Cooperation in microbial communities and their biotechnological applications

Cavaliere, Matteo; Feng, Song; Soyer, Orkun S.; Jiménez, José I.

doi:10.1111/1462-2920.13767

Cited by 168 publications

(131 citation statements)

References 113 publications

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“…The enzymatic modification of antibiotics is both a deactivation mechanism that confers bacterial resistance (Blair et al, 2015) and a cooperative behaviour that can allow resistant cells to protect sensitive cells from antibiotics (Yurtsev et al, 2016). The presence of cooperative interactions among microorganisms is now recognized as an important factor in the function and evolutionary dynamics of microbial communities (Asfahl and Schuster, 2017;Cavaliere et al, 2017). Understanding how microbial cooperation can enable microbes to survive antibiotic exposure in environments is important both clinically and ecologically (Yurtsev et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

Bacillus licheniformis escapes from Myxococcus xanthus predation by deactivating myxovirescin A through enzymatic glucosylation

Zhang

Wang

et al. 2019

Environmental Microbiology

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Summary Myxococcus xanthus kills susceptible bacteria using myxovirescin A (TA) during predation. However, whether prey cells in nature can escape M. xanthus by developing resistance to TA is unknown. We observed that many field‐isolated Bacillus licheniformis strains could survive encounters with M. xanthus, which was correlated to their TA resistance. A TA glycoside was identified in the broth of predation‐resistant B. licheniformis J32 co‐cultured with M. xanthus, and a glycosyltransferase gene (yjiC) was up‐regulated in J32 after the addition of TA. Hetero‐expressed YjiC‐modified TA to a TA glucoside (TA‐Gluc) by conjugating a glucose moiety to the C‐21 hydroxyl group, and the resulting compound was identical to the TA glycoside present in the co‐culture broth. TA‐Gluc exhibited diminished bactericidal activity due to its weaker binding with LspA, as suggested by in silico docking data. Heterologous expression of the yjiC gene conferred both TA and M. xanthus‐predation resistance to the host Escherichia coli cells. Furthermore, under predatory pressure, B. licheniformis Y071 rapidly developed predation resistance by acquiring TA resistance through the overexpression of yjiC and lspA genes. These results suggest that M. xanthus predation resistance in B. licheniformis is due to the TA deactivation by glucosylation, which is induced in a predator‐mediated manner.

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Section: Discussionmentioning

confidence: 99%

Bacillus licheniformis escapes from Myxococcus xanthus predation by deactivating myxovirescin A through enzymatic glucosylation

Zhang

Wang

et al. 2019

Environmental Microbiology

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“…It is certainly not straightforward to apply the lessons learned from animal cooperativity to microbial systems. Although a thorough treatment of this subject is beyond our word limit, some excellent reviews and discussions are available …”

Section: A Variety Of Mechanisms Allow the Evolution Of Cooperativitymentioning

confidence: 99%

Is “Wolf‐Pack” Predation by Antimicrobial Bacteria Cooperative? Cell Behaviour and Predatory Mechanisms Indicate Profound Selfishness, Even when Working Alongside Kin

Marshall

Whitworth

2019

BioEssays

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For decades, myxobacteria have been spotlighted as exemplars of social “wolf‐pack” predation, communally secreting antimicrobial substances into the shared public milieu. This behavior has been described as cooperative, becoming more efficient if performed by more cells. However, laboratory evidence for cooperativity is limited and of little relevance to predation in a natural setting. In contrast, there is accumulating evidence for predatory mechanisms promoting “selfish” behavior during predation, which together with conflicting definitions of cooperativity, casts doubt on whether microbial “wolf‐pack” predation really is cooperative. Here, it is hypothesized that public‐goods‐mediated predation is not cooperative, and it is argued that a holistic model of microbial predation is needed, accounting for predator and prey relatedness, social phenotypes, spatial organization, activity/specificity/transport of secreted toxins, and prey resistance mechanisms. Filling such gaps in our knowledge is vital if the evolutionary benefits of potentially costly microbial behaviors mediated by public goods are to be properly understood.

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“…More generally, the field of synthetic community ecology, the rational design and control of microbial communities, is gaining momentum in biotechnology and in addressing fundamental ecological questions (De Roy et al, 2014). Broader application of rationally designed communities will develop over the next 20 years with a more mechanistic understanding of crossfeeding and syntrophic interactions and the production of public goods (such as extracellular polymeric substances or extracellular enzymes), as well as with improved analysis of metabolites (Cavaliere et al, 2017). Understanding and minimizing the switch from cooperative to competitive behaviour, and in particular how to limit 'cheating' by members of a consortium, will make the functioning of consortia more reliable (Lindemann et al, 2016;Cavaliere et al, 2017).…”

Section: Microbes Working Togethermentioning

confidence: 99%

“…Broader application of rationally designed communities will develop over the next 20 years with a more mechanistic understanding of crossfeeding and syntrophic interactions and the production of public goods (such as extracellular polymeric substances or extracellular enzymes), as well as with improved analysis of metabolites (Cavaliere et al, 2017). Understanding and minimizing the switch from cooperative to competitive behaviour, and in particular how to limit 'cheating' by members of a consortium, will make the functioning of consortia more reliable (Lindemann et al, 2016;Cavaliere et al, 2017). Several approaches are being used to make consortia more productive, manageable and predictable for bioengineers, for example, by optimizing spatial organization of species so that they can grow under ideal conditions while allowing metabolite exchange with their partner species, all of which is aided by developments in microfluidics, microfabrication and microsensors (Ben Said & Or, 2017;Seymour et al, 2017).…”

Section: Microbes Working Togethermentioning

confidence: 99%

“…Cyanobacteria, for example, produce hydrocarbons that could sustain populations of hydrocarbonoclastic bacteria and contribute to a potentially large-scale cryptic hydrocarbon cycle in the oceans (Lea-Smith et al, 2015), and microalgal phototrophs in general enhance hydrocarbon biodegradation by supplying oxygen and other compounds to associated bacteria (McGenity et al, 2012). The next 20 years will see an accelerated move toward biotechnological processes using mixed cultures of diverse constellations, both bottom-up designed and topdown tamed, underpinned by an improved understanding of how microbial molecular cocktails influence social behaviour and by predictive models to provide efficient and stable processes (Richter et al, 2018;Cavaliere et al, 2017;Widder et al, 2016;Hays et al, 2015).…”

Section: Microbes Working Togethermentioning

confidence: 99%

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