Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis
Vibrio vulnificus is an opportunistic human pathogen and autochthonous inhabitant of coastal marine environments, where the bacterium is under constant predation by heterotrophic protists or protozoans. As a result of this selection pressure, genetic variants with antipredation mechanisms are select...
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Science::Biological sciences Protozoan Predation Grazing Resistance |
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Science::Biological sciences Protozoan Predation Grazing Resistance Rasheedkhan Regina, Viduthalai Noorian, Parisa Sim, Clarence Bo Wen Constancias, Florentin Kaliyamoorthy, Eganathan Booth, Sean C. Espinoza-Vergara, Gustavo Rice, Scott A. McDougald, Diane Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis |
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Vibrio vulnificus is an opportunistic human pathogen and autochthonous inhabitant of coastal marine environments, where the bacterium is under constant predation by heterotrophic protists or protozoans. As a result of this selection pressure, genetic variants with antipredation mechanisms are selected for and persist in the environment. Such natural variants may also be pathogenic to animal or human hosts, making it important to understand these defense mechanisms. To identify antipredator strategies, 13 V. vulnificus strains of different genotypes isolated from diverse environments were exposed to predation by the ciliated protozoan Tetrahymena pyriformis, and only strain ENV1 was resistant to predation. Further investigation of the cell-free supernatant showed that ENV1 acidifies the environment by the excretion of organic acids, which are toxic to T. pyriformis. As this predation resistance was dependent on the availability of iron, transcriptomes of V. vulnificus in iron-replete and iron-deplete conditions were compared. This analysis revealed that ENV1 ferments pyruvate and the resultant acetyl-CoA leads to acetate synthesis under aerobic conditions, a hallmark of overflow metabolism. The anaerobic respiration global regulator arcA was upregulated when iron was available. An ΔarcA deletion mutant of ENV1 accumulated less acetate and, importantly, was sensitive to grazing by T. pyriformis. Based on the transcriptome response and quantification of metabolites, we conclude that ENV1 has adapted to overflow metabolism and has lost a control switch that shifts metabolism from acetate excretion to acetate assimilation, enabling it to excrete acetate continuously. We show that overflow metabolism and the acetate switch contribute to prey-predator interactions. IMPORTANCE Bacteria in the environment, including Vibrio spp., interact with protozoan predators. To defend against predation, bacteria evolve antipredator mechanisms ranging from changing morphology, biofilm formation, and secretion of toxins or virulence factors. Some of these adaptations may result in strains that are pathogenic to humans. Therefore, it is important to study predator defense strategies of environmental bacteria. V. vulnificus thrives in coastal waters and infects humans. Very little is known about the defense mechanisms V. vulnificus expresses against predation. Here, we show that a V. vulnificus strain (ENV1) has rewired the central carbon metabolism, enabling the production of excess organic acid that is toxic to the protozoan predator T. pyriformis. This is a previously unknown mechanism of predation defense that protects against protozoan predators. |
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School of Biological Sciences |
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School of Biological Sciences Rasheedkhan Regina, Viduthalai Noorian, Parisa Sim, Clarence Bo Wen Constancias, Florentin Kaliyamoorthy, Eganathan Booth, Sean C. Espinoza-Vergara, Gustavo Rice, Scott A. McDougald, Diane |
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Article |
| author |
Rasheedkhan Regina, Viduthalai Noorian, Parisa Sim, Clarence Bo Wen Constancias, Florentin Kaliyamoorthy, Eganathan Booth, Sean C. Espinoza-Vergara, Gustavo Rice, Scott A. McDougald, Diane |
| author_sort |
Rasheedkhan Regina, Viduthalai |
| title |
Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis |
| title_short |
Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis |
| title_full |
Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis |
| title_fullStr |
Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis |
| title_full_unstemmed |
Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis |
| title_sort |
loss of the acetate switch in vibrio vulnificus enhances predation defense against tetrahymena pyriformis |
| publishDate |
2022 |
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https://hdl.handle.net/10356/160065 |
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1738844889998688256 |
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sg-ntu-dr.10356-1600652022-07-16T20:11:50Z Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis Rasheedkhan Regina, Viduthalai Noorian, Parisa Sim, Clarence Bo Wen Constancias, Florentin Kaliyamoorthy, Eganathan Booth, Sean C. Espinoza-Vergara, Gustavo Rice, Scott A. McDougald, Diane School of Biological Sciences Singapore Centre for Environmental Life Sciences and Engineering (SCELSE) Science::Biological sciences Protozoan Predation Grazing Resistance Vibrio vulnificus is an opportunistic human pathogen and autochthonous inhabitant of coastal marine environments, where the bacterium is under constant predation by heterotrophic protists or protozoans. As a result of this selection pressure, genetic variants with antipredation mechanisms are selected for and persist in the environment. Such natural variants may also be pathogenic to animal or human hosts, making it important to understand these defense mechanisms. To identify antipredator strategies, 13 V. vulnificus strains of different genotypes isolated from diverse environments were exposed to predation by the ciliated protozoan Tetrahymena pyriformis, and only strain ENV1 was resistant to predation. Further investigation of the cell-free supernatant showed that ENV1 acidifies the environment by the excretion of organic acids, which are toxic to T. pyriformis. As this predation resistance was dependent on the availability of iron, transcriptomes of V. vulnificus in iron-replete and iron-deplete conditions were compared. This analysis revealed that ENV1 ferments pyruvate and the resultant acetyl-CoA leads to acetate synthesis under aerobic conditions, a hallmark of overflow metabolism. The anaerobic respiration global regulator arcA was upregulated when iron was available. An ΔarcA deletion mutant of ENV1 accumulated less acetate and, importantly, was sensitive to grazing by T. pyriformis. Based on the transcriptome response and quantification of metabolites, we conclude that ENV1 has adapted to overflow metabolism and has lost a control switch that shifts metabolism from acetate excretion to acetate assimilation, enabling it to excrete acetate continuously. We show that overflow metabolism and the acetate switch contribute to prey-predator interactions. IMPORTANCE Bacteria in the environment, including Vibrio spp., interact with protozoan predators. To defend against predation, bacteria evolve antipredator mechanisms ranging from changing morphology, biofilm formation, and secretion of toxins or virulence factors. Some of these adaptations may result in strains that are pathogenic to humans. Therefore, it is important to study predator defense strategies of environmental bacteria. V. vulnificus thrives in coastal waters and infects humans. Very little is known about the defense mechanisms V. vulnificus expresses against predation. Here, we show that a V. vulnificus strain (ENV1) has rewired the central carbon metabolism, enabling the production of excess organic acid that is toxic to the protozoan predator T. pyriformis. This is a previously unknown mechanism of predation defense that protects against protozoan predators. Ministry of Education (MOE) National Research Foundation (NRF) Published version We acknowledge support from the iThree Institute at the University of Technology Sydney, Sydney, Australia, the Australian Research Council Discovery Project (DP170100453) and by the National Research Foundation and Ministry of Education Singapore under its Research Centre of Excellence Program to the Singapore Centre for Environmental Life Sciences Engineering, Nanyang Technological University. 2022-07-12T05:29:28Z 2022-07-12T05:29:28Z 2022 Journal Article Rasheedkhan Regina, V., Noorian, P., Sim, C. B. W., Constancias, F., Kaliyamoorthy, E., Booth, S. C., Espinoza-Vergara, G., Rice, S. A. & McDougald, D. (2022). Loss of the acetate switch in Vibrio vulnificus enhances predation defense against Tetrahymena pyriformis. Applied and Environmental Microbiology, 88(2), e01665-21-. https://dx.doi.org/10.1128/AEM.01665-21 0099-2240 https://hdl.handle.net/10356/160065 10.1128/AEM.01665-21 34731052 2-s2.0-85123547599 2 88 e01665-21 en Applied and Environmental Microbiology © 2022 Rasheedkhan Regina et al. This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 International license. application/pdf |