<i>Bacillus licheniformis</i> escapes from <i>Myxococcus xanthus</i> predation by deactivating myxovirescin A through enzymatic glucosylation

Zhang, Peng; Wang, Yan; Li, Zhifeng; Li, Xun; Wang, Renqing; Shang, Zhaohui; Yan, Jingen; He, Haifeng; Wang, Jing; Hu, Wei; Li, Yuezhong

doi:10.1111/1462-2920.14817

Cited by 22 publications

(26 citation statements)

References 69 publications

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“…Streptomyces coelicolor produces an antibiotic, actinorhodin, upon co-cultivation with M. xanthus, which however does not confer a survival advantage (Pérez et al, 2011). Recently, an enzyme released by Bacillus licheniformis was found to glycosylate myxovirescin A, which inactivates the antibiotic and renders the producing strain less susceptible to predation by M. xanthus (Wang et al, 2019).…”

Section: Regulatory Mechanisms and Prey Counteractionsmentioning

confidence: 99%

The Predation Strategy of Myxococcus xanthus

2020

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Myxobacteria are ubiquitous in soil environments. They display a complex life cycle: vegetatively growing cells coordinate their motility to form multicellular swarms, which upon starvation aggregate into large fruiting bodies where cells differentiate into spores. In addition to growing as saprophytes, Myxobacteria are predators that actively kill bacteria of other species to consume their biomass. In this review, we summarize research on the predation behavior of the model myxobacterium Myxococcus xanthus, which can access nutrients from a broad spectrum of microorganisms. M. xanthus displays an epibiotic predation strategy, i.e., it induces prey lysis from the outside and feeds on the released biomass. This predatory behavior encompasses various processes: Gliding motility and induced cell reversals allow M. xanthus to encounter prey and to remain within the area to sweep up its biomass, which causes the characteristic "rippling" of preying populations. Antibiotics and secreted bacteriolytic enzymes appear to be important predation factors, which are possibly targeted to prey cells with the aid of outer membrane vesicles. However, certain bacteria protect themselves from M. xanthus predation by forming mechanical barriers, such as biofilms and mucoid colonies, or by secreting antibiotics. Further understanding the molecular mechanisms that mediate myxobacterial predation will offer fascinating insight into the reciprocal relationships of bacteria in complex communities, and might spur application-oriented research on the development of novel antibacterial strategies.

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Section: Regulatory Mechanisms and Prey Counteractionsmentioning

confidence: 99%

The Predation Strategy of Myxococcus xanthus

2020

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“…Building upon previously reported resistance strategies to avoid predatory myxobacteria discovered from predator-prey experiments (11,(17)(18)(19)(20)(21)(22), predation experiments including aeruginosa antibiotic resistance were up-regulated in the survivor phenotype (38,39).…”

Section: Discussionmentioning

confidence: 87%

“…Compared to features associated with bacterial strategies to avoid protozoan predators, prey avoidance of predatory myxobacteria remains underexplored (Weitere et al, 2005;Justice et al, 2008;Erken et al, 2013;Seiler et al, 2017;Sun et al, 2018). Examples of prey responses correlated with resistance to myxobacterial predation include Escherichia coli biofilm formation (DePas et al, 2014), Bacillus subtilis sporulation and production of bacillaene (Muller et al, 2014;Muller et al, 2015), Bacillus licheniformus glycosylation of the predation-associated metabolite myxovirescin A (Wang et al, 2019), galactoglucan exopolysaccharide production and { PAGE } increased melanin production by Sinorhizobium meliloti (Perez et al, 2014;Contreras-Moreno et al, 2020), and formaldehyde secretion by Pseudomonas aeruginosa (Sutton et al, 2019). All of these features were discovered from predator-prey experiments utilizing the model myxobacterium M. xanthus.…”

Section: Introductionmentioning

confidence: 99%

Predatory selection of mucoid, antibiotic resistantPseudomonas putidaphenotype by myxobacteriumCystobacter ferrugineus

Akbar

Stevens

2020

Preprint

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Predation contributes to the structure and diversity of microbial communities. Predatory myxobacteria are ubiquitous to a variety of microbial habitats and capably consume a broad diversity of microbial prey. Predator-prey experiments utilizing myxobacteria have provided details into predatory mechanisms and features that facilitate consumption of prey. However, prey resistance to myxobacterial predation remains underexplored, and prey resistances have been observed exclusively from predator-prey experiments that included the model myxobacterium Myxococcus xanthus. Utilizing a predator-prey pairing that instead included the myxobacterium, Cystobacter ferrugineus, with Pseudomonas putida as prey, we infrequently observed surviving phenotypes capable of eluding predation. Comparative transcriptomics between P. putida unexposed to C. ferrugineus and the survivor phenotype suggested that increased expression of efflux pumps, genes associated with mucoid conversion, and various membrane features contribute to predator avoidance. The P. putida survivor phenotype was confirmed to be resistant to the antibiotics kanamycin, gentamicin, and tetracycline and to produce more alginate than predator-unexposed P. putida. Unique features observed from the survivor phenotype including small colony variation, efflux-mediated antibiotic resistance, and increased mucoid conversion overlap with traits associated with Pseudomonas aeruginosa predator avoidance and pathogenicity. The survivor phenotype also benefited from increased predator resistance during subsequent predation assays. These results demonstrate the utility of myxobacterial predator-prey models and provide insight into prey resistances in response to predatory stress might contribute to the phenotypic diversity and structure of bacterial communities.

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“…But interspecies cross talk can also trigger the production by prey of specific bioactive compounds for defensive purposes and other resistance mechanisms to counterattack such as biofilm formation [166] , spore differentiation, or induction of new ARGs [167] ( Fig. 3 ).…”

Section: Myxobacteria As Sources Of New Antibiotics Bioactive Producmentioning

confidence: 99%