroids, Esters, Phytosterols metabolism, Prodrugs, Acyl-CoA Dehydrogenases

Abstract

Steroid drug precursors, including C19 and C22 steroids, are crucial to steroid drug synthesis and development. However, C22 steroids are less developed due to the intricacy of the steroid metabolic pathway. In this study, a C22 steroid drug precursor, 9-hydroxy-3-oxo-4,17-pregadiene-20-carboxylic acid methyl ester (9-OH-PDCE), was successfully obtained from Mycolicibacterium neoaurum by 3-ketosteroid-Δ 1 -dehydrogenase and enoyl-CoA hydratase ChsH deficiency. The production of 9-OH-PDCE was improved by the overexpression of 17β-hydroxysteroid dehydrogenase Hsd4A and acyl-CoA dehydrogenase ChsE1-ChsE2 to reduce the accumulation of by-products. The purity of 9-OH-PDCE in fermentation broth was improved from 71.7% to 89.7%. Hence, the molar yield of 9-OH-PDCE was improved from 66.7% to 86.7%, with a yield of 0.78 g/L. Furthermore, enoyl-CoA hydratase ChsH1-ChsH2 was identified to form an indispensable complex in Mycolicibacterium neoaurum DSM 44704. IMPORTANCE C22 steroids are valuable precursors for steroid drug synthesis, but the development of C22 steroids remains unsatisfactory. This study presented a strategy for the one-step bioconversion of phytosterols to a C22 steroid drug precursor, 9-hydroxy-3-oxo-4,17-pregadiene-20-carboxylic acid methyl ester (9-OH-PDCE), by 3-ketosteroid-Δ 1 -dehydrogenase and enoyl-CoA hydratase deficiency with overexpression of 17β-hydroxysteroid dehydrogenase acyl-CoA dehydrogenase in Mycolicibacterium . The function of the enoyl-CoA hydratase ChsH in vivo was revealed. Construction of the novel C22 steroid drug precursor producer provided more potential for steroid drug synthesis, and the characterization of the function of ChsH and the transformation of steroids further revealed the steroid metabolic pathway.

Published

2022

31. Preparation for Denitrification and Phenotypic Diversification at the Cusp of Anoxia: a Purpose for N 2 O Reductase Vis-à-Vis Multiple Roles of O 2 .

Author

Kellermann R, Hauge K, Tjåland R, Thalmann S, Bakken LR, and Bergaust L

Subjects

Bacteria genetics, Denitrification genetics, Hypoxia, Nitrite Reductases genetics, Nitrite Reductases metabolism, Nitrous Oxide metabolism, Oxidoreductases metabolism, Paracoccus denitrificans metabolism

Abstract

Adaptation to anoxia by synthesizing a denitrification proteome costs metabolic energy, and the anaerobic respiration conserves less energy per electron than aerobic respiration. This implies a selective advantage of the stringent O 2 repression of denitrification gene transcription, which is found in most denitrifying bacteria. In some bacteria, the metabolic burden of adaptation can be minimized further by phenotypic diversification, colloquially termed "bet-hedging," where all cells synthesize the N 2 O reductase (NosZ) but only a minority synthesize nitrite reductase (NirS), as demonstrated for the model strain Paracoccus denitrificans. We hypothesized that the cells lacking NirS would be entrapped in anoxia but with the possibility of escape if supplied with O 2 or N 2 O. To test this, cells were exposed to gradual O 2 depletion or sudden anoxia and subsequent spikes of O 2 and N 2 O. The synthesis of NirS in single cells was monitored by using an mCherry-nirS fusion replacing the native nirS , and their growth was detected as dilution of green, fluorescent fluorescein isothiocyanate (FITC) stain. We demonstrate anoxic entrapment due to e - -acceptor deprivation and show that O 2 spiking leads to bet-hedging, while N 2 O spiking promotes NirS synthesis and growth in all cells carrying NosZ. The cells rescued by the N 2 O spike had much lower respiration rates than those rescued by the O 2 spike, however, which could indicate that the well-known autocatalytic synthesis of NirS via NO production requires O 2 . Our results bring into relief a fitness advantage of pairing restrictive nirS expression with universal NosZ synthesis in energy-limited systems. IMPORTANCE Denitrifying bacteria have evolved elaborate regulatory networks securing their respiratory metabolism in environments with fluctuating oxygen concentrations. Here, we provide new insight regarding their bet-hedging in response to hypoxia, which minimizes their N 2 O emissions because all cells express NosZ, reducing N 2 O to N 2 , while a minority express NirS + Nor, reducing NO 2 - to N 2 O. We hypothesized that the cells without Nir were entrapped in anoxia, without energy to synthesize Nir, and that they could be rescued by short spikes of O 2 or N 2 O. We confirm such entrapment and the rescue of all cells by an N 2 O spike but only a fraction by an O 2 spike. The results shed light on the role of O 2 repression in bet-hedging and generated a novel hypothesis regarding the autocatalytic nirS expression via NO production. Insight into the regulation of denitrification, including bet-hedging, holds a clue to understanding, and ultimately curbing, the escalating emissions of N 2 O, which contribute to anthropogenic climate forcing.

Published

2022

32. Evidence for Quinol Oxidation Activity of ImoA, a Novel NapC/NirT Family Protein from the Neutrophilic Fe(II)-Oxidizing Bacterium Sideroxydans lithotrophicus ES-1.

Author

Jain A, Coelho A, Madjarov J, Paquete CM, and Gralnick JA

Subjects

Hydroquinones metabolism, Ferric Compounds metabolism, Phylogeny, Oxidation-Reduction, Electron Transport, Ferrous Compounds metabolism, Quinones metabolism, Porins metabolism, Oxidoreductases metabolism, Iron metabolism, Cytochrome c Group chemistry, Shewanella genetics, Shewanella metabolism

Abstract

Sideroxydans species are important chemolithoautotrophic Fe(II)-oxidizing bacteria in freshwater environments and play a role in biogeochemical cycling of multiple elements. Due to difficulties in laboratory cultivation and genetic intractability, the electron transport proteins required for the growth and survival of this organism remain understudied. In Sideroxydans lithotrophicus ES-1, it is proposed that the Mto pathway transfers electrons from extracellular Fe(II) oxidation across the periplasm to an inner membrane NapC/NirT family protein encoded by Slit_2495 to reduce the quinone pool. Based on sequence similarity, Slit_2495 has been putatively called CymA, a NapC/NirT family protein which in Shewanella oneidensis MR-1 oxidizes the quinol pool during anaerobic respiration of a wide range of substrates. However, our phylogenetic analysis using the alignment of different NapC/NirT family proteins shows that Slit_2495 clusters closer to NirT sequences than to CymA. We propose the name ImoA (inner membrane oxidoreductase) for Slit_2495. Our data demonstrate that ImoA can oxidize quinol pools in the inner membrane and is able to functionally replace CymA in S. oneidensis. The ability of ImoA to oxidize quinol in vivo as opposed to its proposed function of reducing quinone raises questions about the directionality and/or reversibility of electron flow through the Mto pathway in S. lithotrophicus. IMPORTANCE Fe(II)-oxidizing bacteria play an important role in biogeochemical cycles. At circumneutral pH, these organisms perform extracellular electron transfer, taking up electrons from Fe(II) outside the cell, potentially through a porin-cytochrome complex in the outer membrane encoded by the Mto pathway. Electrons from Fe(II) oxidation would then be transported to the quinone pool in the inner membrane via periplasmic and inner membrane electron transfer proteins. Directly demonstrating the functionality of genes in neutrophilic iron oxidizers is challenging due to the absence of robust genetic methods. Here, we heterologously expressed a NapC/NirT family tetraheme cytochrome ImoA, encoded by Slit_2495 , an inner membrane protein from the Gram-negative Fe(II)-oxidizing bacterium Sideroxydans lithotrophicus ES-1, proposed to be involved in extracellular electron transfer to reduce the quinone pool. ImoA functionally replaced the inner membrane c -type cytochrome CymA in the Fe(III)-reducing bacterium Shewanella oneidensis. We suggest that ImoA may function primarily to oxidize quinol in S. lithotrophicus.

Published

2022

33. Transcriptional Response of Candida auris to the Mrr1 Inducers Methylglyoxal and Benomyl.

Author

Biermann AR and Hogan DA

Subjects

ATP Binding Cassette Transporter, Subfamily B, Member 1 genetics, ATP Binding Cassette Transporter, Subfamily B, Member 1 metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, Gene Expression Regulation, Fungal, Oxidoreductases metabolism, Phylogeny, Transcription Factors genetics, Transcription Factors metabolism, Antifungal Agents pharmacology, Benomyl pharmacology, Candida auris drug effects, Candida auris genetics, Fluconazole pharmacology, Pyruvaldehyde pharmacology

Abstract

Candida auris is an urgent threat to human health due to its rapid spread in health care settings and its repeated development of multidrug resistance. Diseases that increase risk for C. auris infection, such as diabetes, kidney failure, or immunocompromising conditions, are associated with elevated levels of methylglyoxal (MG), a reactive dicarbonyl compound derived from several metabolic processes. In other Candida species, expression of MG reductase enzymes that catabolize and detoxify MG are controlled by Mrr1, a multidrug resistance-associated transcription factor, and MG induces Mrr1 activity. Here, we used transcriptomics and genetic assays to determine that C. auris MRR1a contributes to MG resistance, and that the main Mrr1a targets are an MG reductase and MDR1 , which encodes a drug efflux protein. The C. auris Mrr1a regulon is smaller than Mrr1 regulons described in other species. In addition to MG, benomyl (BEN), a known Mrr1 stimulus, induces C. auris Mrr1 activity, and characterization of the MRR1a -dependent and -independent transcriptional responses revealed substantial overlap in genes that were differentially expressed in response to each compound. Additionally, we found that an MRR1 allele specific to one C. auris phylogenetic clade, clade III, encodes a hyperactive Mrr1 variant, and this activity correlated with higher MG resistance. C. auris MRR1a alleles were functional in Candida lusitaniae and were inducible by BEN, but not by MG, suggesting that the two Mrr1 inducers act via different mechanisms. Together, the data presented in this work contribute to the understanding of Mrr1 activity and MG resistance in C. auris. IMPORTANCE Candida auris is a fungal pathogen that has spread since its identification in 2009 and is of concern due to its high incidence of resistance against multiple classes of antifungal drugs. In other Candida species, the transcription factor Mrr1 plays a major role in resistance against azole antifungals and other toxins. More recently, Mrr1 has been recognized to contribute to resistance to methylglyoxal (MG), a toxic metabolic product that is often elevated in different disease states. MG can activate Mrr1 and its induction of Mdr1 which can protect against diverse challenges. The significance of this work lies in showing that MG is also an inducer of Mrr1 in C. auris, and that one of the major pathogenic C. auris lineages has an activating Mrr1 mutation that confers protection against MG.

Published

2022

34. Visualization of mRNA Expression in Pseudomonas aeruginosa Aggregates Reveals Spatial Patterns of Fermentative and Denitrifying Metabolism.

Author

Livingston J, Spero MA, Lonergan ZR, and Newman DK

Subjects

Agar metabolism, Denitrification, Fermentation, Nitrate Reductase genetics, Nitrate Reductase metabolism, Nitrite Reductases genetics, Nitrite Reductases metabolism, Oxidoreductases metabolism, Oxygen metabolism, RNA, Messenger metabolism, Acetate Kinase, Pseudomonas aeruginosa physiology

Abstract

Gaining insight into the behavior of bacteria at the single-cell level is important given that heterogeneous microenvironments strongly influence microbial physiology. The hybridization chain reaction (HCR) is a technique that provides in situ molecular signal amplification, enabling simultaneous mapping of multiple target RNAs at small spatial scales. To refine this method for biofilm applications, we designed and validated new probes to visualize the expression of key catabolic genes in Pseudomonas aeruginosa aggregates. In addition to using existing probes for the dissimilatory nitrate reductase ( narG ), we developed probes for a terminal oxidase ( ccoN1 ), nitrite reductase ( nirS ), nitrous oxide reductase ( nosZ ), and acetate kinase ( ackA ). These probes can be used to determine gene expression levels across heterogeneous populations such as biofilms. Using these probes, we quantified gene expression across oxygen gradients in aggregate populations grown using the a gar b lock b iofilm a ssay (ABBA). We observed distinct patterns of catabolic gene expression, with upregulation occurring in particular ABBA regions both within individual aggregates and over the aggregate population. Aerobic respiration ( ccoN1 ) showed peak expression under oxic conditions, whereas fermentation ( ackA ) showed peak expression in the anoxic cores of high metabolic activity aggregates near the air-agar interface. Denitrification genes narG, nirS, and nosZ showed peak expression in hypoxic and anoxic regions, although nirS expression remained at peak levels deeper into anoxic environments than other denitrification genes. These results reveal that the microenvironment correlates with catabolic gene expression in aggregates, and they demonstrate the utility of HCR in unveiling cellular activities at the microscale level in heterogeneous populations. IMPORTANCE To understand bacteria in diverse contexts, we must understand the variations in behaviors and metabolisms they express spatiotemporally. Populations of bacteria are known to be heterogeneous, but the ways this variation manifests can be challenging to characterize due to technical limitations. By focusing on energy conservation, we demonstrate that HCR v3.0 can visualize nuances in gene expression, allowing us to understand how metabolism in Pseudomonas aeruginosa biofilms responds to microenvironmental variation at high spatial resolution. We validated probes for four catabolic genes, including a constitutively expressed oxidase, acetate kinase, nitrite reductase, and nitrous oxide reductase. We showed that the genes for different modes of metabolism are expressed in overlapping but distinct subpopulations according to oxygen concentrations in a predictable fashion. The spatial transcriptomic technique described here has the potential to be used to map microbial activities across diverse environments.

Published

2022

35. Capturing an Early Gene Induction Event during Wood Decay by the Brown Rot Fungus Rhodonia placenta .

Author

Anderson CE, Zhang J, Markillie LM, Mitchell HD, Chrisler WB, Gaffrey MJ, Orr G, and Schilling JS

Subjects

Benzoquinones metabolism, Gene Expression, Oxidoreductases metabolism, Reactive Oxygen Species metabolism, Polyporales, Wood microbiology

Abstract

Brown rot fungi dominate wood decomposition in coniferous forests, and their carbohydrate-selective mechanisms are of commercial interest. Brown rot was recently described as a two-step, sequential mechanism orchestrated by fungi using differentially expressed genes (DEGs) and consisting of oxidation via reactive oxygen species (ROS) followed by enzymatic saccharification. There have been indications, however, that the initial oxidation step itself might require induction. To capture this early gene regulation event, here, we integrated fine-scale cryosectioning with whole-transcriptome sequencing to dissect gene expression at the single-hyphal-cell scale (tens of micrometers). This improved the spatial resolution 50-fold, relative to previous work, and we were able to capture the activity of the first 100 μm of hyphal front growth by Rhodonia placenta in aspen wood. This early decay period was dominated by delayed gene expression patterns as the fungus ramped up its mechanism. These delayed DEGs included many genes implicated in ROS pathways (lignocellulose oxidation [LOX]) that were previously and incorrectly assumed to be constitutively expressed. These delayed DEGs, which include those with and without predicted functions, also create a focused subset of target genes for functional genomics. However, this delayed pattern was not universal, with a few genes being upregulated immediately at the hyphal front. Most notably, this included a gene commonly implicated in hydroquinone and iron redox cycling: benzoquinone reductase. IMPORTANCE Earth's aboveground terrestrial biomass is primarily wood, and fungi dominate wood decomposition. Here, we studied these fungal pathways in a common "brown rot"-type fungus, Rhodonia placenta , that selectively extracts sugars from carbohydrates embedded within wood lignin. Using a space-for-time design to map fungal gene expression at the extreme hyphal front in wood, we made two discoveries. First, we found that many genes long assumed to be "on" (constitutively expressed) from the very beginning of decay were instead "off" before being upregulated, when mapped (via transcriptome sequencing [RNA-seq]) at a high resolution. Second, we found that the gene encoding benzoquinone reductase was "on" in incipient decay and quickly downregulated, implying a key role in "kick-starting" brown rot.

Published

2022

36. Methanosaeta and " Candidatus Velamenicoccus archaeovorus".

Author

Kizina J, Jordan SFA, Martens GA, Lonsing A, Probian C, Kolovou A, Santarella-Mellwig R, Rhiel E, Littmann S, Markert S, Stüber K, Richter M, Schweder T, and Harder J

Subjects

Archaea metabolism, Bacteria genetics, In Situ Hybridization, Fluorescence, Methanosarcinaceae metabolism, Oxidoreductases metabolism, Phylogeny, RNA, Ribosomal, 16S genetics, Sugars metabolism, Ferredoxins metabolism, Pyruvic Acid metabolism

Abstract

The phylum " Candidatus Omnitrophica" (candidate division OP3) is ubiquitous in anaerobic habitats but is currently characterized only by draft genomes from metagenomes and single cells. We had visualized cells of the phylotype OP3 LiM in methanogenic cultures on limonene as small epibiotic cells. In this study, we enriched OP3 cells by double density gradient centrifugation and obtained the first closed genome of an apparently clonal OP3 cell population by applying metagenomics and PCR for gap closure. Filaments of acetoclastic Methanosaeta , the largest morphotype in the culture community, contained empty cells, cells devoid of rRNA or of both rRNA and DNA, and dead cells according to transmission electron microscopy (TEM), thin-section TEM, scanning electron microscopy (SEM), catalyzed reporter deposition-fluorescence in situ hybridization (CARD-FISH), and LIVE/DEAD imaging. OP3 LiM cells were ultramicrobacteria (200 to 300 nm in diameter) and showed two physiological stages in CARD-FISH fluorescence signals: strong signals of OP3 LiM cells attached to Bacteria and to Archaea indicated many rRNA molecules and an active metabolism, whereas free-living OP3 cells had weak signals. Metaproteomics revealed that OP3 LiM lives with highly expressed secreted proteins involved in depolymerization and uptake of macromolecules and an active glycolysis and energy conservation by the utilization of pyruvate via a pyruvate:ferredoxin oxidoreductase and an Rnf complex (ferredoxin:NAD oxidoreductase). Besides sugar fermentation, a nucleotidyl transferase may contribute to energy conservation by phosphorolysis, the phosphate-dependent depolymerization of nucleic acids. Thin-section TEM showed distinctive structures of predation. Our study demonstrated a predatory metabolism for OP3 LiM cells, and therefore, we propose the name " Candidatus Velamenicoccus archaeovorus" gen. nov., sp. nov., for OP3 LiM. IMPORTANCE Epibiotic bacteria are known to live on and off bacterial cells. Here, we describe the ultramicrobacterial anaerobic epibiont OP3 LiM living on Archaea and Bacteria . We detected sick and dead cells of the filamentous archaeon Methanosaeta in slowly growing methanogenic cultures. OP3 LiM lives as a sugar fermenter, likely on polysaccharides from outer membranes, and has the genomic potential to live as a syntroph. The predatory lifestyle of OP3 LiM was supported by its genome, the first closed genome for the phylum " Candidatus Omnitrophica," and by images of cell-to-cell contact with prey cells. We propose naming OP3 LiM " Candidatus Velamenicoccus archaeovorus." Its metabolic versatility explains the ubiquitous presence of " Candidatus Omnitrophica" 3 in anoxic habitats and gives ultramicrobacterial epibionts an important role in the recycling and remineralization of microbial biomass. The removal of polysaccharides from outer membranes by ultramicrobacteria may also influence biological interactions between pro- and eukaryotes.

Published

2022

37. Characterization of Pyridomycin B Reveals the Formation of Functional Groups in Antimycobacterial Pyridomycin.

Author

Huang T, Zhou Z, Wei M, Chen L, Xiao Z, Deng Z, and Lin S

Subjects

Oligopeptides, Oxidoreductases metabolism, Peptide Synthases genetics, Peptide Synthases metabolism, Polyketide Synthases genetics, Polyketide Synthases metabolism, Mycobacterium tuberculosis genetics, Mycobacterium tuberculosis metabolism, Streptomyces metabolism

Abstract

Pyridomycin, a cyclodepsipeptide with potent antimycobacterial activity, specifically inhibits the InhA enoyl reductase of Mycobacterium tuberculosis. Structure-activity relationship studies indicated that the enolic acid moiety in the pyridomycin core system is an important pharmacophoric group, and the natural configuration of the C-10 hydroxyl contributes to the bioactivity of pyridomycin. The ring structure of pyridomycin was generated by the nonribosomal peptide synthetase (NRPS) and polyketide synthase (PKS) hybrid system (PyrE-PyrF-PyrG). Bioinformatics analysis reveals that short-chain dehydrogenase/reductase (SDR) family protein Pyr2 functions as a 3-oxoacyl acyl carrier protein (ACP) reductase in the pyridomycin pathway. Inactivation of pyr2 resulted in accumulation of pyridomycin B, a new pyridomycin analogue featured with enol moiety in pyridyl alanine moiety and a saturated 3-methylvaleric acid group. The elucidated structure of pyridomycin B suggests that rather than functioning as a post-tailoring enzyme, Pyr2 catalyzes ketoreduction to form the C-10 hydroxyl group in pyridyl alanine moiety and the double bond formation of the enolic acid moiety derived from isoleucine when the intermediate assembled by PKS-NRPS machinery is still tethered to the last NRPS module in a special energy-saving manner. Ser-His-Lys residues constitute the active site of Pyr2, which is different from the typically conserved Tyr-based catalytic triad in the majority of SDRs. Site-directed mutation identified that His154 in the active site is a critical residue for pyridomycin B production. These findings will improve our understanding of pyridomycin biosynthetic logic, identify the missing link for the double bound formation of enol ester in pyridomycin, and enable the creation of chemical diversity of pyridomycin derivatives. IMPORTANCE Tuberculosis (TB) is one of the world's leading causes of death by infection. Recently, pyridomycin, the antituberculous natural product from Streptomyces has garnered considerable attention for being determined as a target inhibitor of InhA enoyl reductase of Mycobacterium tuberculosis. In this study, we report a new pyridomycin analogue from mutant HTT12, demonstrate the essential role of a previously ignored gene pyr2 in pyridomycin biosynthetic pathway, and imply that Pyr2 functions as a trans ketoreductase (KR) contributing to the formation of functional groups of pyridomycin utilizing a distinct catalytic mechanism. As enol moiety are important for pharmaceutical activities of pyridomycin, our work would expand our understanding of the mechanism of SDR family proteins and set the stage for future bioengineering of new pyridomycin derivatives.

Published

2022

38. Mechanism of Pyridoxine 5'-Phosphate Accumulation in Pyridoxal 5'-Phosphate-Binding Protein Deficiency.

Author

Ito T, Ogawa H, Hemmi H, Downs DM, and Yoshimura T

Subjects

Carrier Proteins genetics, Escherichia coli genetics, Escherichia coli metabolism, Oxidoreductases metabolism, Phosphate-Binding Proteins metabolism, Phosphates metabolism, Pyridoxal Phosphate metabolism, Vitamin B 6 metabolism, Vitamins metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Pyridoxine metabolism

Abstract

The pyridoxal 5'-phosphate (PLP)-binding protein (PLPBP) plays an important role in vitamin B 6 homeostasis. Loss of this protein in organisms such as Escherichia coli and humans disrupts the vitamin B 6 pool and induces intracellular accumulation of pyridoxine 5'-phosphate (PNP), which is normally undetectable in wild-type cells. This accumulated PNP could affect diverse metabolic systems through the inhibition of some PLP-dependent enzymes. In this study, we investigated the as-yet-unclear mechanism of intracellular accumulation of PNP due to the loss of PLPBP protein encoded by yggS in E. coli. Genetic studies using several PLPBP-deficient strains of E. coli lacking a known enzyme(s) in the de novo or salvage pathways of vitamin B 6 , including pyridoxine (amine) 5'-phosphate oxidase (PNPO), PNP synthase, pyridoxal kinase, and pyridoxal reductase, demonstrated that neither the flux from the de novo pathway nor the salvage pathway solely contributed to the PNP accumulation caused by the PLPBP mutation. Studies of the strains lacking both PLPBP and PNPO suggested that PNP shares the same pool with PMP, and showed that PNP levels are impacted by PMP levels and vice versa. Here, we show that disruption of PLPBP perturbs PMP homeostasis, which may result in PNP accumulation in the PLPBP-deficient strains. IMPORTANCE A PLP-binding protein (PLPBP) from the conserved COG0325 family has recently been recognized as a key player in vitamin B 6 homeostasis in various organisms. Loss of PLPBP disrupts vitamin B 6 homeostasis and perturbs diverse metabolisms, including amino acid and α-keto acid metabolism. Accumulation of PNP is a characteristic phenotype of PLPBP deficiency and is suggested to be a potential cause of the pleiotropic effects, but the mechanism of this accumulation has been poorly understood. In this study, we show that fluxes for PNP synthesis/metabolism are not responsible for the accumulation of PNP. Our results indicate that PLPBP is involved in the homeostasis of pyridoxamine 5'-phosphate, and that its disruption may lead to the accumulation of PNP in PLPBP deficiency.

Published

2022

39. Heterologous Expression of Active Dehalobacter Respiratory Reductive Dehalogenases in Escherichia coli.

Author

Picott KJ, Flick R, and Edwards EA

Subjects

Bacteria metabolism, Biodegradation, Environmental, Vitamin B 12 metabolism, Escherichia coli genetics, Escherichia coli metabolism, Oxidoreductases metabolism

Abstract

Reductive dehalogenases (RDases) are a family of redox enzymes that are required for anaerobic organohalide respiration, a microbial process that is useful in bioremediation. Structural and mechanistic studies of these enzymes have been greatly impeded due to challenges in RDase heterologous expression, potentially because of their cobamide-dependence. There have been a few successful attempts at RDase production in unconventional heterologous hosts, but a robust method has yet to be developed. Here we outline a novel respiratory RDase expression system using Escherichia coli. The overexpression of E. coli's cobamide transport system, btu , and anaerobic expression conditions were found to be essential for production of active RDases from Dehalobacter -an obligate organohalide respiring bacterium. The expression system was validated on six enzymes with amino acid sequence identities as low as 28%. Dehalogenation activity was verified for each RDase by assaying cell extracts of small-scale expression cultures on various chlorinated substrates including chloroalkanes, chloroethenes, and hexachlorocyclohexanes. Two RDases, TmrA from Dehalobacter sp. UNSWDHB and HchA from Dehalobacter sp. HCH1, were purified by nickel affinity chromatography. Incorporation of the cobamide and iron-sulfur cluster cofactors was verified; however, the precise cobalamin incorporation could not be determined due to variance between methodologies, and the specific activity of TmrA was consistent with that of the native enzyme. The heterologous expression of respiratory RDases, particularly from obligate organohalide respiring bacteria, has been extremely challenging and unreliable. Here we present a relatively straightforward E. coli expression system that has performed well for a variety of Dehalobacter spp. RDases. IMPORTANCE Understanding microbial reductive dehalogenation is important to refine the global halogen cycle and to improve bioremediation of halogenated contaminants; however, studies of the family of enzymes responsible are limited. Characterization of reductive dehalogenase enzymes has largely eluded researchers due to the lack of a reliable and high-yielding production method. We are presenting an approach to express reductive dehalogenase enzymes from Dehalobacter , a key group of organisms used in bioremediation, in Escherichia coli. This expression system will propel the study of reductive dehalogenases by facilitating their production and isolation, allowing researchers to pursue more in-depth questions about the activity and structure of these enzymes. This platform will also provide a starting point to improve the expression of reductive dehalogenases from many other organisms.

Published

2022

40. Substrate Specificity of the 3-Methylmercaptopropionyl Coenzyme A Dehydrogenase (DmdC1) from Ruegeria pomeroyi DSS-3.

Author

Wang T, Shi H, and Whitman WB

Subjects

Bacterial Proteins metabolism, Substrate Specificity, Coenzyme A metabolism, Oxidoreductases metabolism, Rhodobacteraceae enzymology

Abstract

The acyl-coenzyme A (CoA) dehydrogenase family enzyme DmdC catalyzes the third step in the dimethylsulfoniopropionate (DMSP) demethylation pathway, the oxidation of 3-methylmercaptopropionyl-CoA (MMPA-CoA) to 3-methylthioacryloyl-CoA (MTA-CoA). To study its substrate specificity, the recombinant DmdC1 from Ruegeria pomeroyi was characterized. In addition to MMPA-CoA, the enzyme was highly active with short-chain acyl-CoAs, with K m values for MMPA-CoA, butyryl-CoA, valeryl-CoA, caproyl-CoA, heptanoyl-CoA, caprylyl-CoA, and isobutyryl-CoA of 36, 19, 7, 11, 14, 10, and 149 μM, respectively, and k cat values of 1.48, 0.40, 0.48, 0.73, 0.46, 0.23, and 0.01 s -1 , respectively. Among these compounds, MMPA-CoA was the best substrate. The high affinity of DmdC1 for its substrate supports the model for kinetic regulation of the demethylation pathway. In contrast to DmdB, which catalyzes the formation of MMPA-CoA from MMPA, CoA, and ATP, DmdC1 was not affected by physiological concentrations of potential effectors, such as DMSP, MMPA, ATP, and ADP. Thus, compared to the other enzymes of the DMSP demethylation pathway, DmdC1 has only minimal adaptations for DMSP metabolism compared to other enzymes in the same family with similar substrates, supporting the hypothesis that it evolved relatively recently from a short-chain acyl-CoA dehydrogenase involved in fatty acid oxidation. IMPORTANCE We report the kinetic properties of DmdC1 from the model organism R. pomeroyi and close an important gap in the literature. While the crystal structure of this enzyme was recently solved and its mechanism of action described (X. Shao, H. Y. Cao, F. Zhao, M. Peng, et al., Mol Microbiol 111:1057-1073, 2019, https://doi.org/10.1111/mmi.14211), its substrate specificity and sensitivity to potential effectors was never examined. We show that DmdC1 has a high affinity for other short-chain acyl-CoAs in addition to MMPA-CoA, which is the natural substrate in DMSP metabolism and is not affected by the potential effectors tested. This evidence supports the hypothesis that DmdC1 possesses few adaptations to DMSP metabolism and likely evolved relatively recently from a short-chain acyl-CoA dehydrogenase involved in fatty acid oxidation. This work is important because it expands our understanding of the adaptation of marine bacteria to the increased availability of DMSP about 250 million years ago.

Published

2022

41. MdaB and NfrA, Two Novel Reductases Important in the Survival and Persistence of the Major Enteropathogen Campylobacter jejuni.

Author

Nasher F, Taylor AJ, Elmi A, Lehri B, Ijaz UZ, Baker D, Goram R, Lynham S, Singh D, Stabler R, Kelly DJ, Gundogdu O, and Wren BW

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Flavins metabolism, Helicobacter pylori genetics, Helicobacter pylori metabolism, Oxidoreductases genetics, Quinones metabolism, Bacterial Proteins metabolism, Gene Expression Regulation, Bacterial physiology, Gene Expression Regulation, Enzymologic physiology, Helicobacter pylori enzymology, Oxidoreductases metabolism

Abstract

The paralogues RrpA and RrpB, which are members of the MarR family of DNA binding proteins, are important for the survival of the global bacterial foodborne pathogen Campylobacter jejuni under redox stress. We report that RrpA is a positive regulator of mdaB , encoding a flavin-dependent quinone reductase that contributes to the protection from redox stress mediated by structurally diverse quinones, while RrpB negatively regulates the expression of cj1555c (renamed nfrA for NADPH-flavin reductase A), encoding a flavin reductase. NfrA reduces riboflavin at a greater rate than its derivatives, suggesting that exogenous free flavins are the natural substrate. MdaB and NfrA both prefer NADPH as an electron donor. Cysteine substitution and posttranslational modification analyses indicated that RrpA and RrpB employ a cysteine-based redox switch. Complete genome sequence analyses revealed that mdaB is frequently found in Campylobacter and related Helicobacter spp., while nfrA is predominant in C. jejuni strains. Quinones and flavins are redox cycling agents secreted by a wide range of cell types that can form damaging superoxide by one-electron reactions. We propose a model for stress adaptation where MdaB and NfrA facilitate a two-electron reduction mechanism to the less toxic hydroquinones, thus aiding survival and persistence of this major pathogen. IMPORTANCE Changes in cellular redox potential result in alteration in the oxidation state of intracellular metabolites and enzymes; consequently, cells make adjustments that favor growth and survival. The work we present here answers some of the many questions that have remained elusive over the years of investigation into the enigmatic microaerophile bacterium Campylobacter jejuni. We employed molecular approaches to understand the regulation mechanisms and functional analyses to reveal the roles of two novel quinone and flavin reductases; both serve as major pools of cellular redox-active molecules. This work extends our knowledge on bacterial redox sensing mechanisms and the significance of hemostasis.

Published

2022

42. Loss-of-Function ROX1 Mutations Suppress the Fluconazole Susceptibility of upc2A Δ Mutation in Candida glabrata, Implicating Additional Positive Regulators of Ergosterol Biosynthesis.

Author

Ollinger TL, Vu B, Murante D, Parker JE, Simonicova L, Doorley L, Stamnes MA, Kelly SL, Rogers PD, Moye-Rowley WS, and Krysan DJ

Subjects

Antifungal Agents pharmacology, Candida glabrata genetics, Candida glabrata metabolism, Ergosterol genetics, Gene Expression Regulation, Fungal, Methyltransferases genetics, Methyltransferases metabolism, Mutation, Oxidoreductases genetics, Oxidoreductases metabolism, Repressor Proteins metabolism, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Trans-Activators metabolism, Candida glabrata drug effects, Ergosterol biosynthesis, Fluconazole pharmacology, Repressor Proteins genetics, Saccharomyces cerevisiae Proteins genetics, Trans-Activators genetics

Abstract

Two of the major classes of antifungal drugs in clinical use target ergosterol biosynthesis. Despite its importance, our understanding of the transcriptional regulation of ergosterol biosynthesis genes in pathogenic fungi is essentially limited to the role of hypoxia and sterol-stress-induced transcription factors such as Upc2 and Upc2A as well as homologs of sterol response element binding (SREB) factors. To identify additional regulators of ergosterol biosynthesis in Candida glabrata, an important human fungal pathogen with reduced susceptibility to ergosterol biosynthesis inhibitors relative to other Candida spp., we used a serial passaging strategy to isolate suppressors of the fluconazole hypersusceptibility of a upc2A Δ deletion mutant. This led to the identification of loss-of-function mutations in two genes: ROX1 , the homolog of a hypoxia gene transcriptional suppressor in Saccharomyces cerevisiae, and CST6 , a transcription factor that is involved in the regulation of carbon dioxide response in C. glabrata. Here, we describe a detailed analysis of the genetic interaction of ROX1 and UPC2A . In the presence of fluconazole, loss of Rox1 function restores ERG11 expression to the upc2A Δ mutant and inhibits the expression of ERG3 and ERG6 , leading to increased levels of ergosterol and decreased levels of the toxic sterol 14α methyl-ergosta-8,24(28)-dien-3β, 6α-diol, relative to the upc2A Δ mutant. Our observations establish that Rox1 is a negative regulator of ERG gene biosynthesis and indicate that a least one additional positive transcriptional regulator of ERG gene biosynthesis must be present in C. glabrata. IMPORTANCE Candida glabrata is one of the most important human fungal pathogens and has reduced susceptibility to azole-class inhibitors of ergosterol biosynthesis. Although ergosterol is the target of two of the three classes of antifungal drugs, relatively little is known about the regulation of this critical cellular pathway. Sterols are both essential components of the eukaryotic plasma membrane and potential toxins; therefore, sterol homeostasis is critical for cell function. Here, we identified two new negative regulators in C. glabrata of ergosterol ( ERG ) biosynthesis gene expression. Our results also indicate that in addition to Upc2A, the only known activator of ERG genes, additional positive regulators of this pathway must exist.

Published

2021

43. Aromatic Dimer Dehydrogenases from Novosphingobium aromaticivorans Reduce Monoaromatic Diketones.

Author

Linz AM, Ma Y, Perez JM, Myers KS, Kontur WS, Noguera DR, and Donohue TJ

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Industrial Microbiology, Oxidoreductases genetics, Ketones metabolism, Lignin metabolism, Oxidoreductases metabolism, Sphingomonadaceae enzymology

Abstract

Lignin is a potential source of valuable chemicals, but its chemical depolymerization results in a heterogeneous mixture of aromatics and other products. Microbes could valorize depolymerized lignin by converting multiple substrates into one or a small number of products. In this study, we describe the ability of Novosphingobium aromaticivorans to metabolize 1-(4-hydroxy-3-methoxyphenyl)propane-1,2-dione (G-diketone), an aromatic Hibbert diketone that is produced during formic acid-catalyzed lignin depolymerization. By assaying genome-wide transcript levels from N. aromaticivorans during growth on G-diketone and other chemically-related aromatics, we hypothesized that the Lig dehydrogenases, previously characterized as oxidizing β-O-4 linkages in aromatic dimers, were involved in G-diketone metabolism by N. aromaticivorans. Using purified N. aromaticivorans Lig dehydrogenases, we found that LigL, LigN, and LigD each reduced the Cα ketone of G-diketone in vitro but with different substrate specificities and rates. Furthermore, LigL, but not LigN or LigD, also reduced the Cα ketone of 2-hydroxy-1-(4-hydroxy-3-methoxyphenyl)propan-1-one (GP-1) in vitro , a derivative of G-diketone with the Cβ ketone reduced, when GP-1 was provided as a substrate. The newly identified activity of these Lig dehydrogenases expands the potential range of substrates utilized by N. aromaticivorans beyond what has been previously recognized. This is beneficial both for metabolizing a wide range of natural and non-native depolymerized lignin substrates and for engineering microbes and enzymes that are active with a broader range of aromatic compounds. IMPORTANCE Lignin is a major plant polymer composed of aromatic units that have value as chemicals. However, the structure and composition of lignin have made it difficult to use this polymer as a renewable source of industrial chemicals. Bacteria like Novosphingobium aromaticivorans have the potential to make chemicals from lignin not only because of their natural ability to metabolize a variety of aromatics but also because there are established protocols to engineer N. aromaticivorans strains to funnel lignin-derived aromatics into valuable products. In this work, we report a newly discovered activity of previously characterized dehydrogenase enzymes with a chemically modified by-product of lignin depolymerization. We propose that the activity of N. aromaticivorans enzymes with both native lignin aromatics and those produced by chemical depolymerization will expand opportunities for producing industrial chemicals from the heterogenous components of this abundant plant polymer.

Published

2021

44. Identification of Copper-Containing Oxidoreductases in the Secretomes of Three Colletotrichum Species with a Focus on Copper Radical Oxidases for the Biocatalytic Production of Fatty Aldehydes.

Author

Ribeaucourt D, Saker S, Navarro D, Bissaro B, Drula E, Correia LO, Haon M, Grisel S, Lapalu N, Henrissat B, O'Connell RJ, Lambert F, Lafond M, and Berrin JG

Subjects

Alcohols, Aldehydes, Fungal Proteins genetics, Fungal Proteins metabolism, Oxidoreductases genetics, Secretome, Colletotrichum enzymology, Colletotrichum genetics, Copper, Fatty Acids biosynthesis, Oxidoreductases metabolism

Abstract

Copper radical alcohol oxidases (CRO-AlcOx), which have been recently discovered among fungal phytopathogens, are attractive for the production of fragrant fatty aldehydes. With the initial objective to investigate the secretion of CRO-AlcOx by natural fungal strains, we undertook time course analyses of the secretomes of three Colletotrichum species (C. graminicola, C. tabacum, and C. destructivum) using proteomics. The addition of a copper-manganese-ethanol mixture in the absence of any plant-biomass mimicking compounds to Colletotrichum cultures unexpectedly induced the secretion of up to 400 proteins, 29 to 52% of which were carbohydrate-active enzymes (CAZymes), including a wide diversity of copper-containing oxidoreductases from the auxiliary activities (AA) class (AA1, AA3, AA5, AA7, AA9, AA11, AA12, AA13, and AA16). Under these specific conditions, while a CRO-glyoxal oxidase from the AA5_1 subfamily was among the most abundantly secreted proteins, the targeted AA5_2 CRO-AlcOx were secreted at lower levels, suggesting heterologous expression as a more promising strategy for CRO-AlcOx production and utilization. C. tabacum and C. destructivum CRO-AlcOx were thus expressed in Pichia pastoris, and their preference toward both aromatic and aliphatic primary alcohols was assessed. The CRO-AlcOx from C. destructivum was further investigated in applied settings, revealing a full conversion of C 6 and C 8 alcohols into their corresponding fragrant aldehydes. IMPORTANCE In the context of the industrial shift toward greener processes, the biocatalytic production of aldehydes is of utmost interest owing to their importance for their use as flavor and fragrance ingredients. Copper radical alcohol oxidases (CRO-AlcOx) have the potential to become platform enzymes for the oxidation of alcohols to aldehydes. However, the secretion of CRO-AlcOx by natural fungal strains has never been explored, while the use of crude fungal secretomes is an appealing approach for industrial applications to alleviate various costs pertaining to biocatalyst production. While investigating this primary objective, the secretomics studies revealed unexpected results showing that under the oxidative stress conditions we probed, Colletotrichum species can secrete a broad diversity of copper-containing enzymes (laccases, sugar oxidoreductases, and lytic polysaccharide monooxygenases [LPMOs]) usually assigned to "plant cell wall degradation," despite the absence of any plant-biomass mimicking compound. However, in these conditions, only small amounts of CRO-AlcOx were secreted, pointing out recombinant expression as the most promising path for their biocatalytic application.

Published

2021

45. Porcine Circovirus 2 Manipulates the PERK-ERO1α Axis of the Endoplasmic Reticulum To Favor Its Replication by Derepressing Viral DNA from HMGB1 Sequestration within Nuclei.

Author

Sun R, Deng Z, Han X, Zhang Y, Zhou Y, Shan Y, Fang W, and Li X

Subjects

Animals, Capsid Proteins chemistry, Capsid Proteins metabolism, Cell Line, Cysteine metabolism, DNA Replication, Enzyme Activation, Reactive Oxygen Species metabolism, Swine, Up-Regulation, Viral Proteins metabolism, Virus Replication, Cell Nucleus metabolism, Circovirus physiology, DNA, Viral metabolism, Endoplasmic Reticulum metabolism, HMGB1 Protein metabolism, Oxidoreductases metabolism, eIF-2 Kinase metabolism

Abstract

Porcine circovirus type 2 (PCV2) causes several disease syndromes in grower pigs. PCV2 infection triggers endoplasmic reticulum (ER) stress, autophagy, and oxidative stress, all of which support PCV2 replication. We have recently reported that nuclear HMGB1 is an anti-PCV2 factor by binding to viral genomic DNA. However, how PCV2 manipulates host cell responses to favor its replication has not been explored. Here, we demonstrate that PCV2 infection increased expression of ERO1α, generation of reactive oxygen species (ROS), and nucleocytoplasmic migration of HMGB1 via protein kinase R-like endoplasmic reticulum kinase (PERK) activation in PK-15 cells. Inhibition of PERK or ERO1α repressed ROS production in PCV2-infected cells and increased HMGB1 retention within nuclei. These findings indicate that PCV2-induced activation of the PERK-ERO1α axis would lead to enhanced generation of ROS sufficient to decrease HMGB1 retention in the nuclei, thus derepressing viral DNA from HMGB1 sequestration. The viral Rep and Cap proteins were able to induce PERK-ERO1α-mediated ROS accumulation. Cysteine residues 107 and 305 of Rep or 108 of Cap played important roles in PCV2-induced PERK activation and distribution of HMGB1. Of the mutant viruses, only the mutant PCV2 with substitution of all three cysteine residues failed to activate PERK with reduced ROS generation and decreased nucleocytoplasmic migration of HMGB1. Collectively, this study offers novel insight into the mechanism of enhanced viral replication in which PCV2 manipulates ER to perturb its redox homeostasis via the PERK-ERO1α axis, and the ER-sourced ROS from oxidative folding is sufficient to reduce HMGB1 retention in the nuclei-hence the release of HMGB1-bound viral DNA for replication. IMPORTANCE Considering the fact that clinical porcine circovirus-associated diseases (PCVAD) mostly results from activation of latent PCV2 infection by confounding factors such as coinfection or environmental stresses, we propose that such confounding factors might impose oxidative stress to the animals, where PCV2 in infected cells might utilize the elevated reactive oxygen species (ROS) to promote HMGB1 migration out of nuclei in favor of its replication. An animal infection model with a particular stressor could be approached with or without antioxidant treatment to examine the relationship among the stressor, ROS level, HMGB1 distribution in target tissues, virus replication, and severity of PCVAD. This will help decide the use of antioxidants in the feeding regime on pig farms that suffer from PCVAD. Further investigation could examine if similar strategies are employed by DNA viruses, such as PCV3 and BFDV and if there is cross talk among endoplasmic reticulum (ER) stress, autophagy/mitophagy, and mitochondrial-sourced ROS in favor of PCV2 replication.

Published

2021

46. Change in Cofactor Specificity of Oxidoreductases by Adaptive Evolution of an Escherichia coli NADPH-Auxotrophic Strain.

Author

Bouzon M, Döring V, Dubois I, Berger A, Stoffel GMM, Calzadiaz Ramirez L, Meyer SN, Fouré M, Roche D, Perret A, Erb TJ, Bar-Even A, and Lindner SN

Subjects

Carbon metabolism, Coenzymes genetics, Escherichia coli genetics, Escherichia coli Proteins, Kinetics, Malate Dehydrogenase metabolism, NAD metabolism, Oxidoreductases genetics, Coenzymes metabolism, Escherichia coli enzymology, Escherichia coli metabolism, Evolution, Molecular, NADP metabolism, Oxidoreductases metabolism

Abstract

The nicotinamide cofactor specificity of enzymes plays a key role in regulating metabolic processes and attaining cellular homeostasis. Multiple studies have used enzyme engineering tools or a directed evolution approach to switch the cofactor preference of specific oxidoreductases. However, whole-cell adaptation toward the emergence of novel cofactor regeneration routes has not been previously explored. To address this challenge, we used an Escherichia coli NADPH-auxotrophic strain. We continuously cultivated this strain under selective conditions. After 500 to 1,100 generations of adaptive evolution using different carbon sources, we isolated several strains capable of growing without an external NADPH source. Most isolated strains were found to harbor a mutated NAD + -dependent malic enzyme (MaeA). A single mutation in MaeA was found to switch cofactor specificity while lowering enzyme activity. Most mutated MaeA variants also harbored a second mutation that restored the catalytic efficiency of the enzyme. Remarkably, the best MaeA variants identified this way displayed overall superior kinetics relative to the wild-type variant with NAD + . In other evolved strains, the dihydrolipoamide dehydrogenase (Lpd) was mutated to accept NADP + , thus enabling the pyruvate dehydrogenase and 2-ketoglutarate dehydrogenase complexes to regenerate NADPH. Interestingly, no other central metabolism oxidoreductase seems to evolve toward reducing NADP + , which we attribute to several biochemical constraints, including unfavorable thermodynamics. This study demonstrates the potential and biochemical limits of evolving oxidoreductases within the cellular context toward changing cofactor specificity, further showing that long-term adaptive evolution can optimize enzyme activity beyond what is achievable via rational design or directed evolution using small libraries. IMPORTANCE In the cell, NAD(H) and NADP(H) cofactors have different functions. The former mainly accepts electrons from catabolic reactions and carries them to respiration, while the latter provides reducing power for anabolism. Correspondingly, the ratio of the reduced to the oxidized form differs for NAD + (low) and NADP + (high), reflecting their distinct roles. We challenged the flexibility of E. coli 's central metabolism in multiple adaptive evolution experiments using an NADPH-auxotrophic strain. We found several mutations in two enzymes, changing the cofactor preference of malic enzyme and dihydrolipoamide dehydrogenase. Upon deletion of their corresponding genes we performed additional evolution experiments which did not lead to the emergence of any additional mutants. We attribute this restricted number of mutational targets to intrinsic thermodynamic barriers; the high ratio of NADPH to NADP + limits metabolic redox reactions that can regenerate NADPH, mainly by mass action constraints.

Published

2021

47. N -(4-Hydroxyphenyl) Retinamide Suppresses SARS-CoV-2 Spike Protein-Mediated Cell-Cell Fusion by a Dihydroceramide Δ4-Desaturase 1-Independent Mechanism.

Author

Hayashi Y, Tsuchiya K, Yamamoto M, Nemoto-Sasaki Y, Tanigawa K, Hama K, Ueda Y, Tanikawa T, Gohda J, Maeda K, Inoue JI, and Yamashita A

Subjects

Cell Fusion, Cell Membrane genetics, Gene Knockout Techniques, HEK293 Cells, Humans, Membrane Fluidity genetics, Oxidoreductases deficiency, SARS-CoV-2 genetics, Spike Glycoprotein, Coronavirus genetics, Cell Membrane metabolism, Fenretinide pharmacology, Membrane Fluidity drug effects, Oxidoreductases metabolism, SARS-CoV-2 metabolism, Spike Glycoprotein, Coronavirus metabolism

Abstract

The membrane fusion between the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and host cells is essential for the initial step of infection; therefore, the host cell membrane components, including sphingolipids, influence the viral infection. We assessed several inhibitors of the enzymes pertaining to sphingolipid metabolism, against SARS-CoV-2 spike protein (S)-mediated cell-cell fusion and viral infection. N -(4-Hydroxyphenyl) retinamide (4-HPR), an inhibitor of dihydroceramide Δ4-desaturase 1 (DES1), suppressed cell-cell fusion and viral infection. The analysis of sphingolipid levels revealed that the inhibition efficiencies of cell-cell fusion and viral infection in 4-HPR-treated cells were consistent with an increased ratio of saturated sphinganine-based lipids to total sphingolipids. We investigated the relationship of DES1 with the inhibition efficiencies of cell-cell fusion. The changes in the sphingolipid profile induced by 4-HPR were mitigated by the supplementation with exogenous cell-permeative ceramide; however, the reduced cell-cell fusion could not be reversed. The efficiency of cell-cell fusion in DES1 knockout (KO) cells was at a level comparable to that in wild-type (WT) cells; however, the ratio of saturated sphinganine-based lipids to the total sphingolipids was higher in DES1 KO cells than in WT cells. 4-HPR reduced cell membrane fluidity without any significant effects on the expression or localization of angiotensin-converting enzyme 2, the SARS-CoV-2 receptor. Therefore, 4-HPR suppresses SARS-CoV-2 S-mediated membrane fusion through a DES1-independent mechanism, and this decrease in membrane fluidity induced by 4-HPR could be the major cause for the inhibition of SARS-CoV-2 infection. IMPORTANCE Sphingolipids could play an important role in SARS-CoV-2 S-mediated membrane fusion with host cells. We studied the cell-cell fusion using SARS-CoV-2 S-expressing cells and sphingolipid-manipulated target cells, with an inhibitor of the sphingolipid metabolism. 4-HPR (also known as fenretinide) is an inhibitor of DES1, and it exhibits antitumor activity and suppresses cell-cell fusion and viral infection. 4-HPR suppresses membrane fusion through a decrease in membrane fluidity, which could possibly be the cause for the inhibition of SARS-CoV-2 infection. There is accumulating clinical data on the safety of 4-HPR. Therefore, it could be a potential candidate drug against COVID-19.

Published

2021

48. GCN4 Regulates Secondary Metabolism through Activation of Antioxidant Gene Expression under Nitrogen Limitation Conditions in Ganoderma lucidum.

Author

Lian L, Wang L, Song S, Zhu J, Liu R, Shi L, Ren A, and Zhao M

Subjects

Fungal Proteins genetics, Glutathione metabolism, Oxidoreductases genetics, Oxidoreductases metabolism, Reactive Oxygen Species metabolism, Reishi growth & development, Secondary Metabolism, Transcription Factors genetics, Fungal Proteins metabolism, Gene Expression Regulation, Fungal, Nitrogen metabolism, Reishi genetics, Reishi metabolism, Transcription Factors metabolism

Abstract

Nitrogen limitation has been widely reported to affect the growth and development of fungi, and the transcription factor GCN4 (general control nonderepressible 4) is involved in nitrogen restriction. Here, we found that nitrogen limitation highly induced the expression of GCN4 and promoted the synthesis of ganoderic acid (GA), an important secondary metabolite in Ganoderma lucidum. The activated GCN4 is involved in regulating GA biosynthesis. In addition, the accumulation of reactive oxygen species (ROS) also affects the synthesis of GA under nitrogen restrictions. The silencing of the gcn4 gene led to further accumulation of ROS and increased the content of GA. Further studies found that GCN4 activated the transcription of antioxidant enzyme biosynthesis genes gr , gst2 , and cat3 (encoding glutathione reductase, glutathione S -transferase, and catalase, respectively) through direct binding to the promoter of these genes to reduce the ROS accumulation. In conclusion, our study found that GCN4 directly interacts with the ROS signaling pathway to negatively regulate GA biosynthesis under nitrogen-limiting conditions. This provides an essential insight into the understanding of GCN4 transcriptional regulation of the ROS signaling pathway and enriches the knowledge of nitrogen regulation mechanisms in fungal secondary metabolism of G. lucidum. IMPORTANCE Nitrogen has been widely reported to regulate secondary metabolism in fungi. Our study assessed the specific nitrogen regulatory mechanisms in Ganoderma lucidum. We found that GCN4 directly interacts with the ROS signaling pathway to negatively regulate GA biosynthesis under nitrogen-limiting conditions. Our research highlights a novel insight that GCN4, the nitrogen utilization regulator, participates in secondary metabolism through ROS signal regulation. In addition, this also provides a theoretical foundation for exploring the regulation of other physiological processes by GCN4 through ROS in fungi.

Published

2021

49. Transcriptomic and Metabolomic Responses to Carbon and Nitrogen Sources in Methylomicrobium album BG8.

Author

Sugden S, Lazic M, Sauvageau D, and Stein LY

Subjects

Carbohydrate Metabolism drug effects, Carbon, Formaldehyde metabolism, Glutathione metabolism, Metabolome drug effects, Metabolomics, Methylococcaceae genetics, Methylococcaceae growth & development, Methylococcaceae metabolism, Nitrogen, Oxidoreductases metabolism, Phospholipids metabolism, Ribosomes metabolism, Transcriptome drug effects, Ammonium Compounds pharmacology, Methane pharmacology, Methanol pharmacology, Methylococcaceae drug effects, Nitrates pharmacology

Abstract

Methanotrophs use methane as their sole carbon and energy source and represent an attractive platform for converting single-carbon feedstocks into value-added compounds. Optimizing these species for biotechnological applications involves choosing an optimal growth substrate based on an understanding of cellular responses to different nutrients. Although many studies of methanotrophs have examined growth rate, yield, and central carbon flux in cultures grown with different carbon and nitrogen sources, few studies have examined more global cellular responses to different media. Here, we evaluated global transcriptomic and metabolomic profiles of Methylomicrobium album BG8 when grown with methane or methanol as the carbon source and nitrate or ammonium as the nitrogen source. We identified five key physiological changes during growth on methanol: M. album BG8 cultures upregulated transcripts for the Entner-Doudoroff and pentose phosphate pathways for sugar catabolism, produced more ribosomes, remodeled the phospholipid membrane, activated various stress response systems, and upregulated glutathione-dependent formaldehyde detoxification. When using ammonium, M. album BG8 upregulated hydroxylamine dehydrogenase ( haoAB ) and overall central metabolic activity, whereas when using nitrate, cultures upregulated genes for nitrate assimilation and conversion. Overall, we identified several nutrient source-specific responses that could provide a valuable basis for future research on the biotechnological optimization of these species. IMPORTANCE Methanotrophs are gaining increasing interest for their biotechnological potential to convert single-carbon compounds into value-added products such as industrial chemicals, fuels, and bioplastics. Optimizing these species for biotechnological applications requires a detailed understanding of how cellular activity and metabolism vary across different growth substrates. Although each of the two most commonly used carbon sources (methane or methanol) and nitrogen sources (ammonium or nitrate) in methanotroph growth media have well-described advantages and disadvantages in an industrial context, their effects on global cellular activity remain poorly characterized. Here, we comprehensively describe the transcriptomic and metabolomic changes that characterize the growth of an industrially promising methanotroph strain on multiple combinations of carbon and nitrogen sources. Our results represent a more holistic evaluation of cellular activity than previous studies of core metabolic pathways and provide a valuable basis for the future biotechnological optimization of these species.

Published

2021

50. Rid Enhances the 6-Hydroxypseudooxynicotine Dehydrogenase Reaction in Nicotine Degradation by Agrobacterium tumefaciens S33.

Author

Shang J, Wang X, Zhang M, Wang R, Zhang C, Huang H, and Wang S

Subjects

Agrobacterium tumefaciens metabolism, Bacterial Proteins metabolism, Oxidoreductases metabolism, Agrobacterium tumefaciens genetics, Bacterial Proteins genetics, Nicotine metabolism, Oxidoreductases genetics

Abstract

Agrobacterium tumefaciens S33 degrades nicotine through a hybrid of the pyridine and pyrrolidine pathways. The oxidation of 6-hydroxypseudooxynicotine to 6-hydroxy-3-succinoyl-semialdehyde-pyridine by 6-hydroxypseudooxynicotine dehydrogenase (Pno) is an important step in the breakdown of the N -heterocycle in this pathway. Although Pno has been characterized, the reaction is not fully understood; what is known is that it starts at a high speed followed by a rapid drop in the reaction rate, leading to the formation of a very small amount of product. In this study, we speculated that an unstable imine intermediate that is toxic with regard to the metabolism is produced in the reaction. We found that a Rid protein (designated Rid-NC) encoded by a gene in the nicotine-degrading gene cluster enhanced the reaction. Rid is a widely distributed family of small proteins with various functions, and some subfamilies have deaminase activity to eliminate the toxicity of the reactive intermediate, imine. Biochemical analyses showed that Rid-NC relieved the toxicity of the presumed imine intermediate produced in the Pno reaction and that, in the presence of Rid-NC, Pno maintained a high level of activity and the amount of the reaction product was increase by at least 5-fold. Disruption of the rid -NC gene led to slower growth of strain S33 on nicotine. The mechanism of Rid-NC-mediated detoxification of the imine intermediate was discussed. A phylogenetic analysis indicated that Rid-NC belongs to the rarely studied Rid6 subfamily. These results further our understanding of the biochemical mechanism of nicotine degradation and provide new insights into the function of the Rid6 subfamily proteins. IMPORTANCE Rid is a family of proteins that participate in metabolite damage repair and is widely distributed in different organisms. In this study, we found that Rid-NC, which belongs to the Rid6 subfamily, promoted the 6-hydroxypseudooxynicotine dehydrogenase (Pno) reaction in the hybrid of the pyridine and pyrrolidine pathways for nicotine degradation by Agrobacterium tumefaciens S33. Rid-NC hydrolyzed the presumed reactive imine intermediate produced in the reaction to remove its toxicity on Pno. The finding furthers our understanding of the metabolic process of the toxic N -heterocyclic aromatic compounds in microorganisms. This study demonstrated that the Rid family of proteins also functions in the metabolism of N -heterocyclic aromatic alkaloids, in addition to the amino acid metabolism, and that Rid6-subfamily proteins also have deaminase activity, similar to the RidA subfamily. The ability of reactive imines to damage a non-pyridoxal-5'-phosphate-dependent enzyme was reported. This study provides new insights into the function of the Rid family of proteins., (Copyright © 2021 American Society for Microbiology.)

Published

2021