644 results on '"Malate synthase"'
Search Results
2. Phosphoglycolate salvage in a chemolithoautotroph using the Calvin cycle
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Axel Fischer, Giovanni Scarinci, Avi I. Flamholz, Oliver Lenz, Arren Bar-Even, Nico J. Claassens, William Newell, and Stefan Frielingsdorf
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Cyanobacteria ,Chemoautotrophic Growth ,Cupriavidus necator ,Glyoxylate cycle ,Malates ,Microbiology ,glycolate secretion ,Carbon Cycle ,Bacterial Proteins ,Acetyl Coenzyme A ,Malate synthase ,Life Science ,Photosynthesis ,CO2 fixation ,Multidisciplinary ,biology ,Chemistry ,Carbon fixation ,RuBisCO ,Malate Synthase ,Metabolism ,Biological Sciences ,glycolate oxidation ,biology.organism_classification ,Glycolates ,hydrogen-oxidizing bacteria ,Biochemistry ,biology.protein ,Photorespiration ,Oxidation-Reduction - Abstract
Significance The Calvin cycle is the most important carbon fixation pathway in the biosphere. However, its carboxylating enzyme Rubisco also accepts oxygen, thus producing 2-phosphoglycolate. Phosphoglycolate salvage pathways were extensively studied in photoautotrophs but remain uncharacterized in chemolithoautotrophs using the Calvin cycle. Here, we study phosphoglycolate salvage in the chemolithoautotrophic model bacterium Cupriavidus necator H16. We demonstrate that this bacterium mainly reassimilates 2-phosphoglycolate via the glycerate pathway. Upon disruption of this pathway, a secondary route, which we term the malate cycle, supports photorespiration by completely oxidizing 2-phosphoglycolate to CO2. While the malate cycle was not previously known to metabolize 2-phosphoglycolate in nature, a bioinformatic analysis suggests that it may support phosphoglycolate salvage in diverse chemoautotrophic bacteria., Carbon fixation via the Calvin cycle is constrained by the side activity of Rubisco with dioxygen, generating 2-phosphoglycolate. The metabolic recycling of phosphoglycolate was extensively studied in photoautotrophic organisms, including plants, algae, and cyanobacteria, where it is referred to as photorespiration. While receiving little attention so far, aerobic chemolithoautotrophic bacteria that operate the Calvin cycle independent of light must also recycle phosphoglycolate. As the term photorespiration is inappropriate for describing phosphoglycolate recycling in these nonphotosynthetic autotrophs, we suggest the more general term “phosphoglycolate salvage.” Here, we study phosphoglycolate salvage in the model chemolithoautotroph Cupriavidus necator H16 (Ralstonia eutropha H16) by characterizing the proxy process of glycolate metabolism, performing comparative transcriptomics of autotrophic growth under low and high CO2 concentrations, and testing autotrophic growth phenotypes of gene deletion strains at ambient CO2. We find that the canonical plant-like C2 cycle does not operate in this bacterium, and instead, the bacterial-like glycerate pathway is the main route for phosphoglycolate salvage. Upon disruption of the glycerate pathway, we find that an oxidative pathway, which we term the malate cycle, supports phosphoglycolate salvage. In this cycle, glyoxylate is condensed with acetyl coenzyme A (acetyl-CoA) to give malate, which undergoes two oxidative decarboxylation steps to regenerate acetyl-CoA. When both pathways are disrupted, autotrophic growth is abolished at ambient CO2. We present bioinformatic data suggesting that the malate cycle may support phosphoglycolate salvage in diverse chemolithoautotrophic bacteria. This study thus demonstrates a so far unknown phosphoglycolate salvage pathway, highlighting important diversity in microbial carbon fixation metabolism.
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- 2020
3. Correlation of dicarboxylic acid cycle with tricarboxylic acid cycle in highly productive pigs
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V. P. Galochkina, V. О. Lemiasheuski, N. V. Belova, I. V. Kutin, A. V. Agafonova, K. S. Ostrenko, and A. N. Ovcharova
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0301 basic medicine ,biology ,Chemistry ,Glyoxylate cycle ,Dehydrogenase ,General Medicine ,Peroxisome ,Peroxisome localization ,Malate dehydrogenase ,Citric acid cycle ,03 medical and health sciences ,chemistry.chemical_compound ,030104 developmental biology ,0302 clinical medicine ,Biochemistry ,Malate synthase ,biology.protein ,Anaplerotic reactions ,030217 neurology & neurosurgery - Abstract
The paper is the fundamental beginning of research series aimed at understanding the processes associated with high performance in higher animals. The research aim is to study correlation of dicarboxylic acid cycle with tricarboxylic acid cycle with establishment of activity and dislocation of enzymes, confirming the hypothesis of availability and active metabolic participation of peroxisome in highly productive animals. Research was conducted on the basis of the VNIIFBiP animal vivarium in 2019 with a group of piglets of the Irish Landrace breed (n = 10). After slaughter at the age of 210 days, the nuclear (with large tissue particles), mitochondrial and postmitochondrial fractions of the liver were studied with assessment of succinate dehydrogenase and activity of other dehydrogenes of the Krebs cycle. It was found that peroxisomes act as universal agents of communication and cooperation, and microtelets are able to generate various chemical signals that carry information, to control and arrange a number of mechanisms in the metabolic processes in the body. Despite the fact that the Krebs cycle dehydrogenases are considered mitochondrial enzymes, the experiment showed an increase in activity of priruvate dehydrogenase (P > 0.1), isocitrate dehydrogenase (0.1 > P > 0.05) and malate dehydrogenase (0.1 > P > 0.05), which, when comparing the mitochondrial and postmitochondrial fractions, indicates a higher activity of peroxisomal fractions. The peroxisome localization place is the postmitochondrial fraction, and the lower layer contains larger peroxisomes to a greater extent, while the upper layer contains smaller ones. It was found that indicator enzymes of glyoxylate cycle isocitratliase and malate synthase exhibit catalytic activity in the peroxisomal fraction of liver of highly productive pigs. The obtained data on functioning of key glyoxylate cycle enzymes and their intracellular compartmentalization in highly productive pigs allow learning more about the specifics of metabolism and its regulation processes. Application of this knowledge in practice opens up prospects for rationalizing the production of livestock products of increased quantity, improved quality with less feed, labor and financial resources spent.
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- 2020
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4. Adaption and Degradation Strategies of Methylotrophic 1,4-Dioxane Degrading Strain Xanthobacter sp. YN2 Revealed by Transcriptome-Scale Analysis
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Haijuan Guo, Delin Su, Yingning Wang, Fang Ma, Jixian Yang, and Lan Yu
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QH301-705.5 ,Glyoxylate cycle ,biodegradation ,Catalysis ,Inorganic Chemistry ,Transcriptome ,chemistry.chemical_compound ,methylotroph ,Malate synthase ,Physical and Theoretical Chemistry ,Biology (General) ,Molecular Biology ,QD1-999 ,Spectroscopy ,biology ,Catabolism ,Organic Chemistry ,General Medicine ,1,4-Dioxane ,Metabolism ,1,4-dioxane ,biology.organism_classification ,adaption ,transcriptome ,Computer Science Applications ,Quorum sensing ,Chemistry ,Biochemistry ,chemistry ,biology.protein ,Methylotroph - Abstract
Biodegradation of 1,4-dioxane (dioxane) contamination has gained much attention for decades. In our previous work, we isolated a highly efficient dioxane degrader, Xanthobacter sp. YN2, but the underlying mechanisms of its extraordinary degradation performance remained unresolved. In this study, we performed a comparative transcriptome analysis of YN2 grown on dioxane and citrate to elucidate its genetic degradation mechanism and investigated the transcriptomes of different dioxane degradation stages (T0, T24, T48). We also analyzed the transcriptional response of YN2 over time during which the carbon source switched from citrate to dioxane. The results indicate that strain YN2 was a methylotroph, which provides YN2 a major advantage as a pollutant degrader. A large number of genes involved in dioxane metabolism were constitutively expressed prior to dioxane exposure. Multiple genes related to the catabolism of each intermediate were upregulated by treatment in response to dioxane. Glyoxylate metabolism was essential during dioxane degradation by YN2, and the key intermediate glyoxylate was metabolized through three routes: glyoxylate carboligase pathway, malate synthase pathway, and anaplerotic ethylmalonyl–CoA pathway. Genes related to quorum sensing and transporters were significantly upregulated during the early stages of degradation (T0, T24) prior to dioxane depletion, while the expression of genes encoding two-component systems was significantly increased at late degradation stages (T48) when total organic carbon in the culture was exhausted. This study is the first to report the participation of genes encoding glyoxalase, as well as methylotrophic genes xoxF and mox, in dioxane metabolism. The present study reveals multiple genetic and transcriptional strategies used by YN2 to rapidly increase biomass during growth on dioxane, achieve high degradation efficiency and tolerance, and adapt to dioxane exposure quickly, which provides useful information regarding the molecular basis for efficient dioxane biodegradation.
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- 2021
5. Theranostic Application of a Novel G-Quadruplex-Forming DNA Aptamer Targeting Malate Synthase of Mycobacterium tuberculosis
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Abhijeet Dhiman, Sagarika Haldar, Jaya Sivaswami Tyagi, Kriti Sikri, Chanchal Kumar, Yusra Ahmad, Neera Sharma, Ishara Datta, Pradeep Sharma, Anjali Bansal, Tej P. Singh, Tarun Kumar Sharma, Amit Kumar, and Subodh Kumar Mishra
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0301 basic medicine ,chemistry.chemical_classification ,biology ,Aptamer ,In silico ,lcsh:RM1-950 ,Glyoxylate cycle ,Entry into host ,biology.organism_classification ,Article ,Mycobacterium tuberculosis ,03 medical and health sciences ,lcsh:Therapeutics. Pharmacology ,030104 developmental biology ,0302 clinical medicine ,Enzyme ,chemistry ,Biochemistry ,030220 oncology & carcinogenesis ,Malate synthase ,Drug Discovery ,biology.protein ,Molecular Medicine ,Systematic evolution of ligands by exponential enrichment - Abstract
The successful management of tuberculosis (TB) requires efficient diagnosis and treatment. Further, the increasing prevalence of drug-resistant TB highlights the urgent need to develop novel inhibitors against both drug-susceptible and drug-resistant forms of disease. Malate synthase (MS), an enzyme of the glyoxylate pathway, plays a vital role in mycobacterial persistence, and therefore it is considered as an attractive target for novel anti-TB drug development. Recent studies have also ascribed an adhesin function to MS and established it as a potent diagnostic biomarker. In this study, a panel of Mycobacterium tuberculosis (Mtb) MS-specific single-stranded DNA aptamers was identified by Systematic Evolution of Ligands by EXponential enrichment (SELEX). The best-performing G-quadruplex-forming 44-mer aptamer, MS10, was optimized post-SELEX to generate an 11-mer aptamer, MS10-Trunc. This aptamer was characterized by various biochemical, biophysical, and in silico techniques. Its theranostic activity toward Mtb was established using enzyme inhibition, host cell binding, and invasion assays. MS10-Trunc aptamer exhibited high affinity for MS (equilibrium dissociation constant [KD] ∼19 pM) and displayed robust inhibition of MS enzyme activity with IC50 of 251.1 nM and inhibitor constant (Ki) of 230 nM. This aptamer blocked mycobacterial entry into host cells by binding to surface-associated MS. In addition, we have also demonstrated its application in the detection of tuberculous meningitis (TBM) in patients with sensitivity and specificity each of >97%.
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- 2019
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6. GATA‐type transcriptional factor Gat1 regulates nitrogen uptake and polymalic acid biosynthesis in polyextremotolerant fungus Aureobasidium pullulans
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Xiang Zou, Xiaodan Song, Yongkang Wang, Guihong Pu, and Pan Wang
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Proline ,Nitrogen ,Polymers ,Glutamine ,Mutant ,Malates ,Glyoxylate cycle ,Oxidative phosphorylation ,Microbiology ,03 medical and health sciences ,chemistry.chemical_compound ,Ascomycota ,Biosynthesis ,Malate synthase ,Ecology, Evolution, Behavior and Systematics ,030304 developmental biology ,0303 health sciences ,biology ,030306 microbiology ,Glyoxylates ,biology.organism_classification ,Carbon ,Aureobasidium pullulans ,chemistry ,Biochemistry ,biology.protein ,Gene Deletion ,Transcription Factors - Abstract
Polymalic acid (PMA) is a novel biopolymer produced by the polyextremotolerant fungus Aureobasidium pullulans. In this study, a GATA-family transcriptional factor, Gat1, which regulates nitrogen uptake and PMA biosynthesis, was investigated. PMA production increased to 11.2% in the mutant overexpressing gat1 but decreased to 49.1% of the PMA titre when gat1 was knocked out from the genome of A. pullulans. Comparative transcriptome analysis of wild-type and mutant strains (∆gat1 and OE::gat1) revealed that 23 common differentially expressed genes were related to oxidative phosphorylation, ribosome biogenesis, and nitrogen metabolism. Under nitrogen-limited stress, regardless of the preferred nitrogen (glutamine, Gln) or non-preferred nitrogen (proline, Pro), 70% of Gat1 in the cells was located in the nucleus-cytoplasm, which resulted in an increase in nitrogen uptake and PMA biosynthesis regulation. Quantitative RT-PCR revealed that glucosekinase (GLK) in the glycolytic pathway and malate synthase (MLS) in the glyoxylate shunt pathway may be cross-regulated by Gat1 and nitrogen concentration (Gln or Pro), Therefore, glk was overexpressed in mutant strain (OE::gat1), which resulted in an increased PMA titre and yield of 12.6% and 13.0% respectively. These findings indicate that Gat1 may play an important role in the dual regulation of the nitrogen and carbon metabolisms in PMA biosynthesis.
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- 2019
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7. Effect of Target Gene Silencing on Calcite Single Crystal Formation by Thermophilic Bacterium Geobacillus thermoglucosidasius NY05
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Keiji Kiyoshi, Naoto Yoshida, and Rie Murai
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Glyoxylate cycle ,Acetates ,Applied Microbiology and Biotechnology ,Microbiology ,Calcium Carbonate ,03 medical and health sciences ,chemistry.chemical_compound ,Bacterial Proteins ,Geobacillus thermoglucosidasius ,Malate synthase ,Gene Silencing ,030304 developmental biology ,chemistry.chemical_classification ,Calcite ,0303 health sciences ,DNA ligase ,biology ,030306 microbiology ,Oligonucleotide ,Thermophile ,Malate Synthase ,Geobacillus ,Glyoxylates ,General Medicine ,Isocitrate lyase ,biology.organism_classification ,Isocitrate Lyase ,Biochemistry ,chemistry ,biology.protein ,Calcium - Abstract
Geobacillus thermoglucosidasius NY05 catalyzes calcite single crystal formation at 60 °C by using acetate and calcium. Endospores are embedded at the central part of the calcite single crystal and carbon atoms in the calcite lattice are derived from acetate carbon. Here, we synthesized 21-mer antisense DNA oligonucleotides targeting sporulation transcription factor, acetate-CoA ligase, isocitrate lyase, and malate synthase G mRNAs and evaluated the effect of these oligonucleotides on calcite formation in G. thermoglucosidasius NY05. G. thermoglucosidasius NY05 cells containing antisense DNA oligonucleotides targeting sporulation transcription factor, acetate-CoA ligase, isocitrate lyase, and malate synthase G mRNAs had reduced calcite single crystal formation by 18.7, 50.6, 55.7, and 82.3%, respectively, compared with cells without antisense DNA oligonucleotides. These results support that calcite formation needs endospores as the nucleus to grow, and carbon dioxide generated from acetate, which is metabolized via the glyoxylate pathway and glucogenesis, is supplied to the crystal lattice.
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- 2019
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8. Differential expression of a malate synthase gene during the preinfection stage of symbiosis in the ectomycorrhizal fungus Laccaria bicolor
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Sung-Jae Kim, Sujata Balasubramanian, and Gopi K. Podila
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Laccaria ,biology ,Hypha ,Physiology ,fungi ,Glyoxylate cycle ,Plant Science ,biology.organism_classification ,Metabolic pathway ,Symbiosis ,Biochemistry ,Laccaria bicolor ,Malate synthase ,biology.protein ,Mycorrhiza - Abstract
Summary • The ectomycorrhiza is a symbiotic organ formed between a filamentous fungus and a plant root, mainly tree roots. Root colonization involves significant shifts in gene expression resulting in metabolic and structural changes in the fungus, including growth toward the plant root, penetration and establishment of the symbiotic organ. • The preinfection stage of the association is crucial as changes that occur throughout mycorrhiza formation are set in motion. Using an in vitro system for identifying preinfection stage symbiosis-regulated genes from the Laccaria bicolor–Pinus resinosa interaction we have identified a malate synthase from L. bicolor (Lb-MS). • The glyoxylate pathway, of which malate synthase is an enzyme, acts as a tricarboxylic acid pathway bypass generating four-carbon compounds for biosynthesis. While it is anticipated that malate synthase would be a part of the genetic and metabolic machinery of any fungus, Lb-MS is of interest because it is symbiosis regulated. • Lb-MS is regulated through interaction between the fungus and the host, by glucose and by the presence of other carbon sources in the medium. Its proposed role in the symbiosis is in the utilization of two carbon compounds formed from catabolic processes in early interaction facilitating hyphal net growth.
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- 2021
9. Copper-zinc superoxide dismutase is a constituent enzyme of the matrix of peroxisomes in the cotyledons of oilseed plants
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Francisco J. Corpas, Richard N. Trelease, Luis A. del Río, and Luisa M. Sandalio
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chemistry.chemical_classification ,food.ingredient ,Physiology ,Plant Science ,Mitochondrion ,Biology ,Peroxisome ,Superoxide dismutase ,Chloroplast ,food ,Enzyme ,Biochemistry ,chemistry ,Malate synthase ,Organelle ,biology.protein ,Cotyledon - Abstract
The number and type of isoforms of superoxide dismutase (SOD) and their activities were compared in mitochondria and peroxisomes isolated from cotyledons of three different oilseed seedlings. Mitochondrial and peroxisomal isoforms of SOD could be distinguished in nondenaturing polyacrylamide gels by their differential sensitivities to KCN and/or H2O2. The type of SOD was not the same for each organelle in each of the three oilseed species. For example, a single Mn–SOD was found in cotton and cucumber mitochondria, whereas four CuZn–SODs were present in mitochondria from sunflower. At least one CuZn–SOD isoform was found in the peroxisomes of all three species. Cucumber peroxisomes contained both a CuZn–SOD and a Mn–SOD, cotton peroxisomes contained a single CuZn–SOD, whilst four separate CuZn–SODs, but no Mn–SOD were found in sunflower peroxisomes. Using antibodies against CuZn–SOD from watermelon peroxisomes or from chloroplasts of Equisetum, a single polypeptide of c. 16·5 kDa was detected on immunoblots of peroxisomal fractions from the three species. Post-embedment, electron-microscopic double immunogold-labelling showed that CuZn–SOD, with malate synthase used as marker enzyme of peroxisomes, was localized in the matrix of these organelles of all three species. These results suggest that CuZn–SOD is a characteristic matrix enzyme of peroxisomes in oilseed cotyledons.
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- 2021
10. Metabolic fitness of
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Zeeshan Fatima, Saif Hameed, and Sandeep Hans
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QH301-705.5 ,Glyoxylate cycle ,chitin ,Microbiology ,chemistry.chemical_compound ,Chitin ,Malate synthase ,glyoxylate cycle ,Biology (General) ,Candida albicans ,Internal medicine ,Ergosterol ,ergosterol ,biology ,Isocitrate lyase ,biology.organism_classification ,RC31-1245 ,Metabolic pathway ,Infectious Diseases ,chemistry ,Biochemistry ,candida ,biology.protein ,efflux pump ,Original Article ,Efflux - Abstract
Background and Purpose: The increment in fungal infections, particularly due to Candida species, is alarming due to the emergence of multidrug resistance (MDR). Hence, the identification of novel drug targets to circumvent the problem of MDR requires immediate attention. The metabolic pathway, such as glyoxylate cycle (GC), which utilizes key enzymes (isocitrate lyase [ICL] and malate synthase [MLS]), enables C. albicans to adapt under glucose-deficient conditions. This study uncovers the effect of GC disruption on the major MDR mechanisms of C. albicans as a human pathogenic fungus. Materials and Methods: For the purpose of the study, efflux pump activity was assessed by phenotypic susceptibilities in the presence of substrates rhodamine 6G (R6G) and Nile red, along with R6G extracellular concentration (527 nm). In addition, ergosterol content was estimated by the alcoholic potassium hydroxide hydrolysis method. The estimation of chitin was also accomplished by the absorbance (520 nm) of glucosamine released by acid hydrolysis. Results: The results revealed that the disruption of ICL enzyme gene (Δicl1) led to the impairment of the efflux activity of multidrug transporters belonging to the ATP-binding cassette superfamily. It was further shown that Δicl1 mutant exhibited diminished ergosterol and chitin contents. In addition, all abrogated phenotypes could be rescued in the reverting strain of Δicl1 mutant. Conclusion: Based on the findings, the disruption of GC affected efflux activity and the synthesis of ergosterol and chitin. The present study for the first time revealed that metabolic fitness was associated with functional drug efflux, ergosterol and chitin biosynthesis and validated GC as an antifungal target. However, further studies are needed to comprehend and exploit this therapeutic opportunity.
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- 2021
11. Production of succinate by engineered strains of Synechocystis PCC 6803 overexpressing phosphoenolpyruvate carboxylase and a glyoxylate shunt
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Alessia Albergati, Jeffrey A. Hawkes, Kateryna Kukil, Peter Lindblad, Pia Lindberg, and Claudia Durall
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Succinate ,Glyoxylate cycle ,lcsh:QR1-502 ,Succinic Acid ,Bioengineering ,Microbiology ,Applied Microbiology and Biotechnology ,lcsh:Microbiology ,Synechocystis PCC 6803 ,2-thenoyltrifluoroacetone ,Bacterial Proteins ,Malate synthase ,Phosphoenolpyruvate carboxylase ,TCA cycle ,biology ,Chemistry ,Acetate ,Succinate dehydrogenase ,Research ,Synechocystis ,Glyoxylates ,Isocitrate lyase ,biology.organism_classification ,Citric acid cycle ,Mikrobiologi ,Biochemistry ,Metabolic Engineering ,Glyoxylate shunt ,biology.protein ,Heterologous expression ,Phosphoenolpyruvate Carboxykinase (ATP) ,Biotechnology - Abstract
Background Cyanobacteria are promising hosts for the production of various industrially important compounds such as succinate. This study focuses on introduction of the glyoxylate shunt, which is naturally present in only a few cyanobacteria, into Synechocystis PCC 6803. In order to test its impact on cell metabolism, engineered strains were evaluated for succinate accumulation under conditions of light, darkness and anoxic darkness. Each condition was complemented by treatments with 2-thenoyltrifluoroacetone, an inhibitor of succinate dehydrogenase enzyme, and acetate, both in nitrogen replete and deplete medium. Results We were able to introduce genes encoding the glyoxylate shunt, aceA and aceB, encoding isocitrate lyase and malate synthase respectively, into a strain of Synechocystis PCC 6803 engineered to overexpress phosphoenolpyruvate carboxylase. Our results show that complete expression of the glyoxylate shunt results in higher extracellular succinate accumulation compared to the wild type control strain after incubation of cells in darkness and anoxic darkness in the presence of nitrate. Addition of the inhibitor 2-thenoyltrifluoroacetone increased succinate titers in all the conditions tested when nitrate was available. Addition of acetate in the presence of the inhibitor further increased the succinate accumulation, resulting in high levels when phosphoenolpyruvate carboxylase was overexpressed, compared to control strain. However, the highest succinate titer was obtained after dark incubation of an engineered strain with a partial glyoxylate shunt overexpressing isocitrate lyase in addition to phosphoenolpyruvate carboxylase, with only 2-thenoyltrifluoroacetone supplementation to the medium. Conclusions Heterologous expression of the glyoxylate shunt with its central link to the tricarboxylic acid cycle (TCA) for acetate assimilation provides insight on the coordination of the carbon metabolism in the cell. Phosphoenolpyruvate carboxylase plays an important role in directing carbon flux towards the TCA cycle.
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- 2021
12. Increasing glycolysis by deletion of kcs1 and arg82 improved S-adenosyl-l-methionine production in Saccharomyces cerevisiae
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Jia Zheng, Hailong Chen, Xin Zhang, Jiaping Peng, Yan Wang, Xinxin Gao, Yuhe Song, and Nianqing Zhu
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biology ,ATP synthase ,Chemistry ,lcsh:Biotechnology ,Increasing glycolysis ,Saccharomyces cerevisiae ,lcsh:QR1-502 ,Biophysics ,Metabolism ,biology.organism_classification ,Applied Microbiology and Biotechnology ,lcsh:Microbiology ,Yeast ,S-adenosyl-l-methionine ,Metabolic pathway ,Inositol pyrophosphates metabolism ,Biochemistry ,lcsh:TP248.13-248.65 ,Malate synthase ,biology.protein ,Original Article ,Fermentation ,Glycolysis - Abstract
Reprogramming glycolysis for directing glycolytic metabolites to a specific metabolic pathway is expected to be useful for increasing microbial production of certain metabolites, such as amino acids, lipids or considerable secondary metabolites. In this report, a strategy of increasing glycolysis by altering the metabolism of inositol pyrophosphates (IPs) for improving the production of S-adenosyl-l-methionine (SAM) for diverse pharmaceutical applications in yeast is presented. The genes associated with the metabolism of IPs, arg82, ipk1 and kcs1, were deleted, respectively, in the yeast strain Saccharomyces cerevisiae CGMCC 2842. It was observed that the deletions of kcs1 and arg82 increased SAM by 83.3 % and 31.8 %, respectively, compared to that of the control. In addition to the improved transcription levels of various glycolytic genes and activities of the relative enzymes, the levels of glycolytic intermediates and ATP were also enhanced. To further confirm the feasibility, the kcs1 was deleted in the high SAM-producing strain Ymls1ΔGAPmK which was deleted malate synthase gene mls1 and co-expressed the Acetyl-CoA synthase gene acs2 and the SAM synthase gene metK1 from Leishmania infantum, to obtain the recombinant strain Ymls1Δkcs1ΔGAPmK. The level of SAM in Ymls1Δkcs1ΔGAPmK reached 2.89 g L−1 in a 250-mL flask and 8.86 g L−1 in a 10-L fermentation tank, increasing 30.2 % and 46.2 %, respectively, compared to those levels in Ymls1ΔGAPmK. The strategy of increasing glycolysis by deletion of kcs1 and arg82 improved SAM production in yeast.
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- 2021
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13. Evolutionary Maintenance of the PTS2 Protein Import Pathway in the Stramenopile Alga Nannochloropsis
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Imke de Grahl, Pierre Endries, Sigrun Reumann, and Dmitry Kechasov
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0301 basic medicine ,Signal peptide ,Cellebiologi: 471 [VDP] ,Cell and Developmental Biology ,03 medical and health sciences ,malate synthase ,0302 clinical medicine ,evolution ,PTS2 protein import pathway ,thiolase ,peroxisome biogenesis ,lcsh:QH301-705.5 ,Original Research ,Endosymbiosis ,biology ,Peroxisomal matrix ,Cell Biology ,Peroxisomal Targeting Signal 2 Receptor ,Peroxisome ,biology.organism_classification ,Fusion protein ,microalgae (unicellular eukaryotic algae) ,030104 developmental biology ,lcsh:Biology (General) ,Biochemistry ,030220 oncology & carcinogenesis ,Proteome ,Nannochloropsis ,Developmental Biology - Abstract
The stramenopile alga Nannochloropsis evolved by secondary endosymbiosis of a red alga by a heterotrophic host cell and emerged as a promising organism for biotechnological applications, such as the production of polyunsaturated fatty acids and biodiesel. Peroxisomes play major roles in fatty acid metabolism but experimental analyses of peroxisome biogenesis and metabolism in Nannochloropsis are not reported yet. In fungi, animals, and land plants, soluble proteins of peroxisomes are targeted to the matrix by one of two peroxisome targeting signals (type 1, PTS1, or type 2, PTS2), which are generally conserved across kingdoms and allow the prediction of peroxisomal matrix proteins from nuclear genome sequences. Because diatoms lost the PTS2 pathway secondarily, we investigated its presence in the stramenopile sister group of diatoms, the Eustigmatophyceae, represented by Nannochloropsis. We detected a full-length gene of a putative PEX7 ortholog coding for the cytosolic receptor of PTS2 proteins and demonstrated its expression in Nannochloropsis gaditana. The search for predicted PTS2 cargo proteins in N. gaditana yielded several candidates. In vivo subcellular targeting analyses of representative fusion proteins in different plant expression systems demonstrated that two predicted PTS2 domains were indeed functional and sufficient to direct a reporter protein to peroxisomes. Peroxisome targeting of the predicted PTS2 cargo proteins was further confirmed in Nannochloropsis oceanica by confocal and transmission electron microscopy. Taken together, the results demonstrate for the first time that one group of stramenopile algae maintained the import pathway for PTS2 cargo proteins. To comprehensively map and model the metabolic capabilities of Nannochloropsis peroxisomes, in silico predictions needs to encompass both the PTS1 and the PTS2 matrix proteome.
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- 2020
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14. Controlled atmospheres and sugar can delay malate synthase gene expression during asparagus senescence
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Paul L. Hurst, Ben K. Sinclair, Sheryl D. Somerfield, and Simon A. Coupe
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chemistry.chemical_classification ,Sucrose ,biology ,cDNA library ,Glyoxylate cycle ,food and beverages ,Plant Science ,biology.organism_classification ,Molecular biology ,Amino acid ,chemistry.chemical_compound ,chemistry ,Biochemistry ,Malate synthase ,Complementary DNA ,Gene expression ,biology.protein ,Asparagus ,Agronomy and Crop Science - Abstract
A cDNA clone encoding malate synthase (MS; EC 4.1.3.2) was isolated from a 48-h postharvest asparagus (Asparagus officinalis L.) spear cDNA library using a MS clone from Brassica napus. The asparagus MS (AoMS1) cDNA hybridized to a 1.9-kb transcript that increased in abundance preferentially in spear-tip tissue during postharvest storage. The AoMS1 transcript also accumulated during natural foliar senescence of asparagus fern. The cDNA consists of 1960 nucleotides with an open reading frame of 1665 nucleotides or 555 amino acids, and encodes a deduced protein with a predicted Mr of 63 kDa and a pI of 8.1. The deduced amino acid sequence of AoMS1 showed high identity with the B. napus MS clone (77.2%) used to isolate it, and with MS from cucumber (77%). Genomic Southern analysis suggests that a single gene in asparagus encodes AoMS1. Controlled- atmosphere treatments aimed at reducing deterioration of harvested asparagus spears reduced the expression of AoMS1. The reduction was correlated with the reduced oxygen level, and reduced MS enzyme activity was also observed. Asparagus cell cultures were used to test the role of sugar status in regulating AoMS1 gene expression. In cultures without sucrose there was an accumulation of AoMS1 transcript that was absent in cultures containing sucrose.
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- 2020
15. 2-Aminopyridine Analogs Inhibit Both Enzymes of the Glyoxylate Shunt in Pseudomonas aeruginosa
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Mahmud Kajbaf, Päivi Tammela, Viviana Gatta, David R. Spring, Sean Bartlett, Alyssa C. McVey, Annalisa Pellacani, Martin Welch, Division of Pharmaceutical Biosciences, Drug Research Program, Bioactivity Screening Group, Divisions of Faculty of Pharmacy, Tammela, Päivi [0000-0003-4697-8066], Spring, David R [0000-0001-7355-2824], Welch, Martin [0000-0003-3646-1733], Apollo - University of Cambridge Repository, and Spring, David R. [0000-0001-7355-2824]
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0301 basic medicine ,MECHANISM ,116 Chemical sciences ,Aminopyridines ,medicine.disease_cause ,01 natural sciences ,lcsh:Chemistry ,glyoxylate shunt ,Cytotoxicity ,lcsh:QH301-705.5 ,Spectroscopy ,chemistry.chemical_classification ,biology ,Molecular Structure ,Glyoxylates ,General Medicine ,3. Good health ,Computer Science Applications ,Anti-Bacterial Agents ,isothermal titration calorimetry ,Biochemistry ,Enzyme inhibitor ,317 Pharmacy ,Pseudomonas aeruginosa ,ANTIBIOTICS ,MALATE SYNTHASE ,Glyoxylate cycle ,enzyme inhibitor ,malate synthase G ,Calorimetry ,Catalysis ,Cell Line ,Inorganic Chemistry ,03 medical and health sciences ,Bacterial Proteins ,Malate synthase ,medicine ,Humans ,Physical and Theoretical Chemistry ,Molecular Biology ,010405 organic chemistry ,Organic Chemistry ,Metabolism ,Isocitrate lyase ,Gene Expression Regulation, Bacterial ,ACIDS ,isocitrate lyase ,0104 chemical sciences ,030104 developmental biology ,Enzyme ,chemistry ,lcsh:Biology (General) ,lcsh:QD1-999 ,conditionally essential target ,biology.protein - Abstract
Pseudomonas aeruginosa is an opportunistic pathogen responsible for many hospital-acquired infections. P. aeruginosa can thrive in diverse infection scenarios by rewiring its central metabolism. An example of this is the production of biomass from C2 nutrient sources such as acetate via the glyoxylate shunt when glucose is not available. The glyoxylate shunt is comprised of two enzymes, isocitrate lyase (ICL) and malate synthase G (MS), and flux through the shunt is essential for the survival of the organism in mammalian systems. In this study, we characterized the mode of action and cytotoxicity of structural analogs of 2-aminopyridines, which have been identified by earlier work as being inhibitory to both shunt enzymes. Two of these analogs were able to inhibit ICL and MS in vitro and prevented growth of P. aeruginosa on acetate (indicating cell permeability). Moreover, the compounds exerted negligible cytotoxicity against three human cell lines and showed promising in vitro drug metabolism and safety profiles. Isothermal titration calorimetry was used to confirm binding of one of the analogs to ICL and MS, and the mode of enzyme inhibition was determined. Our data suggest that these 2-aminopyridine analogs have potential as anti-pseudomonal agents.
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- 2020
16. The chloroplast localization of protease mediated by the potato rbcS signal peptide and its improvement for construction of photorespiratory bypasses
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Boran Shen, Zhen Yao, Xiulan Yang, and Minhui Long
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chemistry.chemical_classification ,Signal peptide ,Proteases ,Protease ,biology ,medicine.medical_treatment ,Agriculture (General) ,food and beverages ,Peptide ,Forestry ,Plant Science ,Horticulture ,SD1-669.5 ,Amino acid ,S1-972 ,Chloroplast ,chemistry ,Biochemistry ,Chloroplast localization ,Malate synthase ,chloroplast localization ,chloroplast signal peptide ,photorespiratory bypass ,biology.protein ,medicine ,Agronomy and Crop Science - Abstract
Location of the proteases would affect on protease stability and photorespiratory bypass pathway, while it is unsolved. Potato rbcS signal peptide was analyzed and constructed into the protease for study of their localization site. The tartronate semialdehyde reductase (EcTSR) proteins could be accurately and efficiently located in chloroplast only when this signal peptide was extended to 80 amino acids. The signal peptide would help malate synthase (CmMS) locate to the surface of chloroplast, to form granules on the outer membrane of chloroplast. The whole spectrum scanning showed that these proteins could enter chloroplast. A signal peptide named PCS1 (Peptide of self-cleavage site 1) carrying a self-cleavage site was designed, and sixteen amino acids from the blue pigment precursor protein of chloroplast positioning signal of Silene pratensis were added to the C-terminal of PCS1. Transient expression, Western blot analysis and full-spectrum scanning showed that PCS1 could locate the EcTSR to the chloroplast, after the removal of the signal peptide.
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- 2020
17. The carbonate concentration mechanism of Pyropia yezoensis (Rhodophyta): evidence from transcriptomics and biochemical data
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Linwen He, Yuanyuan Sun, Xuehua Liu, Guangce Wang, Xiujun Xie, and Baoyu Zhang
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0106 biological sciences ,0301 basic medicine ,Carbonates ,Plant Science ,Photosynthesis ,01 natural sciences ,03 medical and health sciences ,Total inorganic carbon ,Gene Expression Regulation, Plant ,Malate synthase ,Carbonic anhydrase ,lcsh:Botany ,Carbon concentrating mechanism ,Enzyme activity ,biology ,Gene Expression Profiling ,Isocitrate lyase ,Seaweed ,Pyruvate carboxylase ,lcsh:QK1-989 ,030104 developmental biology ,Biochemistry ,Rhodophyta ,biology.protein ,Phosphoenolpyruvate carboxykinase ,Phosphoenolpyruvate carboxylase ,Pyropia yezoensis ,Transcriptome ,Photosynthetic efficiency ,Research Article ,010606 plant biology & botany - Abstract
Background Pyropia yezoensis (Rhodophyta) is widely cultivated in East Asia and plays important economic, ecological and research roles. Although inorganic carbon utilization of P. yezoensis has been investigated from a physiological aspect, the carbon concentration mechanism (CCM) of P. yezoensis remains unclear. To explore the CCM of P. yezoensis, especially during its different life stages, we tracked changes in the transcriptome, photosynthetic efficiency and in key enzyme activities under different inorganic carbon concentrations. Results Photosynthetic efficiency demonstrated that sporophytes were more sensitive to low carbon (LC) than gametophytes, with increased photosynthesis rate during both life stages under high carbon (HC) compared to normal carbon (NC) conditions. The amount of starch and number of plastoglobuli in cells corresponded with the growth reaction to different inorganic carbon (Ci) concentrations. We constructed 18 cDNA libraries from 18 samples (three biological replicates per Ci treatment at two life cycles stages) and sequenced these using the Illumina platform. De novo assembly generated 182,564 unigenes, including approximately 275 unigenes related to CCM. Most genes encoding internal carbonic anhydrase (CA) and bicarbonate transporters involved in the biophysical CCM pathway were induced under LC in comparison with NC, with transcript abundance of some PyCAs in gametophytes typically higher than that in sporophytes. We identified all key genes participating in the C4 pathway and showed that their RNA abundances changed with varying Ci conditions. High decarboxylating activity of PEPCKase and low PEPCase activity were observed in P. yezoensis. Activities of other key enzymes involved in the C4-like pathway were higher under HC than under the other two conditions. Pyruvate carboxylase (PYC) showed higher carboxylation activity than PEPC under these Ci conditions. Isocitrate lyase (ICL) showed high activity, but the activity of malate synthase (MS) was very low. Conclusion We elucidated the CCM of P. yezoensis from transcriptome and enzyme activity levels. All results indicated at least two types of CCM in P. yezoensis, one involving CA and an anion exchanger (transporter), and a second, C4-like pathway belonging to the PEPCK subtype. PYC may play the main carboxylation role in this C4-like pathway, which functions in both the sporophyte and gametophyte life cycles.
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- 2020
18. Structure-based discovery of phenyl-diketo acids derivatives as Mycobacterium tuberculosis malate synthase inhibitors
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Harish Shukla, Timir Tripathi, and Rohit Shukla
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Virtual screening ,biology ,Chemistry ,Drug target ,General Medicine ,biology.organism_classification ,Mycobacterium tuberculosis ,Biochemistry ,Structural Biology ,Malate synthase ,biology.protein ,Structure based ,Molecular Biology ,Bacteria - Abstract
Mycobacterium tuberculosis remains one of the most successful bacterial pathogens worldwide. The development of drug-resistant strains and the ability of the bacteria to persist in a latent form in the host are major problems for tuberculosis (TB) control. Glyoxylate shunt is a metabolic bypass of the Krebs cycle and is the key for M. tuberculosis to survive under latent conditions. Malate synthase (MtbMS) catalyzes the second step of the glyoxylate cycle and converts glyoxylate into malate. Phenyl-diketo acid (PDKA) is a potent inhibitor of MtbMS, and its efficacy is validated in a mouse model of TB. To identify novel PDKA analogs as anti-TB compounds, PDKA analogs that obeyed the Lipinski rules (n = 5473) were analyzed and docked with MtbMS structure in three sequential modes. These compounds were then assessed for ADMET parameters. Of the compounds examined, 19 were found to fit well for redocking studies. After optimization, four prospective inhibitors were identified, that along with the reference compound PDKA were subjected to 50 ns molecular dynamics simulation and binding-free energy analyses to evaluate the complex dynamics after ligand binding, the stability of the bound complexes, and the intermolecular interactions between the complexes. The MtbMS-PDKA complex showed the binding free energy of –57.16 kJ·mol−1. After a thorough analysis, our results suggested that three compounds which had binding-free energy of –127.96, −97.60, and –83.98 kJ·mol−1, with PubChem IDs 91937661, 14016246, and 126487337, respectively, have the potential to inhibit MtbMS and can be taken as lead compounds for drug discovery against TB. Communicated by Ramaswamy H. Sarma
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- 2020
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19. Structural and energetic understanding of novel natural inhibitors of Mycobacterium tuberculosis malate synthase
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Timir Tripathi, Rohit Shukla, and Harish Shukla
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0301 basic medicine ,biology ,Stereochemistry ,Chemistry ,Glyoxylate cycle ,Cell Biology ,Isocitrate lyase ,Metabolism ,biology.organism_classification ,Biochemistry ,Mycobacterium tuberculosis ,Citric acid cycle ,03 medical and health sciences ,030104 developmental biology ,0302 clinical medicine ,Protein structure ,Docking (molecular) ,030220 oncology & carcinogenesis ,Malate synthase ,biology.protein ,Molecular Biology - Abstract
Persistent infection by Mycobacterium tuberculosis requires the glyoxylate shunt. This is a bypass to the tricarboxylic acid cycle in which isocitrate lyase (ICL) and malate synthase (MS) catalyze the net incorporation of carbon during mycobacterial growth on acetate or fatty acids as the primary carbon source. To identify a potential antitubercular compound, we performed a structure-based screening of natural compounds from the ZINC database (n = 1 67 740) against the M tuberculosis MS (MtbMS) structure. The ligands were screened against MtbMS, and 354 ligands were found to have better docking score. These compounds were assessed for Lipinski and absorption, distribution, metabolism, excretion, and toxicity prediction where 15 compounds were found to fit well for redocking studies. After refinement by molecular docking and drug-likeness analysis, four potential inhibitors (ZINC1483899, ZINC1754310, ZINC2269664, and ZINC15729522) were identified. These four ligands with phenyl-diketo acid were further subjected to molecular dynamics simulation to compare the dynamics and stability of the protein structure after ligand binding. The binding energy analysis was calculated to determine the intermolecular interactions. Our results suggested that the four compounds had a binding free energy of -201.96, -242.02, -187.03, and -169.02 kJ·mol-1 , for compounds with IDs ZINC1483899, ZINC1754310, ZINC2269664, and ZINC15729522, respectively. We concluded that two compounds (ZINC1483899 and ZINC1754310) displayed considerable structural and pharmacological properties and could be probable drug candidates to fight against M tuberculosis parasites.
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- 2018
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20. Spontaneous refolding of the large multidomain protein malate synthase G proceeds through misfolding traps
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Vipul Kumar and Tapan K. Chaudhuri
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Models, Molecular ,0301 basic medicine ,Protein Denaturation ,Protein Folding ,Protein Conformation ,Glyoxylate cycle ,Crystallography, X-Ray ,Biochemistry ,Protein Refolding ,03 medical and health sciences ,Protein structure ,Malate synthase ,Escherichia coli ,Native state ,Molecular Biology ,chemistry.chemical_classification ,030102 biochemistry & molecular biology ,biology ,Chemistry ,Malate Synthase ,Energy landscape ,Cell Biology ,Chevron plot ,Kinetics ,030104 developmental biology ,Enzyme ,Protein Structure and Folding ,Biophysics ,biology.protein ,Thermodynamics ,Protein folding - Abstract
Most protein folding studies until now focus on single domain or truncated proteins. Although great insights in the folding of such systems has been accumulated, very little is known regarding the proteins containing multiple domains. It has been shown that the high stability of domains, in conjunction with inter-domain interactions, manifests as a frustrated energy landscape, causing complexity in the global folding pathway. However, multidomain proteins despite containing independently foldable, loosely cooperative sections can fold into native states with amazing speed and accuracy. To understand the complexity in mechanism, studies were conducted previously on the multidomain protein malate synthase G (MSG), an enzyme of the glyoxylate pathway with four distinct and adjacent domains. It was shown that the protein refolds to a functionally active intermediate state at a fast rate, which slowly produces the native state. Although experiments decoded the nature of the intermediate, a full description of the folding pathway was not elucidated. In this study, we use a battery of biophysical techniques to examine the protein's folding pathway. By using multiprobe kinetics studies and comparison with the equilibrium behavior of protein against urea, we demonstrate that the unfolded polypeptide undergoes conformational compaction to a misfolded intermediate within milliseconds of refolding. The misfolded product appears to be stabilized under moderate denaturant concentrations. Further folding of the protein produces a stable intermediate, which undergoes partial unfolding-assisted large segmental rearrangements to achieve the native state. This study reveals an evolved folding pathway of the multidomain protein MSG, which involves surpassing the multiple misfolding traps during refolding.
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- 2018
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21. Metabolic engineering of Escherichia coli for the production of L-malate from xylose
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Yang-Yang Da, Zheng-Jun Li, Gregory Stephanopoulos, Li Liangkang, and Peng-Hui Hong
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0301 basic medicine ,Xylose ,biology ,Escherichia coli Proteins ,Aldolase A ,Malates ,Malic enzyme ,Bioengineering ,Applied Microbiology and Biotechnology ,Malate dehydrogenase ,Metabolic engineering ,03 medical and health sciences ,chemistry.chemical_compound ,030104 developmental biology ,Metabolic Engineering ,chemistry ,Biochemistry ,Malate synthase ,Fumarase ,Escherichia coli ,biology.protein ,Tagatose ,Biotechnology - Abstract
Malate is regarded as one of the key building block chemicals which can potentially be produced from biomass at a large scale. Although glucose has been extensively studied as the substrate for malate production, its high price and potential competition with food production are serious limiting factors. In this study, Escherichia coli was metabolically engineered to effectively produce malate from xylose, the second most abundant sugar component of lignocellulosic biomass. First, the biosynthetic route of malate was constructed by overexpressing D -tagatose 3-epimerase, L-fuculokinase, L-fuculose-phosphate aldolase, and aldehyde dehydrogenase A. Second, genes encoding malic enzyme, malate dehydrogenase, and fumarate hydratase were knocked out to eliminate malate consumption, resulting in a titer of 1.99 g/l malate and a yield of 0.47 g malate/g xylose. Third, glycolate oxidase and malate synthase were overexpressed to strengthen the conversion of glycolate to malate, which led to a titer of 4.33 g/l malate and a yield of 0.83 g malate/g xylose, reaching 93% of the theoretical yield. Finally, catalase HPII was overexpressed to decompose H2O2 and alleviate its toxicity, which improved cell growth and further boosted malate titer to 5.90 g/l with a yield of 0.80 g malate/g xylose. To the best of our knowledge, this is the first study to report efficient malate production from xylose as the carbon source.
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- 2018
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22. The Effect of Oxalic Acid, the Pathogenicity Factor of Sclerotinia sclerotiorum on the Two Susceptible and Moderately Resistant Lines of Sunfl ower
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Sattar Tahmasebi Enferadi, Zohreh Rabiei, and Maryam Monazzah
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0106 biological sciences ,0301 basic medicine ,Sclerotinia sclerotiorum ,Glyoxylate cycle ,Biology ,biology.organism_classification ,01 natural sciences ,Biochemistry ,Malate dehydrogenase ,Microbiology ,Citric acid cycle ,03 medical and health sciences ,030104 developmental biology ,Fumarase ,Malate synthase ,Lyase Gene ,Genetics ,biology.protein ,Citrate synthase ,010606 plant biology & botany ,Biotechnology - Abstract
Background: One of the main sunfl ower diseases is the white mold Sclerotinia sclerotiorum. The oxalic acid (OA), which is one of the main pathogenicity factors of this fungus, beside the direct toxicity on the host, has other functions such as the disruption of the cell wall and chelating out the calcium ions.Objectives: Regarding the importance of this disease, it is important to study the reactions of the plant against OA which is a nonspecifi c toxin of many other necrotrophic fungi.Materials and Methods: In this study, two susceptible and moderately resistant sunfl ower lines were inoculated with OA and samples at the fi rst leaf stage were collected within the intervals of 2, 6, 12 and 24 hours post inoculation. The expression of five genes related to tricarboxylic acid cycle, including citrate synthase, fumarase, iso-citrate lyase, malate synthase and malate dehydrogenase was studied under OA treatment.Results: Two hours after the inoculation, no signifi cant change was observed in the expression of the fi ve studied genes in the moderately resistant line. The iso-citrate lyase gene, which is related to glyoxylate cycle (a variation of the tricarboxylic acid cycle), showed no change in the moderately resistant line; however, it showed an increase in the susceptible line. The increase in fumarase gene expression in moderately resistant line was higher than the susceptible line. The result showed the activation of glyoxylate cycle and destruction of fatty acids in the susceptible line.Conclusions: Activation of glyoxylate cycle indicated induction of senescent symptoms by OA in susceptible line. Increasing in H2O2 leads to oxidative burst and cell death. Cell death has an apparent benefi t for development and growth of necrotrophic pathogens in the plant cells. The study of resistance mechanisms in response to the pathogen can be useful for breeding programs to provide lines with higher resistance to this pathogen.
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- 2018
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23. Lack of the NAD+-dependent glycerol 3-phosphate dehydrogenase impairs the function of transcription factors Sip4 and Cat8 required for ethanol utilization in Kluyveromyces lactis
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Montserrat Vega, Rosaura Rodicio, Fernando Moreno, Hans-Peter Schmitz, Jürgen J. Heinisch, and Lucía Mojardín
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0301 basic medicine ,Kluyveromyces lactis ,030102 biochemistry & molecular biology ,Glyoxylate cycle ,Dehydrogenase ,Isocitrate lyase ,Biology ,biology.organism_classification ,Microbiology ,03 medical and health sciences ,030104 developmental biology ,Glycerol-3-phosphate dehydrogenase ,Biochemistry ,Kluyveromyces ,Malate synthase ,Genetics ,biology.protein ,NAD+ kinase - Abstract
The NAD+-dependent glycerol 3-phosphate dehydrogenase (KlGpd1) is an important enzyme for maintenance of the cytosolic redox balance in the milk yeast Kluyveromyces lactis. The enzyme is localized in peroxisomes and in the cytosol, indicating its requirement for the oxidation of NADH in both compartments. Klgpd1 mutants grow more slowly on glucose than wild-type cells and do not grow on ethanol as a sole carbon source. We studied the molecular basis of the latter phenotype and found that Gpd1 is required for high expression of KlICL1 and KlMLS1 which encode the key enzymes of the glyoxylate pathway isocitrate lyase and malate synthase, respectively. This regulation is mediated by CSRE elements in the promoters of these genes and the Snf1-regulated transcription factors KlCat8 and KlSip4. To study the transactivation function of these factors we developed a modified yeast one-hybrid system for K. lactis, using the endogenous s-galactosidase gene LAC4 as a reporter in a lac9 deletion background. In combination with ChIP analyses we discovered that Gpd1 controls both the specific binding of Cat8 and Sip4 to the target promoters and the capacity of these factors to activate the reporter gene expression. We propose a model in which KlGpd1 activity is required for maintenance of the redox balance. In its absence, genes which function in generating redox balance instabilities are not expressed. A comparison of mutant phenotypes further indicates, that this system not only operates in K. lactis, but also in Saccharomyces cerevisiae.
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- 2018
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24. Monoterpenoid perillyl alcohol impairs metabolic flexibility of Candida albicans by inhibiting glyoxylate cycle
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Saif Hameed, Moiz A. Ansari, Kamal Ahmad, and Zeeshan Fatima
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0301 basic medicine ,Cell Survival ,030106 microbiology ,Biophysics ,Glyoxylate cycle ,Biochemistry ,03 medical and health sciences ,chemistry.chemical_compound ,Bacterial Proteins ,Malate synthase ,Candida albicans ,Enzyme kinetics ,Molecular Biology ,chemistry.chemical_classification ,Dose-Response Relationship, Drug ,biology ,Chemistry ,Perillyl alcohol ,Malate Synthase ,Glyoxylates ,Gene Expression Regulation, Bacterial ,Cell Biology ,Isocitrate lyase ,biology.organism_classification ,Isocitrate Lyase ,Molecular biology ,Metabolic Flux Analysis ,Anti-Bacterial Agents ,Metabolic pathway ,030104 developmental biology ,Enzyme ,Monoterpenes ,biology.protein ,Metabolic Networks and Pathways - Abstract
The metabolic pathway such as glyoxylate cycle (GC) enables Candida albicans, to survive under glucose deficient conditions prevalent in the hostile niche. Thus its key enzymes (Isocitrate lyase; ICL and malate synthase; MLS) represent attractive targets against C. albicans. We have previously reported the antifungal potential of a natural monoterpenoid perillyl alcohol (PA). The present study uncovers additional role of PA as a potent GC inhibitor. We explored that PA phenocopied ICL1 deletion mutant and were hypersensitive under low carbon utilizing conditions. The effect of PA on GC was substantiated by molecular docking analyses, which reveals the in-silico binding affinity of PA with ICL and MLS and explored that PA binds to the active sites of both proteins with better binding energy in comparison to their known inhibitors 3-nitropropionate and bromopyruvate respectively. Enzyme kinetics by Lineweaver-Burk plot unravels that PA inhibits ICL and MLS enzymes in competitive and non-competitive manner respectively. Moreover, semi-quantitative RT-PCR indicated that PA inhibits ICL1 and MLS1 mRNA expressions. Lastly, we demonstrated the antifungal efficacy of PA by enhanced survival of Caenorhabditis elegans model and less hemolytic activity (10.6%) on human blood cells. Further studies are warranted for PA to be considered as viable drug candidate.
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- 2018
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25. Metabolic engineering of Escherichia coli for the production of glyoxylate from xylose
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Li Liangkang, Zheng-Jun Li, Peng-Hui Hong, Tianwei Tan, and Li-Long Shi
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0301 basic medicine ,Environmental Engineering ,030102 biochemistry & molecular biology ,biology ,Biomedical Engineering ,Glyoxylate cycle ,Bioengineering ,Xylose ,medicine.disease_cause ,Metabolic engineering ,03 medical and health sciences ,chemistry.chemical_compound ,030104 developmental biology ,chemistry ,Biochemistry ,Catalase ,Malate synthase ,biology.protein ,medicine ,Fermentation ,Escherichia coli ,Gene ,Biotechnology - Abstract
Glyoxylate is an important chemical building block which is currently produced by chemical or electrochemical oxidation methods We herein described the achievement of microbial glyoxylate production from renewable biomass by metabolic engineering of Escherichia coli. The synthetic ribulose-1-phosphate pathway was expressed to produce glycolate from xylose. Additional genomic modifications including the inactivation of malate synthase genes aceB/glcB and glyoxylate carboligase gene gcl were performed to prevent the consumption of glyoxylate. The constructed strain was found to accumulate 0.13 g/L glyoxylate in shake flask cultivations. Further overexpression of glycolate oxidase and catalase significantly improved glyoxylate production to 0.74 g/L, which is the highest titer reported to date. These results demonstrate that microbial fermentation has a promising potential to manufacture glyoxylate from renewable feedstocks.
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- 2018
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26. Replacing the Ethylmalonyl-CoA Pathway with the Glyoxylate Shunt Provides Metabolic Flexibility in the Central Carbon Metabolism of Methylobacterium extorquens AM1
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Lennart Schada von Borzyskowski, Markus Buchhaupt, Jens Schrader, Julia A. Vorholt, Laura Pöschel, Frank Sonntag, and Tobias J. Erb
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0301 basic medicine ,Biomedical Engineering ,Glyoxylate cycle ,Heterologous ,Reductase ,Biochemistry, Genetics and Molecular Biology (miscellaneous) ,Metabolic engineering ,03 medical and health sciences ,chemistry.chemical_compound ,Acyl-CoA Dehydrogenases ,Bacterial Proteins ,Methylmalonyl-CoA ,Methylobacterium extorquens ,Gene ,Acetic Acid ,biology ,Methanol ,Malate Synthase ,Glyoxylates ,General Medicine ,biology.organism_classification ,Formate Dehydrogenases ,Isocitrate Lyase ,Carbon ,Pyruvate carboxylase ,Alcohol Oxidoreductases ,030104 developmental biology ,Metabolic Engineering ,chemistry ,Biochemistry ,Spectrophotometry ,Crotonates ,Acyl Coenzyme A ,Oxidation-Reduction - Abstract
The ethylmalonyl-CoA pathway (EMCP) is an anaplerotic reaction sequence in the central carbon metabolism of numerous Proteo- and Actinobacteria. The pathway features several CoA-bound mono- and dicarboxylic acids that are of interest as platform chemicals for the chemical industry. The EMCP, however, is essential for growth on C1 and C2 carbon substrates and therefore cannot be simply interrupted to drain these intermediates. In this study, we aimed at reengineering central carbon metabolism of the Alphaproteobacterium Methylobacterium extorquens AM1 for the specific production of EMCP derivatives in the supernatant. Establishing a heterologous glyoxylate shunt in M. extorquens AM1 restored wild type-like growth in several EMCP knockout strains on defined minimal medium with acetate as carbon source. We further engineered one of these strains that carried a deletion of the gene encoding crotonyl-CoA carboxylase/reductase to demonstrate in a proof-of-concept the specific production of crotonic acid in the supernatant on a defined minimal medium. Our experiments demonstrate that it is in principle possible to further exploit the EMCP by establishing an alternative central carbon metabolic pathway in M. extorquens AM1, opening many possibilities for the biotechnological production of EMCP-derived compounds in future.
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- 2017
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27. Activity and functional properties of the isocitrate lyase in the cyanobacterium Cyanothece sp. PCC 7424
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Henning Knoop, Marianne Gründel, and Ralf Steuer
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0301 basic medicine ,Cyanobacteria ,food.ingredient ,Photoperiod ,Cyanothece ,030106 microbiology ,Glyoxylate cycle ,Acetates ,Photosynthesis ,Microbiology ,03 medical and health sciences ,food ,Malate synthase ,Cell Proliferation ,biology ,Malate Synthase ,Glyoxylates ,Heterotrophic Processes ,Metabolism ,Isocitrate lyase ,biology.organism_classification ,Isocitrate Lyase ,Citric acid cycle ,Biochemistry ,biology.protein - Abstract
Cyanobacteria are ubiquitous photoautotrophs that assimilate atmospheric CO2 as their main source of carbon. Several cyanobacteria are known to be facultative heterotrophs that are able to grow on diverse carbon sources. For selected strains, assimilation of organic acids and mixotrophic growth on acetate has been reported for decades. However, evidence for the existence of a functional glyoxylate shunt in cyanobacteria has long been contradictory and unclear. Genes coding for isocitrate lyase (ICL) and malate synthase were recently identified in two strains of the genus Cyanothece, and the existence of the complete glyoxylate shunt was verified in a strain of Chlorogloeopsis fritschii. Here, we report that the gene PCC7424_4054 of the strain Cyanothece sp. PCC 7424 encodes an enzymatically active protein that catalyses the reaction of ICL, an enzyme that is specific for the glyoxylate shunt. We demonstrate that ICL activity is induced under alternating day/night cycles and acetate-supplemented cultures exhibit enhanced growth. In contrast, growth under constant light did not result in any detectable ICL activity or enhanced growth of acetate-supplemented cultures. Furthermore, our results indicate that, despite the presence of a glyoxylate shunt, acetate does not support continued heterotrophic growth and cell proliferation. The functional validation of the ICL is supplemented with a bioinformatics analysis of enzymes that co-occur with the glyoxylate shunt. We hypothesize that the glyoxylate shunt in Cyanothece sp. PCC 7424, and possibly other nitrogen-fixing cyanobacteria, is an adaptation to a specific ecological niche and supports assimilation of nitrogen or organic compounds during the night phase.
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- 2017
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28. Horticultural Production of Ultra High Resveratrol Peanut
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Jeneanne M. Kirven, Paul G. Johnson, Godson O. Osuji, Sela Woldesenbet, and Eustace Duffus
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0106 biological sciences ,chemistry.chemical_classification ,biology ,food and beverages ,Fatty acid ,General Medicine ,Isocitrate lyase ,Resveratrol ,Stilbenoid ,01 natural sciences ,Malate dehydrogenase ,chemistry.chemical_compound ,Biosynthesis ,chemistry ,Biochemistry ,010608 biotechnology ,Malate synthase ,biology.protein ,Phosphoenolpyruvate carboxylase ,010606 plant biology & botany - Abstract
Background: Resveratrol naturally occurring antioxidant in peanut (Legume: Arachis hypogaea) has phytochemical human health dietary effects associated with reduced inflammatory cancer risks. Its levels in peanut are ultra-low and variable (0 to 26 μg·g-1), which has made it difficult to market as a consistent high resveratrol produce. Objective: Understanding the regulation of resveratrol accumulation in peanut might lead to development of new techniques for optimizing and stabilizing its yield. Method: Peanuts were cultivated in horticultural field plots and treated with solutions of mineral salts (sulfate, potassium, phosphate, ammonium ion) that were optimized in stoichiometric (reactive) ratios. Peanut seed’s RNAs were subjected to Northern blot analysis for profiling the RNAs synthesized by glutamate dehydrogenase (GDH), and mRNAs encoding resveratrol synthase. The seed’s extracts were analyzed by GC-MS for determination of the resveratrol and fatty acid compositions. Result: Stoichiometric mixes of mineral ions induced the peanut GDH to synthesize some RNA that silenced the mRNAs encoding resveratrol synthase, phosphoglucomutase, isocitrate lyase, malate synthase, enolase, phosphoenolpyruvate carboxylase, malate dehydrogenase, and phosphoglycerate mutase in the control, KN-, and NPKS-treated but not in the NPPK-treated peanut. These resulted to decreased resveratrol content (6.0 μg·g-1) in the control peanut but maximized it (1.15 mg·g-1) in the NPPK-treated peanut. Therefore, resveratrol accumulation was optimized by coupling of glycolysis and citric-glyoxylic acid cycles to resveratrol biosynthesis. Fatty acid content of control (55.6 g·kg-1) was higher than the NPKS-treated (48.5 g·kg-1) and NPPK-treated peanut (44.9 g·kg-1) meaning that malonyl-CoA intermediate in both fatty acid and stilbenoid pathways was diverted to support maximum resveratrol biosynthesis in the NPPK-treated peanut. Conclusion: The functional coupling of citric-glyoxylic acid cycles and glycolysis to optimize resveratrol biosynthesis may encourage development of horticultural technology specific for production of ultra-high resveratrol peanuts.
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- 2017
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29. Alternative fate of glyoxylate during acetate and hexadecane metabolism in Acinetobacter oleivorans DR1
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Chulwoo Park, Bora Shin, and Woojun Park
- Subjects
0301 basic medicine ,030106 microbiology ,Mutant ,Glyoxylate cycle ,lcsh:Medicine ,Acetates ,medicine.disease_cause ,Article ,03 medical and health sciences ,chemistry.chemical_compound ,Lactate dehydrogenase ,Malate synthase ,Alkanes ,medicine ,lcsh:Science ,Escherichia coli ,Multidisciplinary ,biology ,Acinetobacter ,Dose-Response Relationship, Drug ,Gene Expression Profiling ,lcsh:R ,Wild type ,Malate Synthase ,Glyoxylates ,Isocitrate lyase ,Metabolism ,Gene Expression Regulation, Bacterial ,Isocitrate Lyase ,030104 developmental biology ,Soil microbiology ,Bacterial genes ,Biochemistry ,chemistry ,Mutation ,biology.protein ,lcsh:Q - Abstract
The glyoxylate shunt (GS), involving isocitrate lyase (encoded by aceA) and malate synthase G (encoded by glcB), is known to play important roles under several conditions including oxidative stress, antibiotic defense, or certain carbon source metabolism (acetate and fatty acids). Comparative growth analyses of wild type (WT), aceA, and glcB null-strains revealed that aceA, but not glcB, is essential for cells to grow on either acetate (1%) or hexadecane (1%) in Acinetobacter oleivorans DR1. Interestingly. the aceA knockout strain was able to grow slower in 0.1% acetate than the parent strain. Northern Blot analysis showed that the expression of aceA was dependent on the concentration of acetate or H2O2, while glcB was constitutively expressed. Up-regulation of stress response-related genes and down-regulation of main carbon metabolism-participating genes in a ΔaceA mutant, compared to that in the parent strain, suggested that an ΔaceA mutant is susceptible to acetate toxicity, but grows slowly in 0.1% acetate. However, a ΔglcB mutant showed no growth defect in acetate or hexadecane and no susceptibility to H2O2, suggesting the presence of an alternative pathway to eliminate glyoxylate toxicity. A lactate dehydrogenase (LDH, encoded by a ldh) could possibly mediate the conversion from glyoxylate to oxalate based on our RNA-seq profiles. Oxalate production during hexadecane degradation and impaired growth of a ΔldhΔglcB double mutant in both acetate and hexadecane-supplemented media suggested that LDH is a potential detoxifying enzyme for glyoxylate. Our constructed LDH-overexpressing Escherichia coli strain also showed an important role of LDH under lactate, acetate, and glyoxylate metabolisms. The LDH-overexpressing E. coli strain, but not wild type strain, produced oxalate under glyoxylate condition. In conclusion, the GS is a main player, but alternative glyoxylate pathways exist during acetate and hexadecane metabolism in A. oleivorans DR1.
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- 2019
30. Location, location! cellular relocalization primes specialized metabolic diversification
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Robert Last and Craig Schenck
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0301 basic medicine ,Metabolite ,Context (language use) ,Biology ,Biochemistry ,Metabolic engineering ,03 medical and health sciences ,chemistry.chemical_compound ,0302 clinical medicine ,NAD (+) and NADP (+) Dependent Alcohol Oxidoreductases ,Amino Acids ,Molecular Biology ,Hydro-Lyases ,chemistry.chemical_classification ,Nucleotides ,Malate Synthase ,Cell Biology ,Plants ,Subcellular localization ,Phenotype ,Cell biology ,Metabolic pathway ,030104 developmental biology ,Enzyme ,chemistry ,Metabolic Engineering ,030220 oncology & carcinogenesis ,biology.protein ,Enzyme promiscuity - Abstract
Specialized metabolites are structurally diverse and cell- or tissue-specific molecules produced in restricted plant lineages. In contrast, primary metabolic pathways are highly conserved in plants and produce metabolites essential for all of life, such as amino acids and nucleotides. Substrate promiscuity - the capacity to accept non-native substrates - is a common characteristic of enzymes, and its impact is especially apparent in generating specialized metabolite variation. However, promiscuity only leads to metabolic diversity when alternative substrates are available; thus, enzyme cellular and subcellular localization directly influence chemical phenotypes. We review a variety of mechanisms that modulate substrate availability for promiscuous plant enzymes. We focus on examples where evolution led to modification of the 'cellular context' through changes in cell-type expression, subcellular relocalization, pathway sequestration, and cellular mixing via tissue damage. These varied mechanisms contributed to the emergence of structurally diverse plant specialized metabolites and inform future metabolic engineering approaches.
- Published
- 2019
31. Progesterone Promotes Mitochondrial Respiration at the Biochemical and Molecular Level in Germinating Maize Seeds
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Hulya Turk
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0106 biological sciences ,food.ingredient ,Plant Science ,progesterone ,maize ,01 natural sciences ,Article ,03 medical and health sciences ,food ,mitochondrial respiration ,Malate synthase ,Citrate synthase ,Cytochrome c oxidase ,Ecology, Evolution, Behavior and Systematics ,030304 developmental biology ,chemistry.chemical_classification ,0303 health sciences ,Ecology ,biology ,ATP synthase ,Chemistry ,Botany ,Isocitrate lyase ,Pyruvate dehydrogenase complex ,Enzyme ,germination ,Biochemistry ,QK1-989 ,gene expression ,biology.protein ,Cotyledon ,010606 plant biology & botany - Abstract
This research aimed to investigate the effects of progesterone, a mammalian steroid sex hormone, on the mitochondrial respiration in germinating maize seeds. For this purpose, maize seeds were divided into four different groups (control, 10−6, 10−8, and 10−10 mol·L−1 progesterone) and were grown in a germination cabinet in the dark at 24.5 ± 0.5 °C for 4 d. The changes in gene expression levels of citrate synthase (CS), cytochrome oxidase (COX19), pyruvate dehydrogenase (Pdh1), and ATP synthase (ATP6), which is involved in mitochondrial respiration, were studied in root and cotyledon tissues. Significant increases were recorded in the gene expression levels of all studied enzymes. In addition, progesterone applications stimulated activities of malate synthase (MS), isocitrate lyase (ICL), and alpha-amylase, which are important enzymes of the germination step. The changes in gene expression levels of mas1 and icl1 were found parallel to the rise in these enzymes’ activities. It was determined similar increases in root and coleoptile lengths and total soluble protein and total carbohydrate contents. The most remarkable changes were detected in 10−8 mol·L−1 progesterone-treated seedlings. These results clearly indicate that progesterone stimulates mitochondrial respiration by inducing biochemical and molecular parameters and thus accelerates seed germination thanks to the activation of other pathways related to mitochondrial respiration.
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- 2021
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32. Modeling, molecular docking, probing catalytic binding mode of acetyl-CoA malate synthase G in Brucella melitensis 16M
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Pradeepkiran Jangampalli Adi, Bhaskar Matcha, and Nanda Kumar Yellapu
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Virtual screening ,0301 basic medicine ,Biophysics ,Glyoxylate cycle ,Protein Data Bank (RCSB PDB) ,Biochemistry ,Docking ,03 medical and health sciences ,chemistry.chemical_compound ,Malate synthase ,Malate synthase G ,chemistry.chemical_classification ,030102 biochemistry & molecular biology ,biology ,Acetyl-CoA ,Modeling ,MODELLER ,biology.organism_classification ,030104 developmental biology ,Enzyme ,chemistry ,Docking (molecular) ,biology.protein ,Catalytic function ,Brucella melitensis - Abstract
There are enormous evidences and previous reports standpoint that the enzyme of glyoxylate pathway malate synthase G (MSG) is a potential virulence factor in several pathogenic organisms, including Brucella melitensis 16M. Where the lack of crystal structures for best candidate proteins like MSG of B. melitensis 16M creates big lacuna to understand the molecular pathogenesis of brucellosis. In the present study, we have constructed a 3-D structure of MSG of Brucella melitensis 16M in MODELLER with the help of crystal structure of Mycobacterium tuberculosis malate synthase (PDB ID: 2GQ3) as template. The stereo chemical quality of the restrained model was evaluated by SAVES server; remarkably we identified the catalytic functional core domain located at 4th cleft with conserved catalytic amino acids, start at ILE 59 to VAL 586 manifest the function of the protein. Furthermore, virtual screening and docking results reveals that best leadmolecules binds at the core domain pocket of MSG catalytic residues and these ligand leads could be the best prospective inhibitors to treat brucellosis.
- Published
- 2016
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33. Production of citramalate by metabolically engineeredEscherichia coli
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Xianghao Wu and Mark A. Eiteman
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0301 basic medicine ,Acetate kinase ,biology ,030106 microbiology ,Acetyl-CoA ,Bioengineering ,Industrial fermentation ,medicine.disease_cause ,Applied Microbiology and Biotechnology ,Metabolic engineering ,03 medical and health sciences ,chemistry.chemical_compound ,030104 developmental biology ,chemistry ,Biochemistry ,Malate synthase ,Lactate dehydrogenase ,biology.protein ,medicine ,Citrate synthase ,Escherichia coli ,Biotechnology - Abstract
Citramalic acid (citramalate) is a five carbon hydroxy-dicarboxylic acid and potential precursor for the production of methacrylic acid from renewable resources. We examined citramalate production in Escherichia coli expressing the citramalate synthase gene cimA. Although, knockouts in ldhA coding lactate dehydrogenase and glcB/aceB coding malate synthase did not benefit citramalate accumulation, knockouts in gltA coding citrate synthase, and ackA coding acetate kinase significantly increased citramalate accumulation compared to the control strain. A fed-batch process in a controlled fermenter using a glucose feed resulted in 46.5 g/L citramalate in 132 h with a yield of 0.63 g/g, over 75% of the theoretical maximum yield from glucose of 0.82 g/g. Biotechnol. Bioeng. 2016;113: 2670-2675. © 2016 Wiley Periodicals, Inc.
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- 2016
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34. Peroxisomal microbodies are at the crossroads of acetate assimilation in the green microalga Chlamydomonas reinhardtii
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Kyle J. Lauersen, Marine Joris, Rémi Willamme, Nadine Coosemans, Olaf Kruse, and Claire Remacle
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0106 biological sciences ,0301 basic medicine ,Glyoxylate cycle ,Chlamydomonas reinhardtii ,Isocitrate lyase ,Biology ,Peroxisome ,biology.organism_classification ,01 natural sciences ,Malate dehydrogenase ,03 medical and health sciences ,030104 developmental biology ,Biochemistry ,Malate synthase ,Glyoxysome ,biology.protein ,Microbody ,Agronomy and Crop Science ,010606 plant biology & botany - Abstract
The glyoxylate cycle is essential for growth on C2 compounds such as acetate. In this investigation, for the first time, we have elucidated the subcellular localization of the enzymes of the glyoxylate cycle in the green microalga Chlamydomonas reinhardtii. Acetyl-CoA synthase and malate dehydrogenase exist as multiple isoforms in this microalga, therefore, we first identified those implicated in the glyoxylate cycle based on the observation that lack of isocitrate lyase (ICL) in a previously identified icl deficient mutant was correlated with specific loss of the other enzymes of the glyoxylate cycle. In this work, we determined that five of the six enzymes associated with the glyoxylate cycle were found to be within peroxisomal microbodies. Citrate synthase, aconitase, malate synthase, malate dehydrogenase, and acetyl-CoA synthase are located in peroxisomal microbodies while isocitrate lyase is cytosolic. Our findings implicate a key role for these cellular compartments in acetate assimilation for Chlamydomonas. Microbodies have only recently been discovered in C. reinhardtii and their existence had been previously debated. The isoform specific subcellular localization determined here suggests that peroxisomal microbodies should be considered in the design of metabolic models for carbon assimilation in C. reinhardtii.
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- 2016
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35. Role of Glyoxylate Shunt in Oxidative Stress Response
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Woojun Park, Eugene L. Madsen, Jaejoon Jung, In Ae Jang, and Sung-Eun Ahn
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0301 basic medicine ,030106 microbiology ,Glyoxylate cycle ,Oxidative phosphorylation ,Acetates ,medicine.disease_cause ,Microbiology ,Biochemistry ,03 medical and health sciences ,Oxygen Consumption ,Malate synthase ,Aerobic denitrification ,medicine ,Molecular Biology ,biology ,Malate Synthase ,Computational Biology ,Glyoxylates ,Gene Expression Regulation, Bacterial ,Cell Biology ,Isocitrate lyase ,Isocitrate Lyase ,Citric acid cycle ,Oxidative Stress ,Metabolic pathway ,Biofilms ,Pseudomonas aeruginosa ,biology.protein ,Transcriptome ,Genome, Bacterial ,Metabolic Networks and Pathways ,Oxidative stress - Abstract
The glyoxylate shunt (GS) is a two-step metabolic pathway (isocitrate lyase, aceA; and malate synthase, glcB) that serves as an alternative to the tricarboxylic acid cycle. The GS bypasses the carbon dioxide-producing steps of the tricarboxylic acid cycle and is essential for acetate and fatty acid metabolism in bacteria. GS can be up-regulated under conditions of oxidative stress, antibiotic stress, and host infection, which implies that it plays important but poorly explored roles in stress defense and pathogenesis. In many bacterial species, including Pseudomonas aeruginosa, aceA and glcB are not in an operon, unlike in Escherichia coli. In P. aeruginosa, we explored relationships between GS genes and growth, transcription profiles, and biofilm formation. Contrary to our expectations, deletion of aceA in P. aeruginosa improved cell growth under conditions of oxidative and antibiotic stress. Transcriptome data suggested that aceA mutants underwent a metabolic shift toward aerobic denitrification; this was supported by additional evidence, including up-regulation of denitrification-related genes, decreased oxygen consumption without lowering ATP yield, increased production of denitrification intermediates (NO and N2O), and increased cyanide resistance. The aceA mutants also produced a thicker exopolysaccharide layer; that is, a phenotype consistent with aerobic denitrification. A bioinformatic survey across known bacterial genomes showed that only microorganisms capable of aerobic metabolism possess the glyoxylate shunt. This trend is consistent with the hypothesis that the GS plays a previously unrecognized role in allowing bacteria to tolerate oxidative stress.
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- 2016
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36. Elevated intracellular acetyl-CoA availability by acs2 overexpression and mls1 deletion combined with metK1 introduction enhanced SAM accumulation in Saccharomyces cerevisiae
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Jie Dou, Hui Wang, Yang Yang, Changlin Zhou, Hailong Chen, and Zhilai Wang
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0301 basic medicine ,Environmental Engineering ,Methionine ,ATP synthase ,biology ,Acetyl-CoA ,Saccharomyces cerevisiae ,Biomedical Engineering ,Bioengineering ,biology.organism_classification ,Molecular biology ,03 medical and health sciences ,chemistry.chemical_compound ,030104 developmental biology ,Biochemistry ,chemistry ,Biosynthesis ,Methionine Adenosyltransferase ,Malate synthase ,biology.protein ,Intracellular ,Biotechnology - Abstract
S-Adenosyl- l -methionine (SAM), with diverse pharmaceutical applications, is biosynthesized from l -methionine and ATP. To enhance SAM accumulation in Saccharomyces cerevisiae CGMCC 2842 (2842), a new strategy based on yeast acetyl-CoA metabolism combined with introducing a methionine adenosyltransferase (metK1) from Leishmania infantum, was presented here. It was found that over-expressing acs2 (encoding acetyl-CoA synthase) and deleting mls1 (encoding malate synthase) increased SAM by 0.86- and 1.30-fold, respectively. To eliminate feedback inhibition of SAM synthase, a codon-optimized metK1 was introduced into 2842, and an increase of 1.45-fold of SAM was observed. Subsequently, metK1 and acs2 were co-expressed in the mls1 deleted strain, obtained the highly SAM-productive strain Ymls1 △GAPmK, and 2.22 g/L of SAM accumulated, which was 3.36-fold that in 2842. Moreover, the Ymls1 △GAPmK strain yielded 6.06 g/L SAM, which was 9.18-fold that in 2842, by fed-batch fermentation in a 10-L fermenter. Finally, the isolation and purification of SAM from yeast cell and preparation of SAM sulfate were preliminarily investigated. This study demonstrated that up-regulating acs2 and deleting mls1, which elevated intracellular acetyl-CoA levels, effectively enhanced the intracellular methionine biosynthesis. The elevated intracellular acetyl-CoA levels ultimately enhanced SAM accumulation, whereas the introduction of metK1 enhanced the redirection of acetyl-CoA to SAM biosynthesis in Ymls1 △GAPmK strain.
- Published
- 2016
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37. Characterisation and structural analysis of glyoxylate cycle enzymes of Teladorsagia circumcincta
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Nikola Palevich, Charlotte L.G. Bouchet, Saleh Umair, and Heather V. Simpson
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Models, Molecular ,Protein Conformation ,030231 tropical medicine ,Glyoxylate cycle ,medicine.disease_cause ,law.invention ,Structure-Activity Relationship ,03 medical and health sciences ,0302 clinical medicine ,law ,Malate synthase ,parasitic diseases ,medicine ,Animals ,Amino Acid Sequence ,Molecular Biology ,Escherichia coli ,030304 developmental biology ,chemistry.chemical_classification ,0303 health sciences ,Trichostrongyloidea ,biology ,Malate Synthase ,Glyoxylates ,Helminth Proteins ,Isocitrate lyase ,Hydrogen-Ion Concentration ,Recombinant Proteins ,Teladorsagia circumcincta ,Amino acid ,Enzyme Activation ,Molecular Weight ,Enzyme ,chemistry ,Biochemistry ,biology.protein ,Recombinant DNA ,Parasitology - Abstract
A 1332 bp full length cDNA encoding Teladorsagia circumcincta isocitrate lyase (TciICL) and a 1575 bp full length cDNA encoding T. circumcincta malate synthase (TciMS) were cloned, expressed in Escherichia coli and the recombinant proteins purified. The predicted TciICL protein of 444 amino acids was present as a single band of about 52 kDa on SDS-PAGE and the recombinant TciMS of 525 amino acids formed a single band about 62 kDa. Multiple alignments of the combined bifunctional TciICL MS protein sequence with homologues from other nematodes showed that the greatest similarity (89-92%) to the homologues of Ancylostoma ceylanicum, Haemonchus contortus and Haemonchus placei and 71-87% similarity to the other nematode sequences. The 3-dimensional structures, binding and catalytic sites were determined for TciICL and TciMS and shown to be highly conserved. Substrate and metal ion binding sites were identified and were completely conserved in other homologues. TciICL was confirmed as a functional enzyme. At 30 °C, the optimum pH was pH 7.5, the Vmax was 275 ± 23 nmoles.min-1.mg-1 protein and the apparent Km for the substrate isocitrate was 0.7 ± 0.01μM (mean ± SEM, n = 3). Addition of 10 mM metal ions (except Mg2+) or 1 mM inhibitors reduced the recombinant TciICL activity by 60-90%. Antibodies in both serum and saliva from field-immune, but not nematode-naïve, sheep recognised recombinant TciICL in ELISA, supporting similar antigenicity to that of the native enzyme.
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- 2020
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38. Recent developments in isotope-aided NMR methods for supramolecular protein complexes –SAIL aromatic TROSY
- Author
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Yohei Miyanoiri, Masatsune Kainosho, Mitsuhiro Takeda, and Tsutomu Terauchi
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0301 basic medicine ,Magnetic Resonance Spectroscopy ,Macromolecular Substances ,Stereochemistry ,Phenylalanine ,Biophysics ,Supramolecular chemistry ,010402 general chemistry ,Ring (chemistry) ,01 natural sciences ,Biochemistry ,Protein Structure, Secondary ,03 medical and health sciences ,chemistry.chemical_compound ,Amide ,Escherichia coli ,Lipid bilayer ,Molecular Biology ,chemistry.chemical_classification ,Carbon Isotopes ,Chemical shift ,Relaxation (NMR) ,Malate Synthase ,Tryptophan ,Proteins ,0104 chemical sciences ,Amino acid ,030104 developmental biology ,chemistry ,Structural biology ,Mutation ,Protons ,Peptides - Abstract
Background The structure-function relationships for large protein complexes at the atomic level would be comprehensively understood, if hitherto unexplored aromatic ring NMR signals became accessible in addition to the currently used backbone amide and side-chain methyl signals. Methods The 82 kDa malate synthase G (MSG) proteins, selectively labeled with Trp and Phe bearing relaxation optimized isotope-labeled rings, were prepared to investigate the optimal conditions for obtaining the aromatic TROSY spectra. Results The MSG proteins, selectively labeled with either [δ1,e1,e3,η2]-SAIL Trp or ζ-SAIL Phe, provided well-separated, narrow TROSY signals for the 12 Trp and 19 Phe residues in MSG. The signals were assigned sequence-specifically, using the set of single amino acid substitution mutants. The site-specific substitution of each Phe with Tyr or Leu induced substantial chemical shifts for the other aromatic ring signals, allowing us to identify the aromatic clusters in MSG, which were comparable to the structural domains proposed previously. Conclusions We demonstrated that the aromatic ring 13CH pairs without directly bonded 13C and adjacent 1H spins provide surprisingly narrow TROSY signals, if the rings are surrounded by fully deuterated amino acids. The observed signals can be readily assigned by either the single amino acid substitution or the NOEs between the aromatic and methyl protons, if the methyl assignments are available. General significance The method described here should be generally applicable for difficult targets, such as proteins in lipid bilayers or possibly in living cells, thus providing unprecedented opportunities to use these new probes in structural biology.
- Published
- 2020
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39. The Glyoxylate Shunt, 60 Years On
- Author
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Martin Welch and Stephen K. Dolan
- Subjects
0301 basic medicine ,030102 biochemistry & molecular biology ,biology ,Glyoxylate cycle ,Glyoxylates ,Isocitrate lyase ,Metabolism ,Microbiology ,Carbon ,Metabolic Flux Analysis ,Shunt (medical) ,Citric acid cycle ,03 medical and health sciences ,030104 developmental biology ,Biochemistry ,Malate synthase ,biology.protein ,Escherichia coli ,Flux (metabolism) ,Oxidative decarboxylation ,Metabolic Networks and Pathways - Abstract
2017 marks the 60th anniversary of Krebs’ seminal paper on the glyoxylate shunt (and coincidentally, also the 80th anniversary of his discovery of the citric acid cycle). Sixty years on, we have witnessed substantial developments in our understanding of how flux is partitioned between the glyoxylate shunt and the oxidative decarboxylation steps of the citric acid cycle. The last decade has shown us that the beautifully elegant textbook mechanism that regulates carbon flux through the shunt in E. coli is an oversimplification of the situation in many other bacteria. The aim of this review is to assess how this new knowledge is impacting our understanding of flux control at the TCA cycle/glyoxylate shunt branch point in a wider range of genera, and to summarize recent findings implicating a role for the glyoxylate shunt in cellular functions other than metabolism.
- Published
- 2018
40. Overproduction of recombinant E. coli malate synthase enhances Chlamydomonas reinhardtii biomass by upregulating heterotrophic metabolism
- Author
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Joonwon Kim, Noo Li Jeon, Sang-Min Paik, and EonSeon Jin
- Subjects
0106 biological sciences ,Environmental Engineering ,Glyoxylate cycle ,Malates ,Chlamydomonas reinhardtii ,Bioengineering ,010501 environmental sciences ,Photosynthesis ,01 natural sciences ,Malate dehydrogenase ,010608 biotechnology ,Malate synthase ,Escherichia coli ,Biomass ,Waste Management and Disposal ,0105 earth and related environmental sciences ,biology ,Renewable Energy, Sustainability and the Environment ,Chemistry ,Malate Synthase ,Glyoxylates ,Heterotrophic Processes ,General Medicine ,Metabolism ,Isocitrate lyase ,biology.organism_classification ,Isocitrate Lyase ,Up-Regulation ,Citric acid cycle ,Biochemistry ,biology.protein - Abstract
High uptake of malate and efficient distribution of intracellular malate to organelles contributed to biomass increase, reducing maintenance energy. In this study, transgenic Chlamydomonas reinhardtii was developed that stably expresses malate synthase in the chloroplast. The strains under glyoxylate treatment showed 19% more increase in microalgal biomass than wild-type. By RNA analysis, transcript levels of malate dehydrogenase (MDH4) and acetyl-CoA synthetase (ACS3), isocitrate lyase (ICL1) and malate synthase (MAS1), were significantly more expressed (17%, 42%, 24%, and 18% respectively), which was consistent with reported heterotrophic metabolism flux analysis with the objective function maximizing biomass. Photosynthetic Fv/Fm was slightly reduced. A more meticulous analysis is necessary, but, in the transgenic microalgae with malate synthase overexpression, the metabolism is likely to more rely on heterotrophic energy production via TCA cycle and glyoxylate shunt than on photosynthesis, resulting in the increase in microalgal biomass.
- Published
- 2018
41. Microbial production of glycolate from acetate by metabolically engineered Escherichia coli
- Author
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Jing Chen, Wei Li, Qipeng Yuan, Zheng-Jun Li, and Chang-Xia Liu
- Subjects
0106 biological sciences ,0301 basic medicine ,Hydroxypyruvate reductase ,Glyoxylate cycle ,Bioengineering ,Citrate (si)-Synthase ,Acetates ,Protein Serine-Threonine Kinases ,medicine.disease_cause ,01 natural sciences ,Applied Microbiology and Biotechnology ,03 medical and health sciences ,010608 biotechnology ,Malate synthase ,medicine ,Escherichia coli ,Citrate synthase ,Acetate kinase ,biology ,Chemistry ,General Medicine ,Isocitrate lyase ,Isocitrate Lyase ,Glycolates ,Citric acid cycle ,Alcohol Oxidoreductases ,030104 developmental biology ,Biochemistry ,Metabolic Engineering ,biology.protein ,Biotechnology - Abstract
Escherichia coli was metabolically engineered to synthesize glycolate using acetate as the carbon source. The native glyoxylate bypass pathway was reinforced by the overexpression of isocitrate lyase and isocitrate dehydrogenase kinase/phosphatase. Glyoxylate/hydroxypyruvate reductase was overexpressed to convert glyoxylate to glycolate. Meanwhile, side reactions were eliminated by inactivating genes encoding malate synthase, glyoxylate carboligase, and glycolate oxidase to prevent loss of glyoxylate and glycolate. The engineered E. coli produced 1.78 g/L glycolate from 3.23 g/L acetate after 48 h shake flask cultivation using minimal medium supplemented with 1 g/L yeast extract. When citrate synthase, phosphotransacetylase, and acetate kinase were co-overexpressed to strengthen the tricarboxylic acid cycle and acetate utilization, glycolate production titer was improved to 2.75 g/L with pH control in shake flasks. The results of this work offer an approach for producing glycolate using acetate as the carbon source.
- Published
- 2018
42. Lack of glyoxylate shunt dysregulates iron homeostasis in Pseudomonas aeruginosa
- Author
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Sunhee Ha, Woojun Park, and Bora Shin
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0301 basic medicine ,Cytoplasm ,Operon ,Iron ,030106 microbiology ,Citric Acid Cycle ,Glyoxylate cycle ,medicine.disease_cause ,Microbiology ,Electron Transport ,03 medical and health sciences ,Bacterial Proteins ,Malate synthase ,medicine ,Homeostasis ,biology ,Chemistry ,Malate Synthase ,Glyoxylates ,Isocitrate lyase ,Gene Expression Regulation, Bacterial ,Hydrogen Peroxide ,Isocitrate Lyase ,Isocitrate Dehydrogenase ,Citric acid cycle ,Oxidative Stress ,030104 developmental biology ,Isocitrate dehydrogenase ,Biochemistry ,Mutation ,Pseudomonas aeruginosa ,biology.protein ,Oxidative stress ,Intracellular - Abstract
The aceA and glcB genes, encoding isocitrate lyase (ICL) and malate synthase, respectively, are not in an operon in many bacteria, including Pseudomonas aeruginosa, unlike in Escherichia coli. Here, we show that expression of aceA in P. aeruginosa is specifically upregulated under H2O2-induced oxidative stress and under iron-limiting conditions. In contrast, the addition of exogenous redox active compounds or antibiotics increases the expression of glcB. The transcriptional start sites of aceA under iron-limiting conditions and in the presence of iron were found to be identical by 5′ RACE. Interestingly, the enzymatic activities of ICL and isocitrate dehydrogenase had opposite responses under different iron conditions, suggesting that the glyoxylate shunt (GS) might be important under iron-limiting conditions. Remarkably, the intracellular iron concentration was lower while the iron demand was higher in the GS-activated cells growing on acetate compared to cells growing on glucose. Absence of GS dysregulated iron homeostasis led to changes in the cellular iron pool, with higher intracellular chelatable iron levels. In addition, GS mutants were found to have higher cytochrome c oxidase activity on iron-supplemented agar plates of minimal media, which promoted the growth of the GS mutants. However, deletion of the GS genes resulted in higher sensitivity to a high concentration of H2O2, presumably due to iron-mediated killing. In conclusion, the GS system appears to be tightly linked to iron homeostasis in the promotion of P. aeruginosa survival under oxidative stress.
- Published
- 2018
43. Metabolic engineering of E. coli for efficient production of glycolic acid from glucose
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Yu Deng, Xiaojuan Zhang, and Yin Mao
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Environmental Engineering ,biology ,Biomedical Engineering ,Glyoxylate cycle ,Bioengineering ,Isocitrate lyase ,medicine.disease_cause ,Metabolic engineering ,chemistry.chemical_compound ,Biochemistry ,chemistry ,Malate synthase ,biology.protein ,medicine ,Fermentation ,Escherichia coli ,Glyoxylate reductase ,Glycolic acid ,Biotechnology - Abstract
Glycolic acid is the smallest member of the α-hydroxy acid family. In order to produce glycolate from glucose via the glyoxylate shunt stably, one malate synthase gene aceB in Escherichia coli BW25113 was deleted by homologous recombination; another malate synthase gene glcB was then replaced by a DNA cassette WAK harboring isocitrate lyase gene (aceA), glyoxylate reductase gene (ycdW) and isocitrate dehydrogenase kinase/phosphatase gene (aceK). The above three genes were over-expressed in the chromosome of E. coli EYX-1WAK. This strain was then transferred 20 times on M9 medium to have a mutant strain: EYX-2 with a significantly improved growth rate. The glycolate yields of EYX-2 in the shaken flasks and the 5-L bioreactor using batch fermentation strategy under 2 vvm aeration and 800 rpm stirring speed were 0.33 g/g-glucose and 0.48 g/g-glucose, respectively. The fed-batch fermentation of EYX-2 on 120 g/L glucose had the highest titer of 56.44 g/L with 0.52 g/g-glucose yield in 120 h, and this is the highest reported glycolate yield ever.
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- 2015
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44. The Sinorhizobium meliloti glyoxylate cycle enzyme isocitrate lyase (AceA) is required for the utilization of poly-β-hydroxybutyrate during carbon starvation
- Author
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Ramón Suárez-Rodríguez, Michael F. Dunn, José Augusto Ramírez-Trujillo, and Ismael Hernández-Lucas
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0301 basic medicine ,chemistry.chemical_classification ,Sinorhizobium meliloti ,Catabolism ,030106 microbiology ,technology, industry, and agriculture ,Glyoxylate cycle ,macromolecular substances ,Isocitrate lyase ,Biology ,biology.organism_classification ,Applied Microbiology and Biotechnology ,Citric acid cycle ,03 medical and health sciences ,Enzyme ,chemistry ,Biochemistry ,Malate synthase ,biology.protein ,lipids (amino acids, peptides, and proteins) ,Bacteria - Abstract
The glyoxylate cycle is an anaplerotic pathway of the tricarboxylic acid cycle that allows bacteria to grow using acetate, fatty acids, or poly-β-hydroxybutyrate (PHB). In Sinorhizobium meliloti, activities of the glyoxylate cycle enzymes isocitrate lyase (AceA) and malate synthase (GlcB) are present during growth on these kinds of carbon sources, but a study of the importance of these enzymes in utilizing these carbon compounds under starvation conditions has not been done. We therefore evaluated the role of AceA and GlcB in the utilization of PHB by determining the PHB degradative and growth capacities of the S. meliloti wild type and aceA and glcB mutants under carbon starvation conditions in culture. We found that only the aceA gene product was essential for bacterial growth and PHB degradation under these conditions, presumably by generating succinate from the acetyl-CoA derived from PHB catabolism, thus allowing the cells to grow in the absence of an external carbon source.
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- 2015
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45. Functional and genomic diversity of methylotrophic Rhodocyclaceae: description of Methyloversatilis discipulorum sp. nov
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Nicole Shapiro, Paolo De Marco, Nina V. Doronina, Nikos C. Kyrpides, Tanja Woyke, Sami J. Taipale, Nicole E. Smalley, and Marina G. Kalyuzhnaya
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DNA, Bacterial ,Washington ,Geologic Sediments ,Rhodocyclaceae ,Sequence analysis ,Molecular Sequence Data ,lake sediments ,Microbiology ,Phylogenetics ,RNA, Ribosomal, 16S ,Malate synthase ,Phylogeny ,Ecology, Evolution, Behavior and Systematics ,Genetics ,biology ,Methanol dehydrogenase ,ta1184 ,phylogenetic analysis ,ta1183 ,Fatty Acids ,Genomics ,Sequence Analysis, DNA ,General Medicine ,Isocitrate lyase ,Ribosomal RNA ,16S ribosomal RNA ,biology.organism_classification ,Bacterial Typing Techniques ,Alcohol Oxidoreductases ,Lakes ,Biochemistry ,biology.protein ,metabolism ,Genome, Bacterial - Abstract
Three strains of methylotrophic Rhodocyclaceae (FAM1T, RZ18-153 and RZ94) isolated from Lake Washington sediment samples were characterized. Based on phylogenetic analysis of 16S rRNA gene sequences the strains should be assigned to the genus Methyloversatilis. Similarly to other members of the family, the strains show broad metabolic capabilities and are able to utilize a number of organic acids, alcohols and aromatic compounds in addition to methanol and methylamine. The main fatty acids were 16:1ω7c (49–59 %) and 16:0 (32–29 %). Genomes of all isolates were sequenced, assembled and annotated in collaboration with the DOE Joint Genome Institute (JGI). Genome comparison revealed that the strains FAM1T, RZ18-153 and RZ94 are closely related to each other and almost equally distant from two previously described species of the genus Methyloversatilis, Methyloversatilis universalis and Methyloversatilis thermotolerans. Like other methylotrophic species of the genus Methyloversatilis, all three strains possess one-subunit PQQ-dependent ethanol/methanol dehydrogenase (Mdh-2), the N-methylglutamate pathway and the serine cycle (isocitrate lyase/malate synthase, Icl/ms+ variant). Like M. universalis, strains FAM1T, RZ18-153 and RZ94 have a quinohemoprotein amine dehydrogenase, a tungsten-containing formaldehyde ferredoxin oxidoreductase, phenol hydroxylase, and the complete Calvin cycle. Similarly to M. thermotolerans, the three strains possess two-subunit methanol dehydrogenase (MxaFI), monoamine oxidase (MAO) and nitrogenase. Based on the phenotypic and genomic data, the strains FAM1T, RZ18-153 and RZ94 represent a novel species of the genus Methyloversatilis, for which the name Methyloversatilis discipulorum sp. nov. is proposed. The type strain is FAM1T ( = JCM 30542T = VKM = B-2888T).
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- 2015
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46. The glyoxylate shunt is essential for CO2-requiring oligotrophic growth of Rhodococcus erythropolis N9T-4
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Miki Wakamatsu, Fujio Yu, Nobuyuki Yoshida, Hiroshi Takagi, and Takanori Yano
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Microbial Viability ,biology ,Glyoxylate cycle ,Glyoxylates ,Dehydrogenase ,General Medicine ,Isocitrate lyase ,Carbon Dioxide ,Applied Microbiology and Biotechnology ,Culture Media ,Succinic semialdehyde ,Citric acid cycle ,chemistry.chemical_compound ,Biochemistry ,Gluconeogenesis ,chemistry ,Mutagenesis ,Malate synthase ,biology.protein ,Rhodococcus ,Phosphoenolpyruvate carboxykinase ,Metabolic Networks and Pathways ,Biotechnology - Abstract
Rhodococcus erythropolis N9T-4 shows extremely oligotrophic growth requiring atmospheric CO2 and forms its colonies on an inorganic basal medium (BM) without any additional carbon source. Screening of a random mutation library constructed by a unique genome deletion method that we established indicated that the aceA, aceB, and pckG genes encoding isocitrate lyase, malate synthase, and phosphoenolpyruvate carboxykinase, respectively, were requisite for survival on BM plates. The aceA- and aceB deletion mutants and the pckG deletion mutant grew well on BM plates containing L-malate and D-glucose, respectively, suggesting that the glyoxylate (GO) shunt and gluconeogenesis are essential for the oligotrophic growth of N9T-4. Interestingly, most of the enzyme activities in the TCA cycle were observed in the cell-free extract of N9T-4, with perhaps the most important exception being α-ketoglutarate dehydrogenase (KGDH) activity. Instead of the KGDH activity, we detected a remarkable level of α-ketoglutarate decarboxylase (KGD) activity, which is the activity exhibited by the E1 component of the KGDH complex in Mycobacterium tuberculosis. The recombinant KGD of N9T-4 catalyzed the decarboxylation of α-ketoglutarate to form succinic semialdehyde (SSA) in a time-dependent manner. Since N9T-4 also showed a detectable SSA dehydrogenase activity, we concluded that N9T-4 possesses a variant TCA cycle, which uses SSA rather than succinyl-CoA. These results suggest that oligotrophic N9T-4 cells utilize the GO shunt to avoid the loss of carbons as CO2 and to conserve CoA units in the TCA cycle.
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- 2015
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47. The regulatory role of Streptomyces coelicolor TamR in central metabolism
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Hao Huang, Anne Grove, and Smitha Sivapragasam
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Citric Acid Cycle ,Glyoxylate cycle ,Streptomyces coelicolor ,Ligands ,Response Elements ,Biochemistry ,Malate dehydrogenase ,Aconitase ,Citric Acid ,Bacterial Proteins ,Species Specificity ,Genes, Reporter ,Malate Dehydrogenase ,Malate synthase ,Binding site ,Promoter Regions, Genetic ,Molecular Biology ,biology ,Aconitic Acid ,Malate Synthase ,Gene Expression Regulation, Bacterial ,Methyltransferases ,Cell Biology ,biology.organism_classification ,Isocitrate Dehydrogenase ,Recombinant Proteins ,Repressor Proteins ,Citric acid cycle ,Isocitrate dehydrogenase ,Enzyme Induction ,biology.protein ,Mutant Proteins - Abstract
Trans -aconitate methyltransferase regulator (TamR) is a member of the ligand-responsive multiple antibiotic resistance regulator (MarR) family of transcription factors. In Streptomyces coelicolor , TamR regulates transcription of tamR (encoding TamR), tam (encoding trans -aconitate methyltransferase) and sacA (encoding aconitase); up-regulation of these genes promotes metabolic flux through the citric acid cycle. DNA binding by TamR is attenuated and transcriptional derepression is achieved on binding of ligands such as citrate and trans -aconitate to TamR. In the present study, we show that three additional genes are regulated by S. coelicolor TamR. Genes encoding malate synthase ( aceB1 ; SCO6243 ), malate dehydrogenase ( mdh ; SCO4827 ) and isocitrate dehydrogenase ( idh ; SCO7000 ) are up-regulated in vivo when citrate and trans -aconitate accumulate, and TamR binds the corresponding gene promoters in vitro , a DNA binding that is attenuated by cognate ligands. Mutations to the TamR binding site attenuate DNA binding in vitro and result in constitutive promoter activity in vivo . The predicted TamR binding sites are highly conserved in the promoters of these genes in Streptomyce s species that encode divergent tam–tamR gene pairs, suggesting evolutionary conservation. Like aconitase and trans -aconitate methyltransferase, malate dehydrogenase, isocitrate dehydrogenase and malate synthase are closely related to the citric acid cycle, either catalysing individual reaction steps or, in the case of malate synthase, participating in the glyoxylate cycle to produce malate that enters the citric acid cycle to replenish the intermediate pool. Taken together, our data suggest that TamR plays an important and conserved role in promoting metabolic flux through the citric acid cycle. Abbreviations: EGFP, enhanced green fluorescent protein; EMSA, electrophoretic mobility shift assay(s); MarR, multiple antibiotic resistance regulator; qRT-PCR, quantitative reverse transcription–PCR; TamR, trans-aconitate methyltransferase regulator; TBE, Tris/borate/EDTA
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- 2015
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48. Enhanced polymalic acid production from the glyoxylate shunt pathway under exogenous alcohol stress
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Xiang Zou, Wenwen Yang, Jie Chen, Jun Feng, Jing Yang, and Min Jiang
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0106 biological sciences ,0301 basic medicine ,Polymers ,Mutant ,Glyoxylate cycle ,Malates ,Bioengineering ,01 natural sciences ,Applied Microbiology and Biotechnology ,Fungal Proteins ,03 medical and health sciences ,chemistry.chemical_compound ,Ascomycota ,Stress, Physiological ,010608 biotechnology ,Malate synthase ,Gene Expression Regulation, Fungal ,Inducer ,Ethanol ,biology ,Cell growth ,Malate Synthase ,Glyoxylates ,General Medicine ,biology.organism_classification ,Aureobasidium pullulans ,030104 developmental biology ,Biochemistry ,chemistry ,Batch Cell Culture Techniques ,Alcohols ,Fermentation ,biology.protein ,Genetic Engineering ,Biotechnology - Abstract
Polymalic acid (PMA) is a water-soluble biopolymer produced by the yeast-like fungus Aureobasidium pullulans. In this study, the physiological response of A. pullulans against exogenous alcohols stress was investigated. Interestingly, ethanol stress was an effective inducer of enhanced PMA yield, although cell growth was slightly inhibited. The stress-responsive gene malate synthase (mls), which is involved in the glyoxylate shunt, was identified and was found to be regulated by exogenous ethanol stress. Therefore, an engineered strain, YJ-MLS, was constructed by overexpressing the endogenous mls gene, which increased the PMA titer by 16.2% compared with the wild-type strain. Following addition of 1% (v/v) of ethanol, a high PMA titer of 40.0 ± 0.38 g/L was obtained using batch fermentation with the mutant YJ-MLS in a 5-L fermentor, with a strongest PMA productivity of 0.56 g/L h. This study was the interesting report to show strengthening of the carbon metabolic flow from the glyoxylate shunt for PMA synthesis, and also provided a new sight for re-recognizing the regulatory behavior of alcohol stress in eukaryotic microbes.
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- 2017
49. Plant-growth-promoting rhizobacteria Bacillus subtilis RR4 isolated from rice rhizosphere induces malic acid biosynthesis in rice roots
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Santhanam Srinath, Baburaj Baskar, B. Usha, and Kandaswamy Rekha
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0106 biological sciences ,0301 basic medicine ,030106 microbiology ,Immunology ,Malates ,Bacillus subtilis ,Rhizobacteria ,01 natural sciences ,Applied Microbiology and Biotechnology ,Microbiology ,Plant Roots ,03 medical and health sciences ,chemistry.chemical_compound ,Biosynthesis ,Malate synthase ,Botany ,Genetics ,Molecular Biology ,chemistry.chemical_classification ,Rhizosphere ,biology ,Chemotaxis ,Oryza ,General Medicine ,biology.organism_classification ,chemistry ,Biochemistry ,biology.protein ,Malic acid ,010606 plant biology & botany ,Organic acid - Abstract
Malic acid (MA), one of the major organic acid exudates from roots, plays a significant role in the chemotaxis of beneficial bacteria to the plant’s rhizosphere. In this study, the effect of a plant-growth-promoting rhizobacterium, Bacillus subtilis RR4, on the synthesis and exudation of MA from roots is demonstrated in rice. To test the chemotactic ability of strain RR4 towards MA, a capillary chemotaxis assay was performed, which revealed a positive response (relative chemotactic ratio of 6.15 with 10 μmol/L MA); with increasing concentrations of MA, an elevated chemotactic response was observed. Quantitative polymerase chain reaction, performed to analyze the influence of RR4 on the MA biosynthetic gene, malate synthase (OsMS), and the transporter gene, aluminium-activated malate transporter (OsALMT), demonstrated significant differential expression, with 1.8- and –0.58-fold changes, respectively, in RR4-treated roots. The gene expression pattern of OsMS corroborated the data obtained by high-performance liquid chromatography, which showed elevated MA levels in roots (1.52-fold), whereas the levels of MA in root exudates were not altered significantly although expression of OsALMT was reduced. Our results demonstrate that B. subtilis RR4 is chemotactic to MA and can induce biosynthesis of MA in rice roots.
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- 2017
50. Four Types of Novel Potential Malate Synthase Inhibitors from Virtual Screening
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Lan-Fang Hao, Yong He, Ming-Liang Chang, Chuan Zhao, and Shao-Yong Li
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Virtual screening ,biology ,Biochemistry ,Chemistry ,Malate synthase ,Drug Discovery ,biology.protein ,Molecular Medicine - Published
- 2017
- Full Text
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