猎物对粘菌捕食敏感性的遗传学研究进展,包括影响黄粘球菌捕食的铜绿假单胞菌突变的研究。

Pub Date : 2021-01-01 Epub Date: 2021-04-01 DOI:10.1159/000515546
Natashia Sydney, Martin T Swain, Jeffery M T So, Egbert Hoiczyk, Nicholas P Tucker, David E Whitworth
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引用次数: 13

摘要

细菌捕食是一个普遍存在的基本生物过程,影响着微生物生态系统的群落组成。其中最具特征的细菌捕食者是粘菌,其中包括模式生物粘球菌。M. xanthus的捕食涉及抗生素代谢物和水解酶的分泌,这导致猎物有机体的裂解和猎物营养物质释放到细胞外环境中。由于这种捕食机制的通用性,M. xanthus具有广泛的猎物范围,能够杀死和消耗革兰氏阴性/阳性细菌和真菌。潜在的猎物生物已经进化出一系列的行为来保护自己免受捕食者的攻击。近年来,一些研究研究了多种被捕食生物对黄芽孢杆菌捕食的分子反应。猎物所采用的各种机制似乎属于少数几种一般的“抵抗捕食”策略。在这篇简短的综述中,我们介绍了目前关于黄芽孢杆菌捕食的知识状况,以及被捕食生物如何抵抗捕食。由于先前对猎物敏感性的分子研究主要集中在个体基因/代谢物上,我们也对铜绿假单胞菌抗捕食能力的基因进行了全基因组筛选。铜绿假单胞菌是世界卫生组织优先考虑的耐抗生素病原体。它代谢多样,具有一系列致病机制,导致其作为机会致病菌流行。利用近5500个已定义的转座子插入突变体的文库,我们筛选了“猎物基因”,这些基因在突变后可以增加黄色分枝杆菌荧光菌株的捕食。我们发现了一组候选“猎物蛋白”,它们具有共同的功能作用,其性质表明铜绿假单胞菌的捕食抗性需要有效的金属/氧化应激系统、完整的运动系统和解毒抗菌肽的机制。
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The Genetics of Prey Susceptibility to Myxobacterial Predation: A Review, Including an Investigation into Pseudomonas aeruginosa Mutations Affecting Predation by Myxococcus xanthus.

Bacterial predation is a ubiquitous and fundamental biological process, which influences the community composition of microbial ecosystems. Among the best characterised bacterial predators are the myxobacteria, which include the model organism Myxococcus xanthus. Predation by M. xanthus involves the secretion of antibiotic metabolites and hydrolytic enzymes, which results in the lysis of prey organisms and release of prey nutrients into the extracellular milieu. Due to the generalist nature of this predatory mechanism, M. xanthus has a broad prey range, being able to kill and consume Gram-negative/positive bacteria and fungi. Potential prey organisms have evolved a range of behaviours which protect themselves from attack by predators. In recent years, several investigations have studied the molecular responses of a broad variety of prey organisms to M. xanthus predation. It seems that the diverse mechanisms employed by prey belong to a much smaller number of general "predation resistance" strategies. In this mini-review, we present the current state of knowledge regarding M. xanthus predation, and how prey organisms resist predation. As previous molecular studies of prey susceptibility have focussed on individual genes/metabolites, we have also undertaken a genome-wide screen for genes of Pseudomonas aeruginosa which contribute to its ability to resist predation. P. aeruginosa is a World Health Organisation priority 1 antibiotic-resistant pathogen. It is metabolically versatile and has an array of pathogenic mechanisms, leading to its prevalence as an opportunistic pathogen. Using a library of nearly 5,500 defined transposon insertion mutants, we screened for "prey genes", which when mutated allowed increased predation by a fluorescent strain of M. xanthus. A set of candidate "prey proteins" were identified, which shared common functional roles and whose nature suggested that predation resistance by P. aeruginosa requires an effective metal/oxidative stress system, an intact motility system, and mechanisms for de-toxifying antimicrobial peptides.

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