Department of Biology, University of California, Riverside, CA, USA.
BMC Evol Biol. 2010 Feb 17;10:48. doi: 10.1186/1471-2148-10-48.
Outer membrane proteins (OMPs) of Gram-negative bacteria are key players in the biology of bacterial-host interactions. However, while considerable attention has been given to OMPs of vertebrate pathogens, relatively little is known about the role of these proteins in bacteria that primarily infect invertebrates. One such OMP is found in the intracellular bacteria Wolbachia, which are widespread symbionts of arthropods and filarial nematodes. Recent experimental studies have shown that the Wolbachia surface protein (WSP) can trigger host immune responses and control cell death programming in humans, suggesting a key role of WSP for establishment and persistence of the symbiosis in arthropods.
Here we performed an analysis of 515 unique alleles found in 831 Wolbachia isolates, to investigate WSP structure, microevolution and population genetics. WSP shows an eight-strand transmembrane beta-barrel structure with four extracellular loops containing hypervariable regions (HVRs). A clustering approach based upon patterns of HVR haplotype diversity was used to group similar WSP sequences and to estimate the relative contribution of mutation and recombination during early stages of protein divergence. Results indicate that although point mutations generate most of the new protein haplotypes, recombination is a predominant force triggering diversity since the very first steps of protein evolution, causing at least 50% of the total amino acid variation observed in recently diverged proteins. Analysis of synonymous variants indicates that individual WSP protein types are subject to a very rapid turnover and that HVRs can accommodate a virtually unlimited repertoire of peptides. Overall distribution of WSP across hosts supports a non-random association of WSP with the host genus, although extensive horizontal transfer has occurred also in recent times.
In OMPs of vertebrate pathogens, large recombination impact, positive selection, reduced structural and compositional constraints, and extensive lateral gene transfer are considered hallmarks of evolution in response to the adaptive immune system. However, Wolbachia do not infect vertebrates. Here we predict that the rapid turnover of WSP loop motifs could aid in evading or inhibiting the invertebrate innate immune response. Overall, these features identify WSP as a strong candidate for future studies of host-Wolbachia interactions that affect establishment and persistence of this widespread endosymbiosis.
革兰氏阴性菌的外膜蛋白(OMPs)是细菌与宿主相互作用生物学中的关键因素。然而,尽管人们对脊椎动物病原体的 OMP 给予了相当多的关注,但对于主要感染无脊椎动物的细菌中这些蛋白质的作用却知之甚少。一种这样的 OMP 存在于细胞内细菌沃尔巴克氏体(Wolbachia)中,它是节肢动物和丝虫线虫的广泛共生体。最近的实验研究表明,沃尔巴克氏体表面蛋白(WSP)可以触发宿主的免疫反应并控制人类细胞死亡编程,这表明 WSP 对于在节肢动物中建立和维持共生关系起着关键作用。
在这里,我们对 831 个沃尔巴克氏体分离株中发现的 515 个独特等位基因进行了分析,以研究 WSP 的结构、微观进化和群体遗传学。WSP 显示出一个八链跨膜β-桶结构,有四个包含高变区(HVRs)的细胞外环。一种基于 HVR 单倍型多样性模式的聚类方法被用来对相似的 WSP 序列进行分组,并估计在蛋白质分化的早期阶段突变和重组对相对贡献。结果表明,尽管点突变产生了大多数新的蛋白质单倍型,但重组是触发多样性的主要力量,因为这是蛋白质进化的最初步骤,导致在最近分化的蛋白质中观察到的总氨基酸变异的至少 50%。对同义变体的分析表明,个体 WSP 蛋白类型受到非常快速的更替,并且 HVR 可以容纳几乎无限数量的肽。WSP 在宿主中的整体分布支持 WSP 与宿主属的非随机关联,尽管在最近的时间里也发生了广泛的水平转移。
在脊椎动物病原体的 OMPs 中,大的重组影响、正选择、减少的结构和组成约束以及广泛的横向基因转移被认为是对适应性免疫系统进化的标志。然而,沃尔巴克氏体不感染脊椎动物。在这里,我们预测 WSP 环基序的快速更替可能有助于逃避或抑制无脊椎动物的先天免疫反应。总的来说,这些特征将 WSP 确定为未来研究影响这种广泛共生关系建立和维持的宿主-沃尔巴克氏体相互作用的有力候选者。
