Your search keyword '"Megan L. Kempher"' showing total 45 results

1. Experimental warming accelerates positive soil priming in a temperate grassland ecosystem

Author

Xuanyu Tao, Zhifeng Yang, Jiajie Feng, Siyang Jian, Yunfeng Yang, Colin T. Bates, Gangsheng Wang, Xue Guo, Daliang Ning, Megan L. Kempher, Xiao Jun A. Liu, Yang Ouyang, Shun Han, Linwei Wu, Yufei Zeng, Jialiang Kuang, Ya Zhang, Xishu Zhou, Zheng Shi, Wei Qin, Jianjun Wang, Mary K. Firestone, James M. Tiedje, and Jizhong Zhou

Subjects

Science

Abstract

Abstract Unravelling biosphere feedback mechanisms is crucial for predicting the impacts of global warming. Soil priming, an effect of fresh plant-derived carbon (C) on native soil organic carbon (SOC) decomposition, is a key feedback mechanism that could release large amounts of soil C into the atmosphere. However, the impacts of climate warming on soil priming remain elusive. Here, we show that experimental warming accelerates soil priming by 12.7% in a temperate grassland. Warming alters bacterial communities, with 38% of unique active phylotypes detected under warming. The functional genes essential for soil C decomposition are also stimulated, which could be linked to priming effects. We incorporate lab-derived information into an ecosystem model showing that model parameter uncertainty can be reduced by 32–37%. Model simulations from 2010 to 2016 indicate an increase in soil C decomposition under warming, with a 9.1% rise in priming-induced CO2 emissions. If our findings can be generalized to other ecosystems over an extended period of time, soil priming could play an important role in terrestrial C cycle feedbacks and climate change.

Published

2024

2. Bacterial type II toxin-antitoxin systems acting through post-translational modifications

Author

Si-Ping Zhang, Han-Zhong Feng, Qian Wang, Megan L. Kempher, Shuo-Wei Quan, Xuanyu Tao, Shaomin Niu, Yong Wang, Hu-Yuan Feng, and Yong-Xing He

Subjects

TA system, Phosphorylation, AMPylation, ADP-ribosylation, Acetylation, Persistence, Biotechnology, TP248.13-248.65

Abstract

The post-translational modification (PTM) serves as an important molecular switch mechanism to modulate diverse biological functions in response to specific cues. Though more commonly found in eukaryotic cells, many PTMs have been identified and characterized in bacteria over the past decade, highlighting the importance of PTMs in regulating bacterial physiology. Several bacterial PTM enzymes have been characterized to function as the toxin component of type II TA systems, which consist of a toxin that inhibits cell growth and an antitoxin that protects the cell from poisoning by the toxin. While TA systems can be classified into seven types based on nature of the antitoxin and its activity, type II TA systems are perhaps the most studied among the different TA types and widely distributed in eubacteria and archaea. The type II toxins possessing PTM activities typically modify various cellular targets mostly associated with protein translation and DNA replication. This review mainly focuses on the enzymatic activities, target specificities, antitoxin neutralizing mechanisms of the different families of PTM toxins. We also proposed that TA systems can be conceptually viewed as molecular switches where the ‘on’ and ‘off’ state of the system is tightly controlled by antitoxins and discussed the perspective on toxins having other physiologically roles apart from growth inhibition by acting on the nonessential cellular targets.

Published

2021

3. In vivo Functional Characterization of Hydrophilic X2 Modules in the Cellulosomal Scaffolding Protein

Author

Xuanyu Tao, Jiantao Liu, Megan L. Kempher, Tao Xu, and Jizhong Zhou

Subjects

cellulosome, X2 module, cellulose degradation, Clostridium cellulolyticum, motif deletion, Microbiology, QR1-502

Abstract

As part of free cellulases or scaffolding proteins in cellulosomes, the hydrophilic non-catalytic X2 module is widely distributed in cellulolytic Clostridia or other Firmicutes bacteria. Previous biochemical studies suggest that X2 modules might increase the solubility and substrate binding affinity of X2-bearing proteins. However, their in vivo biological functions remain elusive. Here we employed CRISPR-Cas9 editing to genetically modify X2 modules by deleting the conserved motif (NGNT) from the CipC scaffoldin. Both single and double X2 mutants (X2-N: near the N terminus of CipC; X2-C: near the C terminus of CipC) presented similar stoichiometric compositions in isolated cellulosomes as the wildtype strain (WT). These X2 mutants had an elongated adaptation stage during growth on cellulose compared to cellobiose. Compared to WT, the double mutant ΔX2-NC reduced cellulose degradation by 15% and the amount of released soluble sugars by 63%. Since single X2 mutants did not present such obvious physiological changes as ΔX2-NC, there seems to be a functional redundancy between X2 modules in CipC. The in vivo adhesion assay revealed that ΔX2-NC decreased cell attachment to cellulose by 70% but a weaker effect was also overserved in single X2 mutants. These results highlight the in vivo biological role of X2 in increasing cellulose degradation efficiency by enhancing the binding affinity between cells and cellulose, which provides new perspectives for microbial engineering.

Published

2022

4. Genomic Features and Pervasive Negative Selection in Rhodanobacter Strains Isolated from Nitrate and Heavy Metal Contaminated Aquifer

Author

Mu Peng, Dongyu Wang, Lauren M. Lui, Torben Nielsen, Renmao Tian, Megan L. Kempher, Xuanyu Tao, Chongle Pan, Romy Chakraborty, Adam M. Deutschbauer, Michael P. Thorgersen, Michael W. W. Adams, Matthew W. Fields, Terry C. Hazen, Adam P. Arkin, Aifen Zhou, and Jizhong Zhou

Subjects

Rhodanobacter, comparative genomics, methylation, negative selection, horizontal gene transfer, restriction-modification system genes, Microbiology, QR1-502

Abstract

ABSTRACT Rhodanobacter species dominate in the Oak Ridge Reservation (ORR) subsurface environments contaminated with acids, nitrate, metal radionuclides, and other heavy metals. To uncover the genomic features underlying adaptations to these mixed-waste environments and to guide genetic tool development, we sequenced the whole genomes of eight Rhodanobacter strains isolated from the ORR site. The genome sizes ranged from 3.9 to 4.2 Mb harboring 3,695 to 4,035 protein-coding genes and GC contents approximately 67%. Seven strains were classified as R. denitrificans and one strain, FW510-R12, as R. thiooxydans based on full length 16S rRNA sequences. According to gene annotation, the top two Cluster of Orthologous Groups (COGs) with high pan-genome expansion rates (Pan/Core gene ratio) were “replication, recombination and repair” and “defense mechanisms.” The denitrifying genes had high DNA homologies except the predicted protein structure variances in NosZ. In contrast, heavy metal resistance genes were diverse with between 7 to 34% of them were located in genomic islands, and these results suggested origins from horizontal gene transfer. Analysis of the methylation patterns in four strains revealed the unique 5mC methylation motifs. Most orthologs (78%) had ratios of nonsynonymous to synonymous substitutions (dN/dS) less than one when compared to the type strain 2APBS1, suggesting the prevalence of negative selection. Overall, the results provide evidence for the important roles of horizontal gene transfer and negative selection in genomic adaptation at the contaminated field site. The complex restriction-modification system genes and the unique methylation motifs in Rhodanobacter strains suggest the potential recalcitrance to genetic manipulation. IMPORTANCE Despite the dominance of Rhodanobacter species in the subsurface of the contaminated Oak Ridge Reservation (ORR) site, very little is known about the mechanisms underlying their adaptions to the various stressors present at ORR. Recently, multiple Rhodanobacter strains have been isolated from the ORR groundwater samples from several wells with varying geochemical properties. Using Illumina, PacBio, and Oxford Nanopore sequencing platforms, we obtained the whole genome sequences of eight Rhodanobacter strains. Comparison of the whole genomes demonstrated the genetic diversity, and analysis of the long nanopore reads revealed the heterogeneity of methylation patterns in strains isolated from the same well. Although all strains contained a complete set of denitrifying genes, the predicted tertiary structures of NosZ differed. The sequence comparison results demonstrate the important roles of horizontal gene transfer and negative selection in adaptation. In addition, these strains may be recalcitrant to genetic manipulation due to the complex restriction-modification systems and methylations.

Published

2022

5. Genetic Basis of Chromate Adaptation and the Role of the Pre-existing Genetic Divergence during an Experimental Evolution Study with Desulfovibrio vulgaris Populations

Author

Weiling Shi, Qiao Ma, Feiyan Pan, Yupeng Fan, Megan L. Kempher, Daliang Ning, Yuanyuan Qu, Judy D. Wall, Aifen Zhou, and Jizhong Zhou

Subjects

chromate stress, Desulfovibrio vulgaris, experimental evolution, genetic background, Microbiology, QR1-502

Abstract

ABSTRACT Hexavalent chromium [Cr(VI)] is a common environmental pollutant. However, little is known about the genetic basis of microbial evolution under Cr(VI) stress and the influence of the prior evolution histories on the subsequent evolution under Cr(VI) stress. In this study, Desulfovibrio vulgaris Hildenborough (DvH), a model sulfate-reducing bacterium, was experimentally evolved for 600 generations. By evolving the replicate populations of three genetically diverse DvH clones, including ancestor (AN, without prior experimental evolution history), non-stress-evolved EC3-10, and salt stress-evolved ES9-11, the contributions of adaptation, chance, and pre-existing genetic divergence to the evolution under Cr(VI) stress were able to be dissected. Significantly decreased lag phases under Cr(VI) stress were observed in most evolved populations, while increased Cr(VI) reduction rates were primarily observed in populations evolved from EC3-10 and ES9-11. The pre-existing genetic divergence in the starting clones showed strong influences on the changes in lag phases, growth rates, and Cr(VI) reduction rates. Additionally, the genomic mutation spectra in populations evolved from different starting clones were significantly different. A total of 14 newly mutated genes obtained mutations in at least two evolved populations, suggesting their importance in Cr(VI) adaptation. An in-frame deletion mutation of one of these genes, the chromate transporter gene DVU0426, demonstrated that it played an important role in Cr(VI) tolerance. Overall, our study identified potential key functional genes for Cr(VI) tolerance and demonstrated the important role of pre-existing genetic divergence in evolution under Cr(VI) stress conditions. IMPORTANCE Chromium is one of the most common heavy metal pollutants of soil and groundwater. The potential of Desulfovibrio vulgaris Hildenborough in heavy metal bioremediation such as Cr(VI) reduction was reported previously; however, experimental evidence of key functional genes involved in Cr(VI) resistance are largely unknown. Given the genetic divergence of microbial populations in nature, knowledge on how this divergence affects the microbial adaptation to a new environment such as Cr(VI) stress is very limited. Taking advantage of our previous study, three groups of genetically diverse D. vulgaris Hildenborough populations with or without prior experimental evolution histories were propagated under Cr(VI) stress for 600 generations. Whole-population genome resequencing of the evolved populations revealed the genomic changes underlying the improved Cr(VI) tolerance. The strong influence of the pre-existing genetic divergence in the starting clones on evolution under Cr(VI) stress conditions was demonstrated at both phenotypic and genetic levels.

Published

2021

6. Effects of Genetic and Physiological Divergence on the Evolution of a Sulfate-Reducing Bacterium under Conditions of Elevated Temperature

Author

Megan L. Kempher, Xuanyu Tao, Rong Song, Bo Wu, David A. Stahl, Judy D. Wall, Adam P. Arkin, Aifen Zhou, and Jizhong Zhou

Subjects

Desulfovibrio vulgaris, evolutionary biology, stress adaptation, temperature stress, Microbiology, QR1-502

Abstract

ABSTRACT Adaptation via natural selection is an important driver of evolution, and repeatable adaptations of replicate populations, under conditions of a constant environment, have been extensively reported. However, isolated groups of populations in nature tend to harbor both genetic and physiological divergence due to multiple selective pressures that they have encountered. How this divergence affects adaptation of these populations to a new common environment remains unclear. To determine the impact of prior genetic and physiological divergence in shaping adaptive evolution to accommodate a new common environment, an experimental evolution study with the sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough (DvH) was conducted. Two groups of replicate populations with genetic and physiological divergence, derived from a previous evolution study, were propagated in an elevated-temperature environment for 1,000 generations. Ancestor populations without prior experimental evolution were also propagated in the same environment as a control. After 1,000 generations, all the populations had increased growth rates and all but one had greater fitness in the new environment than the ancestor population. Moreover, improvements in growth rate were moderately affected by the divergence in the starting populations, while changes in fitness were not significantly affected. The mutations acquired at the gene level in each group of populations were quite different, indicating that the observed phenotypic changes were achieved by evolutionary responses that differed between the groups. Overall, our work demonstrated that the initial differences in fitness between the starting populations were eliminated by adaptation and that phenotypic convergence was achieved by acquisition of mutations in different genes. IMPORTANCE Improving our understanding of how previous adaptation influences evolution has been a long-standing goal in evolutionary biology. Natural selection tends to drive populations to find similar adaptive solutions for the same selective conditions. However, variations in historical environments can lead to both physiological and genetic divergence that can make evolution unpredictable. Here, we assessed the influence of divergence on the evolution of a model sulfate-reducing bacterium, Desulfovibrio vulgaris Hildenborough, in response to elevated temperature and found a significant effect at the genetic but not the phenotypic level. Understanding how these influences drive evolution will allow us to better predict how bacteria will adapt to various ecological constraints.

Published

2020

7. Adaptive Evolution of Sphingobium hydrophobicum C1T in Electronic Waste Contaminated River Sediment

Author

Da Song, Xingjuan Chen, Meiying Xu, Rong Hai, Aifen Zhou, Renmao Tian, Joy D. Van Nostrand, Megan L. Kempher, Jun Guo, Guoping Sun, and Jizhong Zhou

Subjects

Sphingobium, electronic waste (e-waste), xenobiotic degradation, heavy metal resistance, comparative genomics, genome plasticity, Microbiology, QR1-502

Abstract

Electronic waste (e-waste) has caused a severe worldwide pollution problem. Despite increasing isolation of degradative microorganisms from e-waste contaminated environments, the mechanisms underlying their adaptive evolution in such habitats remain unclear. Sphingomonads generally have xenobiotic-degrading ability and may play important roles in bioremediation. Sphingobium hydrophobicum C1T, characterized with superior cell surface hydrophobicity, was recently isolated from e-waste contaminated river sediment. To dissect the mechanisms driving its adaptive evolution, we evaluated its stress resistance, sequenced its genome and performed comparative genomic analysis with 19 other Sphingobium strains. Strain C1T can feed on several kinds of e-waste-derived xenobiotics, exhibits a great resistance to heavy metals and possesses a high colonization ability. It harbors abundant genes involved in environmental adaptation, some of which are intrinsic prior to experiencing e-waste contamination. The extensive genomic variations between strain C1T and other Sphingobium strains, numerous C1T-unique genes, massive mobile elements and frequent genome rearrangements reflect a high genome plasticity. Positive selection, gene duplication, and especially horizontal gene transfer drive the adaptive evolution of strain C1T. Moreover, presence of type IV secretion systems may allow strain C1T to be a source of beneficial genes for surrounding microorganisms. This study provides new insights into the adaptive evolution of sphingomonads, and potentially guides bioremediation strategies.

Published

2019

8. Key Metabolites and Mechanistic Changes for Salt Tolerance in an Experimentally Evolved Sulfate-Reducing Bacterium, Desulfovibrio vulgaris

Author

Aifen Zhou, Rebecca Lau, Richard Baran, Jincai Ma, Frederick von Netzer, Weiling Shi, Drew Gorman-Lewis, Megan L. Kempher, Zhili He, Yujia Qin, Zhou Shi, Grant M. Zane, Liyou Wu, Benjamin P. Bowen, Trent R. Northen, Kristina L. Hillesland, David A. Stahl, Judy D. Wall, Adam P. Arkin, and Jizhong Zhou

Subjects

Desulfovibrio vulgaris, PLFA, cell motility, energy efficiency, genomic mutations, organic solutes, Microbiology, QR1-502

Abstract

ABSTRACT Rapid genetic and phenotypic adaptation of the sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough to salt stress was observed during experimental evolution. In order to identify key metabolites important for salt tolerance, a clone, ES10-5, which was isolated from population ES10 and allowed to experimentally evolve under salt stress for 5,000 generations, was analyzed and compared to clone ES9-11, which was isolated from population ES9 and had evolved under the same conditions for 1,200 generations. These two clones were chosen because they represented the best-adapted clones among six independently evolved populations. ES10-5 acquired new mutations in genes potentially involved in salt tolerance, in addition to the preexisting mutations and different mutations in the same genes as in ES9-11. Most basal abundance changes of metabolites and phospholipid fatty acids (PLFAs) were lower in ES10-5 than ES9-11, but an increase of glutamate and branched PLFA i17:1ω9c under high-salinity conditions was persistent. ES9-11 had decreased cell motility compared to the ancestor; in contrast, ES10-5 showed higher cell motility under both nonstress and high-salinity conditions. Both genotypes displayed better growth energy efficiencies than the ancestor under nonstress or high-salinity conditions. Consistently, ES10-5 did not display most of the basal transcriptional changes observed in ES9-11, but it showed increased expression of genes involved in glutamate biosynthesis, cation efflux, and energy metabolism under high salinity. These results demonstrated the role of glutamate as a key osmolyte and i17:1ω9c as the major PLFA for salt tolerance in D. vulgaris. The mechanistic changes in evolved genotypes suggested that growth energy efficiency might be a key factor for selection. IMPORTANCE High salinity (e.g., elevated NaCl) is a stressor that affects many organisms. Salt tolerance, a complex trait involving multiple cellular pathways, is attractive for experimental evolutionary studies. Desulfovibrio vulgaris Hildenborough is a model sulfate-reducing bacterium (SRB) that is important in biogeochemical cycling of sulfur, carbon, and nitrogen, potentially for bio-corrosion, and for bioremediation of toxic heavy metals and radionuclides. The coexistence of SRB and high salinity in natural habitats and heavy metal-contaminated field sites laid the foundation for the study of salt adaptation of D. vulgaris Hildenborough with experimental evolution. Here, we analyzed a clone that evolved under salt stress for 5,000 generations and compared it to a clone evolved under the same condition for 1,200 generations. The results indicated the key roles of glutamate for osmoprotection and of i17:1ω9c for increasing membrane fluidity during salt adaptation. The findings provide valuable insights about the salt adaptation mechanism changes during long-term experimental evolution.

Published

2017

9. Nascent Genomic Evolution and Allopatric Speciation of Myroides profundi D25 in Its Transition from Land to Ocean

Author

Yu-Zhong Zhang, Yi Li, Bin-Bin Xie, Xiu-Lan Chen, Qiong-Qiong Yao, Xi-Ying Zhang, Megan L. Kempher, Jizhong Zhou, Aharon Oren, and Qi-Long Qin

Subjects

Microbiology, QR1-502

Abstract

ABSTRACT A large amount of bacterial biomass is transferred from land to ocean annually. Most transferred bacteria should not survive, but undoubtedly some do. It is unclear what mechanisms these bacteria use in order to survive and even thrive in a new marine environment. Myroides profundi D25T, a member of the Bacteroidetes phylum, was isolated from deep-sea sediment of the southern Okinawa Trough near the China mainland and had high genomic sequence identity to and synteny with the human opportunistic pathogen Myroides odoratimimus. Phylogenetic and physiological analyses suggested that M. profundi recently transitioned from land to the ocean. This provided an opportunity to explore how a bacterial genome evolved to survive in a novel environment. Changes in the transcriptome were evaluated when both species were cultured under low-salinity conditions and then transferred to high-salinity conditions. Comparative genomic and transcriptomic analyses showed that M. profundi altered transcription regulation in the early stages of survival. In these stages, vertically inherited genes played a key role in the survival of M. profundi. The contribution of M. profundi unique genes, some possibly acquired by horizontal gene transfer (HGT), appeared relatively small, and expression levels of unique genes were diminished under the high-salinity conditions. We postulate that HGT genes might play an important role in longer-term adaptation. These results suggested that some human pathogens might have the ability to survive in and adapt to the marine environment, which may have important implications for public health control in coastal regions. IMPORTANCE Horizontal gene transfer (HGT) is considered to be important for bacteria to adapt to a different microhabitat. However, our results showed that vertically inherited genes might play more important roles than HGT genes in the nascent adaptation to the marine environment in the bacterium Myroides profundi, which has recently been transferred from land to ocean. M. profundi unique genes had low expression levels and were less regulated under high-salinity conditions, indicating that the contribution of HGT genes to survival of this bacterium under marine high-salinity conditions was limited. In the early adaptation stages, M. profundi apparently survived and adapted mainly by regulating the expression of inherited core genes. These results may explain in part why human pathogens can easily be detected in marine environments.

Published

2016

10. Anaerobic 3-methylhopanoid production by an acidophilic photosynthetic purple bacterium

Author

Marisa H. Mayer, Mary N. Parenteau, Megan L. Kempher, Michael T. Madigan, Linda L. Jahnke, and Paula V. Welander

Published

2021

11. Functional and structural diversification of incomplete phosphotransferase system in cellulose-degrading clostridia

Author

Tao Xu, Xuanyu Tao, Hongxi He, Megan L. Kempher, Siping Zhang, Xiaochun Liu, Jun Wang, Dongyu Wang, Daliang Ning, Chongle Pan, Honghua Ge, Nannan Zhang, Yong-Xing He, and Jizhong Zhou

Subjects

Microbiology, Ecology, Evolution, Behavior and Systematics

Published

2023

12. Anaerobic 3-methylhopanoid production by an acidophilic photosynthetic purple bacterium

Author

M. N. Parenteau, Linda L. Jahnke, Michael T. Madigan, Megan L. Kempher, Paula V. Welander, and Marisa H. Mayer

Subjects

Hopanoids, Aerobic bacteria, Photosynthesis, Biochemistry, Microbiology, Anoxygenic phototrophs, Microbial ecology, RNA, Ribosomal, 16S, Botany, Genetics, Anaerobiosis, Molecular Biology, Phylogeny, Original Paper, Base Composition, biology, Phototroph, Chemistry, Rhodopila globiformis, General Medicine, Sequence Analysis, DNA, biology.organism_classification, Anoxic waters, Warm thermal springs, Acetobacteraceae, Anaerobic exercise, Bacteria

Abstract

Bacterial lipids are well-preserved in ancient rocks and certain ones have been used as indicators of specific bacterial metabolisms or environmental conditions existing at the time of rock deposition. Here we show that an anaerobic bacterium produces 3-methylhopanoids, pentacyclic lipids previously detected only in aerobic bacteria and widely used as biomarkers for methane-oxidizing bacteria. Both Rhodopila globiformis, a phototrophic purple nonsulfur bacterium isolated from an acidic warm spring in Yellowstone, and a newly isolated Rhodopila species from a geochemically similar spring in Lassen Volcanic National Park (USA), synthesized 3-methylhopanoids and a suite of related hopanoids and contained the genes encoding the necessary biosynthetic enzymes. Our results show that 3-methylhopanoids can be produced under anoxic conditions and challenges the use of 3-methylhopanoids as biomarkers of oxic conditions in ancient rocks and as prima facie evidence that methanotrophic bacteria were active when the rocks were deposited.

Published

2021

13. Response Regulator CD1688 Is a Negative Modulator of Sporulation in Clostridioides difficile

Author

Megan L. Kempher, Savannah C. Morris, Tyler M. Shadid, Smita K. Menon, Jimmy D. Ballard, and Ann H. West

Subjects

Spores, Bacterial, Bacterial Proteins, Clostridioides, Clostridioides difficile, Gene Expression Regulation, Bacterial, Molecular Biology, Microbiology

Abstract

Two-component signal transduction systems (TCSs), consisting of a sensor histidine kinase (HK) and a response regulator (RR), sense environmental stimuli and then modulate cellular responses, typically through changes in gene expression. Our previous work identified the DNA binding motif of CD1586, an RR implicated in Clostridioides difficile strain R20291 sporulation. To determine the role of this RR in the sporulation pathway in C. difficile, we generated a deletion strain of

Published

2022

14. Development of a Markerless Deletion Mutagenesis System in Nitrate-Reducing Bacterium Rhodanobacter denitrificans

Author

Xuanyu Tao, Aifen Zhou, Megan L. Kempher, Jiantao Liu, Mu Peng, Yuan Li, Jonathan P. Michael, Romy Chakraborty, Adam M. Deutschbauer, Adam P. Arkin, Jizhong Zhou, and Bose, Arpita

Subjects

Nitrates, Ecology, Bacteria, in-frame deletion, Human Genome, Rhodanobacter denitrificans, Genetics and Molecular Biology, upp, Applied Microbiology and Biotechnology, Microbiology, Mutagenesis, low-pH resistance, nitrate-reducing bacterium, Genetics, Uranium, Gammaproteobacteria, Ecosystem, Food Science, Biotechnology

Abstract

Rhodanobacter has been found as the dominant genus in aquifers contaminated with high concentrations of nitrate and uranium in Oak Ridge, TN, USA. The in situ stimulation of denitrification has been proposed as a potential method to remediate nitrate and uranium contamination. Among the Rhodanobacter species, Rhodanobacter denitrificans strains have been reported to be capable of denitrification and contain abundant metal resistance genes. However, due to the lack of a mutagenesis system in these strains, our understanding of the mechanisms underlying low-pH resistance and the ability to dominate in the contaminated environment remains limited. Here, we developed an in-frame markerless deletion system in two R. denitrificans strains. First, we optimized the growth conditions, tested antibiotic resistance, and determined appropriate transformation parameters in 10 Rhodanobacter strains. We then deleted the upp gene, which encodes uracil phosphoribosyltransferase, in R. denitrificans strains FW104-R3 and FW104-R5. The resulting strains were designated R3_Δupp and R5_Δupp and used as host strains for mutagenesis with 5-fluorouracil (5-FU) resistance as the counterselection marker to generate markerless deletion mutants. To test the developed protocol, the narG gene encoding nitrate reductase was knocked out in the R3_Δupp and R5_Δupp host strains. As expected, the narG mutants could not grow in anoxic medium with nitrate as the electron acceptor. Overall, these results show that the in-frame markerless deletion system is effective in two R. denitrificans strains, which will allow for future functional genomic studies in these strains furthering our understanding of the metabolic and resistance mechanisms present in Rhodanobacter species. IMPORTANCE Rhodanobacter denitrificans is capable of denitrification and is also resistant to toxic heavy metals and low pH. Accordingly, the presence of Rhodanobacter species at a particular environmental site is considered an indicator of nitrate and uranium contamination. These characteristics suggest its future potential application in bioremediation of nitrate or concurrent nitrate and uranium contamination in groundwater ecosystems. Due to the lack of genetic tools in this organism, the mechanisms of low-pH and heavy metal resistance in R. denitrificans strains remain elusive, which impedes its use in bioremediation strategies. Here, we developed a genome editing method in two R. denitrificans strains. This work marks a crucial step in developing Rhodanobacter as a model for studying the diverse mechanisms of low-pH and heavy metal resistance associated with denitrification.

Published

2022

15. A green sulfur bacterium from epsomitic Hot Lake, Washington, USA

Author

Michael T. Madigan, Stephen R. Lindemann, W. Matthew Sattley, James K. Fredrickson, Kelly S. Bender, Alice Dohnalkova, Deborah O. Jung, Megan L. Kempher, and Allan Konopka

Subjects

Washington, Hot Temperature, Immunology, chemistry.chemical_element, Sulfides, Applied Microbiology and Biotechnology, Microbiology, Late summer, Chlorobi, Magnesium Sulfate, 03 medical and health sciences, Nitrogen Fixation, Genetics, Molecular Biology, Phylogeny, Hot Lake, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, General Medicine, Hypersaline lake, biology.organism_classification, Sulfur, Lakes, Phototrophic Processes, chemistry, Environmental chemistry, Green sulfur bacteria, Environmental science, Seasons, Bacteria

Abstract

Hot Lake is a small heliothermal and hypersaline lake in far north–central Washington State (USA) and is limnologically unusual because MgSO4 rather than NaCl is the dominant salt. In late summer, the Hot Lake metalimnion becomes distinctly green from blooms of planktonic phototrophs. In a study undertaken over 60 years ago, these blooms were predicted to include green sulfur bacteria, but no cultures were obtained. We sampled Hot Lake and established enrichment cultures for phototrophic sulfur bacteria in MgSO4-rich sulfidic media. Most enrichments turned green or red within 2 weeks, and from green-colored enrichments, pure cultures of a lobed green sulfur bacterium (phylum Chlorobi) were isolated. Phylogenetic analyses showed the organism to be a species of the prosthecate green sulfur bacterium Prosthecochloris. Cultures of this Hot Lake phototroph were halophilic and tolerated high levels of sulfide and MgSO4. In addition, unlike all recognized species of Prosthecochloris, the Hot Lake isolates grew at temperatures up to 45 °C, indicating an adaptation to the warm summer temperatures of the lake. Photoautotrophy by Hot Lake green sulfur bacteria may contribute dissolved organic matter to anoxic zones of the lake, and their diazotrophic capacity may provide a key source of bioavailable nitrogen, as well.

Published

2021

16. Target integration of an exogenous β-glucosidase enhances cellulose degradation and ethanol production in Clostridium cellulolyticum

Author

Xuanyu Tao, Josiah S. Morgan, Jiantao Liu, Megan L. Kempher, Tao Xu, and Jizhong Zhou

Subjects

Environmental Engineering, Renewable Energy, Sustainability and the Environment, Bioengineering, General Medicine, Waste Management and Disposal

Published

2023

17. Cultivation and characterization of snowbound microorganisms from the South Pole

Author

Samantha B. Joye, Austin M. Huntington, Kathryn N. Shaffer, Michael T. Madigan, Lynn M. Stokes, W. Matthew Sattley, Emma D. Dewey, Megan L. Kempher, Janessa E. George, Mackenzie K. Hayward, Brad M. Burchell, and Brittney C. Alexander

Subjects

0303 health sciences, Bacteria, biology, 030306 microbiology, Ecology, Microorganism, fungi, Fungi, Antarctic Regions, General Medicine, Sphingomonas, biology.organism_classification, Cell morphology, Microbiology, 03 medical and health sciences, Microbial ecology, Metagenomics, Halotolerance, Molecular Medicine, Extreme environment, Energy source, human activities, Ecosystem, Phylogeny, 030304 developmental biology

Abstract

Little is known about microbial ecosystems of interior Antarctica, if indeed such ecosystems exist. Although considerable research has assessed microorganisms indigenous to coastal regions of Antarctica, particularly their lakes, ponds, and soils, to our knowledge only one characterized bacterium, a strain of Pseudomonas, has been isolated from South Pole ice or snow. Metagenomic community analyses described in this work and elsewhere reveal that a diversity of bacteria exists in inland polar snows, yet attempts to culture and characterize these microbes from this extreme environment have been few to date. In this molecular and culture-dependent investigation of the microbiology of inland Antarctica, we enriched and isolated two new strains of bacteria and one strain of yeast (Fungi) from South Pole snow samples. The bacteria were of the genera Methylobacterium and Sphingomonas, and the yeast grouped with species of Naganishia (class Tremellocytes). In addition to phylogenetic analyses, characterization of these isolates included determinations of cell morphology, growth as a function of temperature, salinity tolerance, and carbon and energy source versatility. All organisms were found to be cold-adapted, and the yeast strain additionally showed considerable halotolerance. These descriptions expand our understanding of the diversity and metabolic activities of snowbound microorganisms of interior Antarctica.

Published

2021

18. Bacterial type II toxin-antitoxin systems acting through post-translational modifications

Author

Xuanyu Tao, Si-Ping Zhang, Hu-Yuan Feng, Han-Zhong Feng, Yong Wang, Qian Wang, Megan L. Kempher, Yong-Xing He, Shuo-Wei Quan, and Shaomin Niu

Subjects

Cell, Biophysics, Review Article, Biochemistry, Persistence, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Genetics, medicine, AMPylation, Phosphorylation, Adenylylation, 030304 developmental biology, 0303 health sciences, TA system, Cell growth, Chemistry, DNA replication, Acetylation, Computer Science Applications, Cell biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, ADP-ribosylation, Antitoxin, TP248.13-248.65, Function (biology), Biotechnology

Abstract

The post-translational modification (PTM) serves as an important molecular switch mechanism to modulate diverse biological functions in response to specific cues. Though more commonly found in eukaryotic cells, many PTMs have been identified and characterized in bacteria over the past decade, highlighting the importance of PTMs in regulating bacterial physiology. Several bacterial PTM enzymes have been characterized to function as the toxin component of type II TA systems, which consist of a toxin that inhibits cell growth and an antitoxin that protects the cell from poisoning by the toxin. While TA systems can be classified into seven types based on nature of the antitoxin and its activity, type II TA systems are perhaps the most studied among the different TA types and widely distributed in eubacteria and archaea. The type II toxins possessing PTM activities typically modify various cellular targets mostly associated with protein translation and DNA replication. This review mainly focuses on the enzymatic activities, target specificities, antitoxin neutralizing mechanisms of the different families of PTM toxins. We also proposed that TA systems can be conceptually viewed as molecular switches where the ‘on’ and ‘off’ state of the system is tightly controlled by antitoxins and discussed the perspective on toxins having other physiologically roles apart from growth inhibition by acting on the nonessential cellular targets.

Published

2020

19. Cas9 Nickase-Based Genome Editing in Clostridium cellulolyticum

Author

Tao, Xu, Xuanyu, Tao, Megan L, Kempher, and Jizhong, Zhou

Subjects

Gene Editing, Clostridium cellulolyticum, Deoxyribonuclease I, CRISPR-Cas Systems, RNA, Guide, Kinetoplastida

Abstract

Clostridium cellulolyticum is a model mesophilic, cellulolytic bacterium, with the potential to produce biofuels from lignocellulose. However, the natural cellulose utilization efficiency is quite low and, therefore, metabolically engineered strains with increased efficiency can decrease both the overall cost and time required for biofuel production. Traditional genetic tools are inefficient, expensive, and time-consuming, but recent developments in the use of CRISPR-Cas genetic editing systems have greatly expanded our ability to reprogram cells. Here we describe an established protocol enabling one-step versatile genome editing in C. cellulolyticum. It integrates Cas9 nickase (Cas9n) which introduces a single nick that triggers repair via homologous recombination (SNHR) to edit genomic loci with high efficiency and accuracy. This one-step editing is achieved by transforming an all-in-one vector to coexpress Cas9n and a single guide RNA (gRNA) and carries a user-defined homologous donor template to promote SNHR at a desired target site. Additionally, this system has high specificity and allows for various types of genomic editing, including markerless insertions, deletions, substitutions, and even multiplex editing.

Published

2022

20. Correction to: Allochromatium tepidum, sp. nov., a hot spring species of purple sulfur bacteria

Author

Michael T. Madigan, Jill N. Absher, Joseph E. Mayers, Marie Asao, Deborah O. Jung, Kelly S. Bender, Megan L. Kempher, Mackenzie K. Hayward, Sophia A. Sanguedolce, Abigail C. Brown, Shinichi Takaichi, Ken Kurokawa, Atsushi Toyoda, Hiroshi Mori, Yusuke Tsukatani, Zheng-Yu Wang-Otomo, David M. Ward, and W. Matthew Sattley

Subjects

Genetics, General Medicine, Molecular Biology, Biochemistry, Microbiology

Published

2022

21. Experimental evolution reveals nitrate tolerance mechanisms in Desulfovibrio vulgaris

Author

Feiyan Pan, Judy D. Wall, Joy D. Van Nostrand, Grant M. Zane, Feifei Liu, Bo Wu, Zhili He, Daliang Ning, Longfei Shu, Shouwen Chen, Megan L. Kempher, Juan Li, Xueqin Yang, Jizhong Zhou, Philippe Juneau, Qingyun Yan, and Aifen Zhou

Subjects

Genotype, medicine.disease_cause, Nitrate reductase, Microbiology, Article, 03 medical and health sciences, chemistry.chemical_compound, Nitrate, medicine, Desulfovibrio vulgaris, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Genetics, 0303 health sciences, Mutation, Experimental evolution, Nitrates, biology, Sulfates, 030306 microbiology, Mutagenesis, biology.organism_classification, chemistry, Desulfovibrio, Nitrogen Oxides, Oxidation-Reduction, Bacteria

Abstract

Elevated nitrate in the environment inhibits sulfate reduction by important microorganisms of sulfate-reducing bacteria (SRB). Several SRB may respire nitrate to survive under elevated nitrate, but how SRB that lack nitrate reductase survive to elevated nitrate remains elusive. To understand nitrate adaptation mechanisms, we evolved 12 populations of a model SRB (i.e., Desulfovibrio vulgaris Hildenborough, DvH) under elevated NaNO(3) for 1000 generations, analyzed growth and acquired mutations, and linked their genotypes with phenotypes. Nitrate-evolved (EN) populations significantly (p

Published

2020

22. Identification of ClpP Dual Isoform Disruption as an Antisporulation Strategy for Clostridioides difficile

Author

Jimmy D. Ballard, Adam S Duerfeldt, Tyler M. Shadid, Catherine E Bishop, Megan L. Kempher, and Nathan P. Lavey

Subjects

medicine.medical_treatment, Mutant, Druggability, Virulence, Biology, Microbiology, Bortezomib, Bacterial Proteins, Genome editing, medicine, Humans, Protein Isoforms, Coding region, Molecular Biology, Gene Editing, Spores, Bacterial, Protease, Clostridioides difficile, Gene Expression Regulation, Bacterial, Phenotype, Stop codon, Mutation, Clostridium Infections, Research Article

Abstract

The Gram-positive bacterium Clostridioides difficile is a primary cause of hospital-acquired diarrhea, threatening both immunocompromised and healthy individuals. An important aspect of defining mechanisms that drive C. difficile persistence and virulence relies on developing a more complete understanding of sporulation. C. difficile sporulation is the single determinant of transmission and complicates treatment and prevention due to the chemical and physical resilience of spores. By extension, the identification of druggable targets that significantly attenuate sporulation would have a significant impact on thwarting C. difficile infection. By use of a new CRISPR-Cas9 nickase genome editing methodology, stop codons were inserted early in the coding sequence for clpP1 and clpP2 to generate C. difficile mutants that no longer produced the corresponding isoforms of caseinolytic protease P (ClpP). The data show that genetic ablation of ClpP isoforms leads to altered sporulation phenotypes with the clpP1/clpP2 double mutant exhibiting asporogenic behavior. A small screen of known ClpP inhibitors in a fluorescence-based biochemical assay identified bortezomib as an inhibitor of C. difficile ClpP that produces dose-dependent inhibition of purified ClpP. Incubation of C. difficile cultures in the presence of bortezomib reveals antisporulation effects approaching that observed in the clpP1/clpP2 double mutant. This work identifies ClpP as a key contributor to C. difficile sporulation and provides compelling support for the pursuit of small-molecule ClpP inhibitors as C. difficile antisporulating agents. IMPORTANCE Due to diverse roles of ClpP and the reliance of pathogens upon this system for infection, it has emerged as a target for antimicrobial development. Biology regulated by ClpP is organism dependent and has not been defined in Clostridioides difficile. This work identifies ClpP as a key contributor to C. difficile sporulation and provides compelling support for the pursuit of small-molecule ClpP inhibitors as antisporulating agents. The identification of new approaches and/or drug targets that reduce C. difficile sporulation would be transformative and are expected to find high utility in prophylaxis, transmission attenuation, and relapse prevention. Discovery of the ClpP system as a major driver to sporulation also provides a new avenue of inquiry for advancing the understanding of sporulation.

Published

2022

23. Cas9 Nickase-Based Genome Editing in Clostridium cellulolyticum

Author

Tao Xu, Xuanyu Tao, Megan L. Kempher, and Jizhong Zhou

Published

2022

24. Allochromatium tepidum, sp. nov., a hot spring species of purple sulfur bacteria

Author

Michael T. Madigan, Jill N. Absher, Joseph E. Mayers, Marie Asao, Deborah O. Jung, Kelly S. Bender, Megan L. Kempher, Mackenzie K. Hayward, Sophia A. Sanguedolce, Abigail C. Brown, Shinichi Takaichi, Ken Kurokawa, Atsushi Toyoda, Hiroshi Mori, Yusuke Tsukatani, Zheng-Yu Wang-Otomo, David M. Ward, and W. Matthew Sattley

Subjects

Genetics, General Medicine, Molecular Biology, Biochemistry, Microbiology

Published

2022

25. Disentangling direct from indirect relationships in association networks

Author

Naijia Xiao, Aifen Zhou, Megan L. Kempher, Benjamin Y. Zhou, Zhou Jason Shi, Mengting Yuan, Xue Guo, Linwei Wu, Daliang Ning, Joy Van Nostrand, Mary K. Firestone, and Jizhong Zhou

Subjects

Climate Action, indirect relationship, Multidisciplinary, climate change, Ecology, direct relationship, systems biology, Biological Sciences, network analysis

Abstract

Significance Networks are fundamental units for studying complex systems, but reconstructing networks from large-scale experimental data is very challenging in systems biology and microbial ecology, primarily due to the difficulty in unraveling direct and indirect interactions. By tackling several mathematical challenges, this study provides a conceptual framework for disentangling direct and indirect relationships in association networks. The application of iDIRECT (Inference of Direct and Indirect Relationships with Effective Copula-based Transitivity) to synthetic, gene expression, and microbial community data demonstrates that it is a powerful, robust, and reliable tool for network inference. The framework developed here will greatly enhance our capability to discern network interactions in various complex systems and allow scientists to address research questions that could not be approached previously., Networks are vital tools for understanding and modeling interactions in complex systems in science and engineering, and direct and indirect interactions are pervasive in all types of networks. However, quantitatively disentangling direct and indirect relationships in networks remains a formidable task. Here, we present a framework, called iDIRECT (Inference of Direct and Indirect Relationships with Effective Copula-based Transitivity), for quantitatively inferring direct dependencies in association networks. Using copula-based transitivity, iDIRECT eliminates/ameliorates several challenging mathematical problems, including ill-conditioning, self-looping, and interaction strength overflow. With simulation data as benchmark examples, iDIRECT showed high prediction accuracies. Application of iDIRECT to reconstruct gene regulatory networks in Escherichia coli also revealed considerably higher prediction power than the best-performing approaches in the DREAM5 (Dialogue on Reverse Engineering Assessment and Methods project, #5) Network Inference Challenge. In addition, applying iDIRECT to highly diverse grassland soil microbial communities in response to climate warming showed that the iDIRECT-processed networks were significantly different from the original networks, with considerably fewer nodes, links, and connectivity, but higher relative modularity. Further analysis revealed that the iDIRECT-processed network was more complex under warming than the control and more robust to both random and target species removal (P < 0.001). As a general approach, iDIRECT has great advantages for network inference, and it should be widely applicable to infer direct relationships in association networks across diverse disciplines in science and engineering.

Published

2021

26. Genetic Basis of Chromate Adaptation and the Role of the Pre-existing Genetic Divergence during an Experimental Evolution Study with Desulfovibrio vulgaris Populations

Author

Daliang Ning, Weiling Shi, Qiao Ma, Jizhong Zhou, Judy D. Wall, Feiyan Pan, Megan L. Kempher, Yupeng Fan, Aifen Zhou, and Yuanyuan Qu

Subjects

Physiology, chromate stress, Biochemistry, Microbiology, genetic background, 03 medical and health sciences, chemistry.chemical_compound, Genetics, Desulfovibrio vulgaris, experimental evolution, Hexavalent chromium, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Experimental evolution, biology, 030306 microbiology, biology.organism_classification, Phenotype, QR1-502, Computer Science Applications, Genetic divergence, chemistry, Modeling and Simulation, Adaptation, Bacteria, Research Article

Abstract

Hexavalent chromium [Cr(VI)] is a common environmental pollutant. However, little is known about the genetic basis of microbial evolution under Cr(VI) stress and the influence of the prior evolution histories on the subsequent evolution under Cr(VI) stress. In this study, Desulfovibrio vulgaris Hildenborough (DvH), a model sulfate-reducing bacterium, was experimentally evolved for 600 generations. By evolving the replicate populations of three genetically diverse DvH clones, including ancestor (AN, without prior experimental evolution history), non-stress-evolved EC3-10, and salt stress-evolved ES9-11, the contributions of adaptation, chance, and pre-existing genetic divergence to the evolution under Cr(VI) stress were able to be dissected. Significantly decreased lag phases under Cr(VI) stress were observed in most evolved populations, while increased Cr(VI) reduction rates were primarily observed in populations evolved from EC3-10 and ES9-11. The pre-existing genetic divergence in the starting clones showed strong influences on the changes in lag phases, growth rates, and Cr(VI) reduction rates. Additionally, the genomic mutation spectra in populations evolved from different starting clones were significantly different. A total of 14 newly mutated genes obtained mutations in at least two evolved populations, suggesting their importance in Cr(VI) adaptation. An in-frame deletion mutation of one of these genes, the chromate transporter gene DVU0426, demonstrated that it played an important role in Cr(VI) tolerance. Overall, our study identified potential key functional genes for Cr(VI) tolerance and demonstrated the important role of pre-existing genetic divergence in evolution under Cr(VI) stress conditions. IMPORTANCE Chromium is one of the most common heavy metal pollutants of soil and groundwater. The potential of Desulfovibrio vulgaris Hildenborough in heavy metal bioremediation such as Cr(VI) reduction was reported previously; however, experimental evidence of key functional genes involved in Cr(VI) resistance are largely unknown. Given the genetic divergence of microbial populations in nature, knowledge on how this divergence affects the microbial adaptation to a new environment such as Cr(VI) stress is very limited. Taking advantage of our previous study, three groups of genetically diverse D. vulgaris Hildenborough populations with or without prior experimental evolution histories were propagated under Cr(VI) stress for 600 generations. Whole-population genome resequencing of the evolved populations revealed the genomic changes underlying the improved Cr(VI) tolerance. The strong influence of the pre-existing genetic divergence in the starting clones on evolution under Cr(VI) stress conditions was demonstrated at both phenotypic and genetic levels.

Published

2021

27. Molecular basis for coordinating secondary metabolite production by bacterial and plant signaling molecules

Author

Nannan Zhang, Jin Wu, Siping Zhang, Maoran Yuan, Hang Xu, Jie Li, Pingping Zhang, Mingzhu Wang, Megan L. Kempher, Xuanyu Tao, Li-Qun Zhang, Honghua Ge, and Yong-Xing He

Subjects

Protein Conformation, Secondary Metabolism, Hydrogen Bonding, Gene Expression Regulation, Bacterial, Cell Biology, Phloroglucinol, Ligands, Pseudomonas fluorescens, Biochemistry, DNA-Binding Proteins, Mupirocin, Bacterial Proteins, Oligopeptides, Molecular Biology, Signal Transduction

Abstract

The production of secondary metabolites is a major mechanism used by beneficial rhizobacteria to antagonize plant pathogens. These bacteria have evolved to coordinate the production of different secondary metabolites due to the heavy metabolic burden imposed by secondary metabolism. However, for most secondary metabolites produced by bacteria, it is not known how their biosynthesis is coordinated. Here, we showed that PhlH from the rhizobacterium Pseudomonas fluorescens is a TetR-family regulator coordinating the expression of enzymes related to the biosynthesis of several secondary metabolites, including 2,4-diacetylphloroglucinol (2,4-DAPG), mupirocin, and pyoverdine. We present structures of PhlH in both its apo form and 2,4-DAPG-bound form and elucidate its ligand-recognizing and allosteric switching mechanisms. Moreover, we found that dissociation of 2,4-DAPG from the ligand-binding domain of PhlH was sufficient to allosterically trigger a pendulum-like movement of the DNA-binding domains within the PhlH dimer, leading to a closed-to-open conformational transition. Finally, molecular dynamics simulations confirmed that two distinct conformational states were stabilized by specific hydrogen bonding interactions and that disruption of these hydrogen bonds had profound effects on the conformational transition. Our findings not only reveal a well-conserved route of allosteric signal transduction in TetR-family regulators but also provide novel mechanistic insights into bacterial metabolic coregulation.

Published

2022

28. Anaerobic 3-Methylhopanoid Production By An Acidophilic Phototrophic Purple Bacterium

Author

Marisa Mayer, Mary N. Parenteau, Megan L. Kempher, Michael T. Madigan, Linda L. Jahnke, and Paula V. Welander

Abstract

Bacterial lipids are well preserved in ancient rocks and certain ones have been used as indicators of specific bacterial metabolisms or environmental conditions existing at the time of rock deposition. Here we show that an anaerobic bacterium produces 3-methylbacteriohopanepolyols (3-MeBHPs), pentacyclic lipids previously detected only in aerobic bacteria and widely used as biomarkers for methane-oxidizing bacteria. Both Rhodopila globiformis, a phototrophic purple nonsulfur bacterium isolated from an acidic warm spring in Yellowstone, and a newly isolated Rhodopila species from a geochemically similar spring in Lassen Volcanic National Park (USA), synthesized 3-MeBHPs and a suite of related BHPs and contained the genes encoding the necessary biosynthetic enzymes. Our results show that 3-MeBHPs can be produced under anoxic conditions and challenges the use of 3-MeBHPs as biomarkers of oxic conditions in ancient rocks and as prima facie evidence that methanotrophic bacteria were active when the rocks were deposited.

Published

2021

29. CRISPR

Author

Tao Xu, Megan L. Kempher, Xuanyu Tao, Aifen Zhou, and Jizhong Zhou

Published

2021

30. Loss of ClpP Function in Clostridioides difficile 630 Significantly Impacts Sporulation Systems

Author

Adam S. Duerfeldt, Jimmy D. Ballard, Bishop Ce, Tyler M. Shadid, Nathan P. Lavey, Nagib Ahsan, and Megan L. Kempher

Subjects

Genetics, Protease, Genome editing, medicine.medical_treatment, Mutant, medicine, Coding region, Virulence, Biology, Phenotype, Function (biology), Stop codon

Abstract

The Gram-positive bacterium Clostridioides difficile is a primary cause of hospital-acquired diarrhea, threatening both immunocompromised and healthy individuals. An important aspect of elucidating mechanisms that drive C. difficile persistence and virulence relies on developing a more complete understanding of sporulation. C. difficile sporulation is the single determinant of transmission and complicates treatment and prevention due to the chemical and physical resilience of spores. Hence, the identification of potentially druggable targets that significantly attenuate sporulation is important. In this report, we describe the impact of the loss of caseinolytic protease P (ClpP) isoforms in C. difficile strain 630 on sporulation phenotypes. Using CRISPR-Cas9 nickase mediated genome editing, stop codons were inserted early in the coding sequence for clpP1 and clpP2 to generate C. difficile mutants that no longer produced ClpP1 or ClpP2. The data show that these genetic modifications lead to altered sporulation phenotypes, germination efficiencies, and cytotoxicity. Comparative proteome profiling of C. difficile 630 WT and clpP mutants reveals potential proteolytic targets of ClpP that are involved in sporulation. These analyses further reveal the potential for preferred co-chaperone interactions for each ClpP isoform. Taken together, our results demonstrate that ClpP, a promising target in other Gram-positive pathogens, holds promise as an anti-sporulation target in C. difficile.

Published

2021

31. Effects of Genetic and Physiological Divergence on the Evolution of a Sulfate-Reducing Bacterium under Conditions of Elevated Temperature

Author

David A. Stahl, Judy D. Wall, Bo Wu, Adam P. Arkin, Megan L. Kempher, Jizhong Zhou, Rong Song, Xuanyu Tao, Aifen Zhou, Rosenzweig, Raphael F, and Cooper, Vaughn S

Subjects

0106 biological sciences, Physiological, Population, Biology, Bacterial Physiological Phenomena, 010603 evolutionary biology, 01 natural sciences, Microbiology, Divergence, 03 medical and health sciences, temperature stress, Virology, Genetics, Desulfovibrio vulgaris, Adaptation, education, Gene, 030304 developmental biology, 0303 health sciences, education.field_of_study, Experimental evolution, Natural selection, Sulfates, fungi, evolutionary biology, Temperature, food and beverages, Genetic Variation, Replicate, QR1-502, stress adaptation, Genetic divergence, Evolutionary biology, Mutation, Genetic Fitness, Directed Molecular Evolution, Oxidation-Reduction

Abstract

Adaptation via natural selection is an important driver of evolution, and repeatable adaptations of replicate populations, under conditions of a constant environment, have been extensively reported. However, isolated groups of populations in nature tend to harbor both genetic and physiological divergence due to multiple selective pressures that they have encountered. How this divergence affects adaptation of these populations to a new common environment remains unclear. To determine the impact of prior genetic and physiological divergence in shaping adaptive evolution to accommodate a new common environment, an experimental evolution study with the sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough (DvH) was conducted. Two groups of replicate populations with genetic and physiological divergence, derived from a previous evolution study, were propagated in an elevated-temperature environment for 1,000 generations. Ancestor populations without prior experimental evolution were also propagated in the same environment as a control. After 1,000 generations, all the populations had increased growth rates and all but one had greater fitness in the new environment than the ancestor population. Moreover, improvements in growth rate were moderately affected by the divergence in the starting populations, while changes in fitness were not significantly affected. The mutations acquired at the gene level in each group of populations were quite different, indicating that the observed phenotypic changes were achieved by evolutionary responses that differed between the groups. Overall, our work demonstrated that the initial differences in fitness between the starting populations were eliminated by adaptation and that phenotypic convergence was achieved by acquisition of mutations in different genes. IMPORTANCE Improving our understanding of how previous adaptation influences evolution has been a long-standing goal in evolutionary biology. Natural selection tends to drive populations to find similar adaptive solutions for the same selective conditions. However, variations in historical environments can lead to both physiological and genetic divergence that can make evolution unpredictable. Here, we assessed the influence of divergence on the evolution of a model sulfate-reducing bacterium, Desulfovibrio vulgaris Hildenborough, in response to elevated temperature and found a significant effect at the genetic but not the phenotypic level. Understanding how these influences drive evolution will allow us to better predict how bacteria will adapt to various ecological constraints.

Published

2020

32. EmhR is an indole-sensing transcriptional regulator responsible for the indole-induced antibiotic tolerance in Pseudomonas fluorescens

Author

Di-Yin Li, Xiang‐Xue Jia, Jian-Ting Han, Megan L. Kempher, Wen-Juan Jia, Yong-Xing He, Meng‐Yuan Zhang, Shaomin Niu, Xu Yan, Xuanyu Tao, Hang Xu, and Xiao-Quan Yu

Subjects

Indole test, Proteomics, 0303 health sciences, Rhizosphere, Indoles, Multidrug tolerance, 030306 microbiology, Operon, Pseudomonas fluorescens, Biology, Rhizobacteria, biology.organism_classification, Microbiology, Anti-Bacterial Agents, 03 medical and health sciences, Pseudomonas, Pseudomonas syringae, Efflux, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology

Abstract

Indole is well known as an interspecies signalling molecule to modulate bacterial physiology; however, it is not clear how the indole signal is perceived and responded to by plant growth promoting rhizobacteria (PGPR) in the rhizosphere. Here, we demonstrated that indole enhanced the antibiotic tolerance of Pseudomonas fluorescens 2P24, a PGPR well known for its biocontrol capacity. Proteomic analysis revealed that indole influenced the expression of multiple genes including the emhABC operon encoding a major multidrug efflux pump. The expression of emhABC was regulated by a TetR-family transcription factor EmhR, which was demonstrated to be an indole-responsive regulator. Molecular dynamics simulation showed that indole allosterically affected the distance between the two DNA-recognizing helices within the EmhR dimer, leading to diminished EmhR-DNA interaction. It was further revealed the EmhR ortholog in Pseudomonas syringae was also responsible for indole-induced antibiotic tolerance, suggesting this EmhR-dependent, indole-induced antibiotic tolerance is likely to be conserved among Pseudomonas species. Taken together, our results elucidated the molecular mechanism of indole-induced antibiotic tolerance in Pseudomonas species and had important implications on how rhizobacteria sense and respond to indole in the rhizosphere.

Published

2020

33. Precise promoter integration improves cellulose bioconversion and thermotolerance in Clostridium cellulolyticum

Author

Jizhong Zhou, Tao Xu, Megan L. Kempher, Xuanyu Tao, and Jiantao Liu

Subjects

0106 biological sciences, DNA, Bacterial, Thermotolerance, Bioconversion, Mutant, Bioengineering, Cellulosomes, Clostridium cellulolyticum, 01 natural sciences, Applied Microbiology and Biotechnology, Cellulosome, 03 medical and health sciences, chemistry.chemical_compound, 010608 biotechnology, Gene cluster, Biomass, Lactic Acid, Cellulose, Promoter Regions, Genetic, 030304 developmental biology, 0303 health sciences, biology, Strain (chemistry), Ethanol, Chemistry, biology.organism_classification, Microarray Analysis, Biochemistry, Multigene Family, Fermentation, DNA Transposable Elements, CRISPR-Cas Systems, Biotechnology, Plasmids

Abstract

Lignocellulose has been used for production of sustainable biofuels and value-added chemicals. However, the low-efficiency bioconversion of lignocellulose greatly contributes to a high production cost. Here, we employed CRISPR-Cas9 editing to improve cellulose degradation efficiency by editing a regulatory element of the cip-cel gene cluster in Clostridium cellulolyticum. Insertion of a synthetic promoter (P4) and an endogenous promoter (P2) in the mspI-deficient parental strain (Δ2866) created chromosomal integrants, P4-2866 and P2-2866, respectively. Both engineered strains increased the transcript abundance of downstream polycistronic genes and enhanced in vitro cellulolytic activities of isolated cellulosomes. A high cellulose load of 20 g/L suppressed cellulose degradation in the parental strain in the first 150 h fermentation; whereas P4-2866 and P2-2866 hydrolyzed 29% and 53% of the cellulose, respectively. Both engineered strains also demonstrated a greater growth rate and a higher cell biomass yield. Interestingly, the Δ2866 parental strain demonstrated better thermotolerance than the wildtype strain, and promoter insertion further enhanced thermotolerance. Similar improvements in cell growth and cellulose degradation were reproduced by promoter insertion in the wildtype strain and a lactate production-defective mutant (LM). P2 insertion in LM increased ethanol titer by 65%. Together, the editing of regulatory elements of catabolic gene clusters provides new perspectives on improving cellulose bioconversion in microbes.

Published

2020

34. Characterization of a cold-active bacterium isolated from the South Pole 'Ice Tunnel'

Author

Alice Dohnalkova, Kelly S. Bender, Paul Sullivan, Megan L. Kempher, Samantha B. Joye, Michael T. Madigan, and W. Matthew Sattley

Subjects

0301 basic medicine, Exopolymer, 030106 microbiology, Antarctic Regions, Wastewater, Microbiology, Extreme Cold Weather, Actinobacteria, Clostridia, 03 medical and health sciences, Pseudomonas, RNA, Ribosomal, 16S, Proteobacteria, Botany, Clostridium, biology, Strain (chemistry), Microbiota, Polysaccharides, Bacterial, General Medicine, biology.organism_classification, 16S ribosomal RNA, Fatty Acids, Unsaturated, Molecular Medicine, Bacteria

Abstract

Extremely cold microbial habitats on Earth (those below -30 °C) are rare and have not been surveyed for microbes as extensively as environments in the 0 to -20 °C range. Using cryoprotected growth media incubated at -5 °C, we enriched a cold-active Pseudomonas species from -50 °C ice collected from a utility tunnel for wastewater pipes under Amundsen-Scott South Pole Station, Antarctica. The isolate, strain UC-1, is related to other cold-active Pseudomonas species, most notably P. psychrophila, and grew at -5 °C to +34-37 °C; growth of UC-1 at +3 °C was significantly faster than at +34 °C. Strain UC-1 synthesized a surface exopolymer and high levels of unsaturated fatty acids under cold growth conditions. A 16S rRNA gene diversity screen of the ice sample that yielded strain UC-1 revealed over 1200 operational taxonomic units (OTUs) distributed across eight major classes of Bacteria. Many of the OTUs were Clostridia and Bacteriodia and some of these were probably of wastewater origin. However, a significant fraction of the OTUs were Proteobacteria and Actinobacteria of likely environmental origin. Our results shed light on the lower temperature limits to life and the possible existence of functional microbial communities in ultra-cold environments.

Published

2017

35. Complete Genome Sequence of Desulfovibrio desulfuricans IC1, a Sulfonate-Respiring Anaerobe

Author

Megan L. Kempher, Leslie A. Day, Kara B. De León, Jizhong Zhou, Judy D. Wall, and Thrash, J Cameron

Subjects

Whole genome sequencing, biology, Chemistry, Circular bacterial chromosome, Human Genome, Genome Sequences, Desulfovibrio desulfuricans, biology.organism_classification, Genome, chemistry.chemical_compound, Sulfonate, Immunology and Microbiology (miscellaneous), Biochemistry, Genetics, Molecular Biology, Gene, Bacteria

Abstract

We report the complete genome sequence of the anaerobic, sulfonate-respiring, sulfate-reducing bacterium Desulfovibrio desulfuricans IC1. The genome was assembled into a single 3.25-Mb circular chromosome with 2,680 protein-coding genes identified. Sequencing of sulfonate-metabolizing anaerobes is key for understanding sulfonate degradation and its role in the sulfur cycle.

Published

2019

36. Blastochloris tepida, sp. nov., a thermophilic species of the bacteriochlorophyll b-containing genus Blastochloris

Author

Hiroshi Mori, Zheng-Yu Wang-Otomo, Sol M. Resnick, Alice Dohnalkova, Megan L. Kempher, Yusuke Tsukatani, Michael T. Madigan, Atsushi Toyoda, Shinichi Takaichi, and Ken Kurokawa

Subjects

DNA, Bacterial, food.ingredient, Biology, Biochemistry, Microbiology, Hot Springs, 03 medical and health sciences, chemistry.chemical_compound, food, Species Specificity, RNA, Ribosomal, 16S, Genetics, Microbial mat, Molecular Biology, Bacteriochlorophylls, Phylogeny, 030304 developmental biology, 0303 health sciences, Hyphomicrobiaceae, Strain (chemistry), 030306 microbiology, Thermophile, Blastochloris, General Medicine, Rhodopseudomonas, 16S ribosomal RNA, biology.organism_classification, Classification, chemistry, Bacteriochlorophyll, Bacteria

Abstract

A new taxon is created for the thermophilic purple nonsulfur bacterium previously designated as Rhodopseudomonas strain GI. Strain GI was isolated from a New Mexico (USA) hot spring microbial mat and grows optimally above 40 °C and to a maximum of 47 °C. Strain GI is a bacteriochlorophyll b-containing species of purple nonsulfur bacteria and displays a budding morphology, typical of species of the genus Blastochloris. Although resembling the species Blc. viridis in many respects, the absorption spectrum, carotenoid content, and lipid fatty acid profile of strain GI is distinct from that of Blc. viridis strain DSM133T and other recognized Blastochloris species. Strain GI forms its own subclade within the Blastochloris clade of purple nonsulfur bacteria based on comparative 16S rRNA gene sequences, and its genome is significantly larger than that of strain DSM133T; average nucleotide identity between the genomes of Blc. viridis and strain GI was below 85%. Moreover, concatenated sequence analyses of PufLM and DnaK clearly showed strain GI to be distinct from both Blc. viridis and Blc. sulfoviridis. Because of its unique assortment of properties, it is proposed to classify strain GI as a new species of the genus Blastochloris, as Blc. tepida, sp.n., with strain GIT designated as the type strain (= ATCC TSD-138 = DSM 106918).

Published

2019

37. Adaptive Evolution of Sphingobium hydrophobicum C1T in Electronic Waste Contaminated River Sediment

Author

Meiying Xu, Rong Hai, Da Song, Megan L. Kempher, Jizhong Zhou, Joy D. Van Nostrand, Guoping Sun, Renmao Tian, Jun Guo, Aifen Zhou, and Xingjuan Chen

Subjects

Microbiology (medical), Environmental Science and Management, lcsh:QR1-502, comparative genomics, heavy metal resistance, Biology, Genome, genome plasticity, Microbiology, Sphingobium, electronic waste (e-waste), lcsh:Microbiology, electronic waste, 03 medical and health sciences, Bioremediation, Gene duplication, Genetics, Gene, Original Research, 030304 developmental biology, Comparative genomics, 0303 health sciences, adaptive evolution, 030306 microbiology, Human Genome, biology.organism_classification, Horizontal gene transfer, Soil Sciences, Mobile genetic elements, xenobiotic degradation, Biotechnology

Abstract

Electronic waste (e-waste) has caused a severe worldwide pollution problem. Despite increasing isolation of degradative microorganisms from e-waste contaminated environments, the mechanisms underlying their adaptive evolution in such habitats remain unclear. Sphingomonads generally have xenobiotic-degrading ability and may play important roles in bioremediation. Sphingobium hydrophobicum C1T, characterized with superior cell surface hydrophobicity, was recently isolated from e-waste contaminated river sediment. To dissect the mechanisms driving its adaptive evolution, we evaluated its stress resistance, sequenced its genome and performed comparative genomic analysis with 19 other Sphingobium strains. Strain C1T can feed on several kinds of e-waste-derived xenobiotics, exhibits a great resistance to heavy metals and possesses a high colonization ability. It harbors abundant genes involved in environmental adaptation, some of which are intrinsic prior to experiencing e-waste contamination. The extensive genomic variations between strain C1T and other Sphingobium strains, numerous C1T-unique genes, massive mobile elements and frequent genome rearrangements reflect a high genome plasticity. Positive selection, gene duplication, and especially horizontal gene transfer drive the adaptive evolution of strain C1T. Moreover, presence of type IV secretion systems may allow strain C1T to be a source of beneficial genes for surrounding microorganisms. This study provides new insights into the adaptive evolution of sphingomonads, and potentially guides bioremediation strategies.

Published

2019

38. Environmental filtering decreases with fish development for the assembly of gut microbiota

Author

Lanjie Liao, Chun Wang, Megan L. Kempher, Jianjun Wang, Jizhong Zhou, Xinghao Li, Zhili He, Jiajia Ni, Joy D. Van Nostrand, Yaping Wang, Liyou Wu, Shu Wu, Jinjin Li, Yuhe Yu, and Qingyun Yan

Subjects

0301 basic medicine, biology, Phylogenetic tree, Ecology, Host (biology), Gut flora, biology.organism_classification, digestive system, Microbiology, 03 medical and health sciences, Phylogenetic diversity, 030104 developmental biology, Taxon, Phylogenetics, Freshwater fish, Ecosystem, Ecology, Evolution, Behavior and Systematics

Abstract

Gut microbiota typically occupy habitats with definable limits/borders that are comparable to oceanic islands. The gut therefore can be regarded as an 'island' for the assembly of microbial communities within the 'sea' of surrounding environments. This study aims to reveal the ecological mechanisms that govern microbiota in the fish gut 'island' ecosystem. Taxonomic compositions, phylogenetic diversity, and community turnover across host development were analyzed via the high-throughput sequencing of 16S rRNA gene amplicons. The results indicate that the Shannon diversity of gut microbiota in the three examined freshwater fish species all significantly decreased with host development, and the dominant bacterial taxa also changed significantly during host development. Null model and phylogenetic-based mean nearest taxon distance (MNTD) analyses suggest that host gut environmental filtering led to the assembly of microbial communities in the fish gut 'island'. However, the phylogenetic clustering of local communities and deterministic processes that governed community turnover became less distinct as the fish developed. The observed mechanisms that shaped fish gut microbiota seemed to be mainly shaped by the gut environment and by some other selective changes accompanying the host development process. These findings greatly enhance our understanding of stage-specific community assembly patterns in the fish gut ecosystem.

Published

2016

39. The antitoxin MqsA homologue in Pseudomonas fluorescens 2P24 has a rewired regulatory circuit through evolution

Author

Li-Qun Zhang, Ding-Ding Guo, Yi Wu, Si-Ping Zhang, Megan L. Kempher, Meng‐Yuan Zhang, Yong Wang, Xuanyu Tao, Yong-Xing He, and Jian-Ting Han

Subjects

Operon, Regulator, Pseudomonas fluorescens, Microbiology, Evolution, Molecular, 03 medical and health sciences, Bacterial Proteins, Transcriptional regulation, Escherichia coli, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, Escherichia coli Proteins, Biofilm, Chemotaxis, Gene Expression Regulation, Bacterial, biology.organism_classification, Cell biology, DNA-Binding Proteins, Antitoxins, rpoS

Abstract

The mqsRA operon encodes a toxin-antitoxin pair that was characterized to participate in biofilm and persister cell formation in Escherichia coli. Notably, the antitoxin MqsA possesses a C-terminal DNA-binding domain that recognizes the [5'-AACCT(N)2-4 AGGTT-3'] motif and acts as a transcriptional regulator controlling multiple genes including the general stress response regulator RpoS. However, it is unknown how the transcriptional circuits of MqsA homologues have changed in bacteria over evolutionary time. Here, we found mqsA in Pseudomonas fluorescens (PfmqsA) is acquired through horizontal gene transfer and binds to a slightly different motif [5'-TACCCT(N)3 AGGGTA-3'], which exists upstream of the PfmqsRA operon. Interestingly, an adjacent GntR-type transcriptional regulator, which was termed AgtR, is under negative control of PfMqsA. It was further demonstrated that PfMqsA reduces production of biofilm components through AgtR, which directly regulates the pga and fap operons involved in the synthesis of extracellular polymeric substances. Moreover, through quantitative proteomics analysis, we showed AgtR is a highly pleiotropic regulator that influences up to 252 genes related to diverse processes including chemotaxis, oxidative phosphorylation and carbon and nitrogen metabolism. Taken together, our findings suggest the rewired regulatory circuit of PfMqsA influences diverse physiological aspects of P. fluorescens 2P24 via the newly characterized AgtR.

Published

2018

40. Key Metabolites and Mechanistic Changes for Salt Tolerance in an Experimentally Evolved Sulfate-Reducing Bacterium, Desulfovibrio vulgaris

Author

Drew Gorman-Lewis, Zhou Shi, Weiling Shi, Zhili He, Frederick von Netzer, Aifen Zhou, Benjamin P. Bowen, Jincai Ma, David A. Stahl, Adam P. Arkin, Judy D. Wall, Jizhong Zhou, Yujia Qin, Liyou Wu, Richard Baran, Grant M. Zane, Kristina L. Hillesland, Trent R. Northen, Rebecca Lau, Megan L. Kempher, and Dubilier, Nicole

Subjects

0301 basic medicine, Genotype, Population, DNA Mutational Analysis, Clone (cell biology), Adaptation, Biological, Biology, cell motility, Microbiology, 03 medical and health sciences, Biological Factors, transcriptomics, Affordable and Clean Energy, Osmotic Pressure, Virology, Botany, Genetics, Metabolomics, Desulfovibrio vulgaris, Adaptation, education, energy efficiency, Experimental evolution, education.field_of_study, organic solutes, Sulfates, Gene Expression Profiling, Salt Tolerance, biology.organism_classification, Biological, genomic mutations, Biological Evolution, QR1-502, Salinity, 030104 developmental biology, Biochemistry, Osmolyte, PLFA, Oxidation-Reduction, Bacteria, Research Article

Abstract

Rapid genetic and phenotypic adaptation of the sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough to salt stress was observed during experimental evolution. In order to identify key metabolites important for salt tolerance, a clone, ES10-5, which was isolated from population ES10 and allowed to experimentally evolve under salt stress for 5,000 generations, was analyzed and compared to clone ES9-11, which was isolated from population ES9 and had evolved under the same conditions for 1,200 generations. These two clones were chosen because they represented the best-adapted clones among six independently evolved populations. ES10-5 acquired new mutations in genes potentially involved in salt tolerance, in addition to the preexisting mutations and different mutations in the same genes as in ES9-11. Most basal abundance changes of metabolites and phospholipid fatty acids (PLFAs) were lower in ES10-5 than ES9-11, but an increase of glutamate and branched PLFA i17:1ω9c under high-salinity conditions was persistent. ES9-11 had decreased cell motility compared to the ancestor; in contrast, ES10-5 showed higher cell motility under both nonstress and high-salinity conditions. Both genotypes displayed better growth energy efficiencies than the ancestor under nonstress or high-salinity conditions. Consistently, ES10-5 did not display most of the basal transcriptional changes observed in ES9-11, but it showed increased expression of genes involved in glutamate biosynthesis, cation efflux, and energy metabolism under high salinity. These results demonstrated the role of glutamate as a key osmolyte and i17:1ω9c as the major PLFA for salt tolerance in D. vulgaris. The mechanistic changes in evolved genotypes suggested that growth energy efficiency might be a key factor for selection., IMPORTANCE High salinity (e.g., elevated NaCl) is a stressor that affects many organisms. Salt tolerance, a complex trait involving multiple cellular pathways, is attractive for experimental evolutionary studies. Desulfovibrio vulgaris Hildenborough is a model sulfate-reducing bacterium (SRB) that is important in biogeochemical cycling of sulfur, carbon, and nitrogen, potentially for bio-corrosion, and for bioremediation of toxic heavy metals and radionuclides. The coexistence of SRB and high salinity in natural habitats and heavy metal-contaminated field sites laid the foundation for the study of salt adaptation of D. vulgaris Hildenborough with experimental evolution. Here, we analyzed a clone that evolved under salt stress for 5,000 generations and compared it to a clone evolved under the same condition for 1,200 generations. The results indicated the key roles of glutamate for osmoprotection and of i17:1ω9c for increasing membrane fluidity during salt adaptation. The findings provide valuable insights about the salt adaptation mechanism changes during long-term experimental evolution.

Published

2017

41. A Halophilic Bacterium Inhabiting the Warm, CaCl 2 -Rich Brine of the Perennially Ice-Covered Lake Vanda, McMurdo Dry Valleys, Antarctica

Author

Samantha B. Joye, Vladimir A. Samarkin, Deborah O. Jung, George S. Tregoning, Megan L. Kempher, and Michael T. Madigan

Subjects

DNA, Bacterial, Salinity, Molecular Sequence Data, Antarctic Regions, Chemocline, DNA, Ribosomal, Applied Microbiology and Biotechnology, Bottom water, RNA, Ribosomal, 16S, Gammaproteobacteria, Botany, Environmental Microbiology, Cluster Analysis, Phylogeny, Halomonas, Ecology, biology, Temperature, Sequence Analysis, DNA, Hydrogen-Ion Concentration, Vanda, biology.organism_classification, Aerobiosis, Halophile, Lakes, Brine, Salts, Food Science, Biotechnology

Abstract

Lake Vanda is a perennially ice-covered and stratified lake in the McMurdo Dry Valleys, Antarctica. The lake develops a distinct chemocline at about a 50-m depth, where the waters transition from cool, oxic, and fresh to warm, sulfidic, and hypersaline. The bottom water brine is unique, as the highly chaotropic salts CaCl 2 and MgCl 2 predominate, and CaCl 2 levels are the highest of those in any known microbial habitat. Enrichment techniques were used to isolate 15 strains of heterotrophic bacteria from the Lake Vanda brine. Despite direct supplementation of the brine samples with different organic substrates in primary enrichments, the same organism, a relative of the halophilic bacterium Halomonas ( Gammaproteobacteria ), was isolated from all depths sampled. The Lake Vanda (VAN) strains were obligate aerobes and showed broad pH, salinity, and temperature ranges for growth, consistent with the physicochemical properties of the brine. VAN strains were halophilic and quite CaCl 2 tolerant but did not require CaCl 2 for growth. The fact that only VAN strain-like organisms appeared in our enrichments hints that the highly chaotropic nature of the Lake Vanda brine may place unusual physiological constraints on the bacterial community that inhabits it.

Published

2015

42. Environmental filtering decreases with fish development for the assembly of gut microbiota

Author

Qingyun, Yan, Jinjin, Li, Yuhe, Yu, Jianjun, Wang, Zhili, He, Joy D, Van Nostrand, Megan L, Kempher, Liyou, Wu, Yaping, Wang, Lanjie, Liao, Xinghao, Li, Shu, Wu, Jiajia, Ni, Chun, Wang, and Jizhong, Zhou

Subjects

RNA, Ribosomal, 16S, Fishes, Animals, Fresh Water, Ecosystem, Phylogeny, Gastrointestinal Microbiome

Abstract

Gut microbiota typically occupy habitats with definable limits/borders that are comparable to oceanic islands. The gut therefore can be regarded as an 'island' for the assembly of microbial communities within the 'sea' of surrounding environments. This study aims to reveal the ecological mechanisms that govern microbiota in the fish gut 'island' ecosystem. Taxonomic compositions, phylogenetic diversity, and community turnover across host development were analyzed via the high-throughput sequencing of 16S rRNA gene amplicons. The results indicate that the Shannon diversity of gut microbiota in the three examined freshwater fish species all significantly decreased with host development, and the dominant bacterial taxa also changed significantly during host development. Null model and phylogenetic-based mean nearest taxon distance (MNTD) analyses suggest that host gut environmental filtering led to the assembly of microbial communities in the fish gut 'island'. However, the phylogenetic clustering of local communities and deterministic processes that governed community turnover became less distinct as the fish developed. The observed mechanisms that shaped fish gut microbiota seemed to be mainly shaped by the gut environment and by some other selective changes accompanying the host development process. These findings greatly enhance our understanding of stage-specific community assembly patterns in the fish gut ecosystem.

Published

2016

43. Nascent Genomic Evolution and Allopatric Speciation of Myroides profundi D25 in Its Transition from Land to Ocean

Author

Jizhong Zhou, Bin-Bin Xie, Megan L. Kempher, Qi-Long Qin, Xi-Ying Zhang, Yu-Zhong Zhang, Xiu-Lan Chen, Qiong-Qiong Yao, Yi Li, Aharon Oren, and Giovannoni, Stephen J

Subjects

0301 basic medicine, Geologic Sediments, China, Salinity, Gene Transfer, Horizontal, Genetic Speciation, Molecular Sequence Data, Gene Transfer, Bacterial genome size, medicine.disease_cause, Microbiology, Genome, Horizontal, 03 medical and health sciences, Phylogenetics, Virology, Genetics, medicine, Life Below Water, Gene, Phylogeny, biology, Bacteroidetes, Ecology, Gene Expression Profiling, Human Genome, Bacterial, Sequence Analysis, DNA, DNA, biology.organism_classification, QR1-502, Culture Media, 030104 developmental biology, Evolutionary biology, Horizontal gene transfer, Adaptation, Infection, Sequence Analysis, Genome, Bacterial, Myroides odoratimimus, Research Article, Biotechnology

Abstract

A large amount of bacterial biomass is transferred from land to ocean annually. Most transferred bacteria should not survive, but undoubtedly some do. It is unclear what mechanisms these bacteria use in order to survive and even thrive in a new marine environment. Myroides profundi D25T, a member of the Bacteroidetes phylum, was isolated from deep-sea sediment of the southern Okinawa Trough near the China mainland and had high genomic sequence identity to and synteny with the human opportunistic pathogen Myroides odoratimimus. Phylogenetic and physiological analyses suggested that M. profundi recently transitioned from land to the ocean. This provided an opportunity to explore how a bacterial genome evolved to survive in a novel environment. Changes in the transcriptome were evaluated when both species were cultured under low-salinity conditions and then transferred to high-salinity conditions. Comparative genomic and transcriptomic analyses showed that M. profundi altered transcription regulation in the early stages of survival. In these stages, vertically inherited genes played a key role in the survival of M. profundi. The contribution of M. profundi unique genes, some possibly acquired by horizontal gene transfer (HGT), appeared relatively small, and expression levels of unique genes were diminished under the high-salinity conditions. We postulate that HGT genes might play an important role in longer-term adaptation. These results suggested that some human pathogens might have the ability to survive in and adapt to the marine environment, which may have important implications for public health control in coastal regions., IMPORTANCE Horizontal gene transfer (HGT) is considered to be important for bacteria to adapt to a different microhabitat. However, our results showed that vertically inherited genes might play more important roles than HGT genes in the nascent adaptation to the marine environment in the bacterium Myroides profundi, which has recently been transferred from land to ocean. M. profundi unique genes had low expression levels and were less regulated under high-salinity conditions, indicating that the contribution of HGT genes to survival of this bacterium under marine high-salinity conditions was limited. In the early adaptation stages, M. profundi apparently survived and adapted mainly by regulating the expression of inherited core genes. These results may explain in part why human pathogens can easily be detected in marine environments.

Published

2016

44. Differential regulation of the two ferrochelatase paralogues in Shewanella loihica PV-4 in response to environmental stresses

Author

Weixing An, Ming Xie, Baohua Gu, Chunyuan Tian, Dongru Qiu, Aifen Zhou, Zhili He, Jizhong Zhou, Jingcheng Dai, Megan L. Kempher, Hehong Wei, and Schottel, JL

Subjects

Enzymologic, 0301 basic medicine, Shewanella, Physiological, 1.1 Normal biological development and functioning, Iron, 030106 microbiology, Mutant, Protoporphyrins, Sigma Factor, Oxidative phosphorylation, Heme, Stress, Microbiology, Applied Microbiology and Biotechnology, Gene Expression Regulation, Enzymologic, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Underpinning research, Sigma factor, Stress, Physiological, Genetics, Transcriptional regulation, Environmental Microbiology, Regulation of gene expression, Ecology, biology, Protoporphyrin IX, Bacterial, Gene Expression Regulation, Bacterial, Ferrochelatase, 030104 developmental biology, Gene Expression Regulation, chemistry, Biochemistry, biology.protein, Food Science, Biotechnology

Abstract

Determining the function and regulation of paralogues is important in understanding microbial functional genomics and environmental adaptation. Heme homeostasis is crucial for the survival of environmental microorganisms. Most Shewanella species encode two paralogues of ferrochelatase, the terminal enzyme in the heme biosynthesis pathway. The function and transcriptional regulation of two ferrochelatase genes, hemH1 and hemH2 , were investigated in Shewanella loihica PV-4. The disruption of hemH1 but not hemH2 resulted in a significant accumulation of extracellular protoporphyrin IX (PPIX), the precursor to heme, and decreased intracellular heme levels. hemH1 was constitutively expressed, and the expression of hemH2 increased when hemH1 was disrupted. The transcription of hemH1 was regulated by the housekeeping sigma factor RpoD and potentially regulated by OxyR, while hemH2 appeared to be regulated by the oxidative stress-associated sigma factor RpoE2. When an oxidative stress condition was mimicked by adding H 2 O 2 to the medium or exposing the culture to light, PPIX accumulation was suppressed in the Δ hemH1 mutant. Consistently, transcriptome analysis indicated enhanced iron uptake and suppressed heme synthesis in the Δ hemH1 mutant. These data indicate that the two paralogues are functional in the heme synthesis pathway but regulated by environmental conditions, providing insights into the understanding of bacterial response to environmental stresses and a great potential to commercially produce porphyrin compounds. IMPORTANCE Shewanella is capable of utilizing a variety of electron acceptors for anaerobic respiration because of the existence of multiple c -type cytochromes in which heme is an essential component. The cytochrome-mediated electron transfer across cellular membranes could potentially be used for biotechnological purposes, such as electricity generation in microbial fuel cells and dye decolorization. However, the mechanism underlying the regulation of biosynthesis of heme and cytochromes is poorly understood. Our study has demonstrated that two ferrochelatase genes involved in heme biosynthesis are differentially regulated in response to environmental stresses, including light and reactive oxygen species. This is an excellent example showing how bacteria have evolved to maintain cellular heme homeostasis. More interestingly, the high yields of extracellular protoporphyrin IX by the Shewanella loihica PV-4 mutants could be utilized for commercial production of this valuable chemical via bacterial fermentation.

Published

2016

45. Phylogeny and photoheterotrophy in the acidophilic phototrophic purple bacterium Rhodoblastus acidophilus

Author

Michael T. Madigan and Megan L. Kempher

Subjects

Canada, food.ingredient, Molecular Sequence Data, Biochemistry, Microbiology, Photoheterotroph, Purple bacteria, Species description, food, Species Specificity, Microbial ecology, Phylogenetics, RNA, Ribosomal, 16S, Botany, Genetics, Molecular Biology, Phylogeny, Phototroph, biology, Pigments, Biological, General Medicine, Hydrogen-Ion Concentration, Rhodopseudomonas, biology.organism_classification, Bradyrhizobiaceae, Carbon, Phototrophic Processes, Alcohols, Wetlands, Bacteria

Abstract

Norbert Pfennig isolated the first acidophilic purple bacterium over 40 years ago and named the organism Rhodopseudomonas acidophila (now Rhodoblastusacidophilus). Since the original work of Pfennig, no systematic study has been conducted on the phylogeny and carbon nutrition of a collection of strains of Rbl. acidophilus. We have isolated six new strains of Rbl. acidophilus from a Canadian peat bog. These strains, three of the original Pfennig strains and two additional putative R. acidophilus strains isolated several years ago in this laboratory,were characterized as to their pigments, phylogeny, and carbon sources supporting photoheterotrophic growth. Phototrophic cultures were either purple or orange in color,and the color of a particular strain was linked to phylogeny. As for the Pfennig strains of Rbl. acidophilus, all new strains grew photoheterotrophically at pH 5 on a variety of organic and fatty acids. However, in addition to methanol and ethanol, the new strains as well as the Pfennig strains grew on several other primary alcohols, results not reported in the original species description. Our work shows that some phylogenetic and physiological diversity exists within the species Rbl. acidophilus and supports the observation that few species of acidophilic purple bacteria appear to exist in nature.

Published

2012