Singapore Centre for Environmental Life Sciences Engineering, Nanyang Technological Universitygrid.59025.3b, Singapore.
The iThree Institute, University of Technology Sydneygrid.117476.2, Sydney, Australia.
Appl Environ Microbiol. 2022 Jan 25;88(2):e0166521. doi: 10.1128/AEM.01665-21. Epub 2021 Nov 3.
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 was upregulated when iron was available. An Δ deletion mutant of ENV1 accumulated less acetate and, importantly, was sensitive to grazing by . 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. Bacteria in the environment, including 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 . This is a previously unknown mechanism of predation defense that protects against protozoan predators.
创伤弧菌是一种机会性人类病原体,也是沿海海洋环境中的本土居民,在这些环境中,细菌不断受到异养原生动物或原生动物的捕食。由于这种选择压力,具有抗捕食机制的遗传变异体被选择并在环境中持续存在。这种天然变异体也可能对动物或人类宿主具有致病性,因此了解这些防御机制很重要。为了确定抗捕食策略,从不同环境中分离出的 13 株不同基因型的创伤弧菌菌株被暴露于纤毛原生动物嗜热四膜虫的捕食下,只有菌株 ENV1 具有抗捕食性。进一步研究无细胞上清液表明,ENV1 通过分泌有机酸使环境酸化,这些有机酸对嗜热四膜虫有毒。由于这种抗捕食性依赖于铁的可用性,因此比较了铁充足和缺铁条件下创伤弧菌的转录组。该分析表明,ENV1 发酵丙酮酸,所得乙酰辅酶 A 在有氧条件下导致乙酸合成,这是溢出代谢的标志。当铁可用时,全球呼吸调节因子 上调。ENV1 的Δ缺失突变体积累的乙酸较少,重要的是,它对 的放牧敏感。基于转录组反应和代谢物的定量,我们得出结论,ENV1 已适应溢出代谢,并且失去了将代谢从乙酸排泄切换到乙酸同化的控制开关,从而使其能够持续排泄乙酸。我们表明,溢出代谢和乙酸开关有助于猎物-捕食者相互作用。环境中的细菌,包括 spp.,与原生动物捕食者相互作用。为了抵御捕食,细菌进化出了从改变形态、生物膜形成到分泌毒素或毒力因子等多种抗捕食机制。这些适应中的一些可能导致对人类致病的菌株。因此,研究环境细菌的捕食防御策略非常重要。创伤弧菌在沿海水域中繁衍生息并感染人类。人们对创伤弧菌针对捕食者的防御机制知之甚少。在这里,我们表明,一种创伤弧菌菌株(ENV1)已经重新布线了中心碳代谢,使过量的有机酸得以产生,这些有机酸对原生动物捕食者有毒。这是一种以前未知的捕食防御机制,可防止原生动物捕食者捕食。
