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社会互补和生长优势促进了社会缺陷细菌的分离株。

Social complementation and growth advantages promote socially defective bacterial isolates.

机构信息

Centre for Advanced Research in Environmental Genomics, Department of Biology, University of Ottawa, , 30 Marie Curie Private, Ottawa, Ontario, Canada , K2P 6N5, Institute for Integrative Biology, ETH Zürich, , Universitaetsstrasse 16, Zürich 8092, Switzerland, Department of Biology, Indiana University, , Bloomington, IN, USA.

出版信息

Proc Biol Sci. 2014 Feb 26;281(1781):20140036. doi: 10.1098/rspb.2014.0036. Print 2014 Apr 22.

DOI:10.1098/rspb.2014.0036
PMID:24573856
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3953853/
Abstract

Social interactions among diverse individuals that encounter one another in nature have often been studied among animals but rarely among microbes. For example, the evolutionary forces that determine natural frequencies of bacteria that express cooperative behaviours at low levels remain poorly understood. Natural isolates of the soil bacterium Myxococcus xanthus sampled from the same fruiting body often vary in social phenotypes, such as group swarming and multicellular development. Here, we tested whether genotypes highly proficient at swarming or development might promote the persistence of less socially proficient genotypes from the same fruiting body. Fast-swarming strains complemented slower isolates, allowing the latter to keep pace with faster strains in mixed groups. During development, one low-sporulating strain was antagonized by high sporulators, whereas others with severe developmental defects had those defects partially complemented by high-sporulating strains. Despite declining in frequency overall during competition experiments spanning multiple cycles of development, developmentally defective strains exhibited advantages during the growth phases of competitions. These results suggest that microbes with low-sociality phenotypes often benefit from interacting with more socially proficient strains. Such complementation may combine with advantages at other traits to increase equilibrium frequencies of low-sociality genotypes in natural populations.

摘要

在自然界中相互遇到的不同个体之间的社交互动,通常在动物中进行研究,但在微生物中很少进行。例如,决定在低水平表达合作行为的细菌自然频率的进化力量仍未得到很好的理解。从同一个子实体中分离出来的土壤细菌粘细菌的自然分离株在社交表型上经常存在差异,例如群体聚集和多细胞发育。在这里,我们测试了在群体聚集或发育方面非常有能力的基因型是否可能促进来自同一子实体的社会能力较低的基因型的持续存在。快速聚集的菌株补充了较慢的分离株,使后者能够在混合群体中跟上快速菌株的步伐。在发育过程中,一个低产孢的菌株被高产孢的菌株拮抗,而其他发育缺陷严重的菌株的缺陷则被高产孢的菌株部分弥补。尽管在跨越多个发育周期的竞争实验中,总体频率下降,但在竞争的生长阶段,发育缺陷的菌株表现出优势。这些结果表明,具有低社交表型的微生物通常受益于与更具社交能力的菌株相互作用。这种互补性可能与其他特征的优势结合起来,增加低社交基因型在自然种群中的平衡频率。

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