Chavez-Dozal Alba A, Gorman Clayton, Lostroh C Phoebe, Nishiguchi Michele K
New Mexico State University, Department of Biology, Las Cruces, New Mexico, United States of America.
Colorado College, Department of Biology, Colorado Springs, Colorado, United States of America.
PLoS One. 2014 Jul 11;9(7):e101691. doi: 10.1371/journal.pone.0101691. eCollection 2014.
Environmentally acquired beneficial associations are comprised of a wide variety of symbiotic species that vary both genetically and phenotypically, and therefore have differential colonization abilities, even when symbionts are of the same species. Strain variation is common among conspecific hosts, where subtle differences can lead to competitive exclusion between closely related strains. One example where symbiont specificity is observed is in the sepiolid squid-Vibrio mutualism, where competitive dominance exists among V. fischeri isolates due to subtle genetic differences between strains. Although key symbiotic loci are responsible for the establishment of this association, the genetic mechanisms that dictate strain specificity are not fully understood. We examined several symbiotic loci (lux-bioluminescence, pil = pili, and msh-mannose sensitive hemagglutinin) from mutualistic V. fischeri strains isolated from two geographically distinct squid host species (Euprymna tasmanica-Australia and E. scolopes-Hawaii) to determine whether slight genetic differences regulated host specificity. Through colonization studies performed in naïve squid hatchlings from both hosts, we found that all loci examined are important for specificity and host recognition. Complementation of null mutations in non-native V. fischeri with loci from the native V. fischeri caused a gain in fitness, resulting in competitive dominance in the non-native host. The competitive ability of these symbiotic loci depended upon the locus tested and the specific squid species in which colonization was measured. Our results demonstrate that multiple bacterial genetic elements can determine V. fischeri strain specificity between two closely related squid hosts, indicating how important genetic variation is for regulating conspecific beneficial interactions that are acquired from the environment.
环境中获得的有益共生关系由多种共生物种组成,这些物种在基因和表型上都存在差异,因此即使共生体属于同一物种,它们的定殖能力也有所不同。菌株变异在同种宿主中很常见,细微的差异可能导致密切相关菌株之间的竞争排斥。观察到共生体特异性的一个例子是乌贼-费氏弧菌的互利共生关系,由于菌株之间细微的基因差异,费氏弧菌分离株之间存在竞争优势。虽然关键的共生基因座负责这种共生关系的建立,但决定菌株特异性的遗传机制尚未完全了解。我们研究了从两种地理上不同的乌贼宿主物种(澳大利亚的塔斯马尼亚艾氏乌贼和夏威夷的艾氏乌贼)分离出的互利共生费氏弧菌菌株的几个共生基因座(lux-生物发光、pil=菌毛和msh-甘露糖敏感血凝素),以确定轻微的基因差异是否调节宿主特异性。通过对来自这两种宿主的未接触过共生体的乌贼幼体进行定殖研究,我们发现所有检测的基因座对特异性和宿主识别都很重要。用来自本地费氏弧菌的基因座对非本地费氏弧菌的无效突变进行互补,会导致适应性增强,从而在非本地宿主中产生竞争优势。这些共生基因座的竞争能力取决于所测试的基因座和测量定殖情况的特定乌贼物种。我们的结果表明,多个细菌遗传元件可以决定两种密切相关的乌贼宿主之间费氏弧菌菌株的特异性,这表明遗传变异对于调节从环境中获得的同种有益相互作用是多么重要。
