University of Vienna, Centre for Microbiology and Environmental Systems Science, Vienna, Austria.
Doctoral School in Microbiology and Environmental Science, University of Vienna, Vienna, Austria.
mSystems. 2024 Jun 18;9(6):e0113523. doi: 10.1128/msystems.01135-23. Epub 2024 May 15.
Sulfur-oxidizing bacteria (SOB) have developed distinct ecological strategies to obtain reduced sulfur compounds for growth. These range from specialists that can only use a limited range of reduced sulfur compounds to generalists that can use many different forms as electron donors. Forming intimate symbioses with animal hosts is another highly successful ecological strategy for SOB, as animals, through their behavior and physiology, can enable access to sulfur compounds. Symbioses have evolved multiple times in a range of animal hosts and from several lineages of SOB. They have successfully colonized a wide range of habitats, from seagrass beds to hydrothermal vents, with varying availability of symbiont energy sources. Our extensive analyses of sulfur transformation pathways in 234 genomes of symbiotic and free-living SOB revealed widespread conservation in metabolic pathways for sulfur oxidation in symbionts from different host species and environments, raising the question of how they have adapted to such a wide range of distinct habitats. We discovered a gene family expansion of in these genomes, with up to five distinct copies per genome. Symbionts harboring only the "canonical" were typically ecological "specialists" that are associated with specific host subfamilies or environments (e.g., hydrothermal vents, mangroves). Conversely, symbionts with multiple divergent genes formed versatile associations across diverse hosts in various marine environments. We hypothesize that expansion and diversification of the gene family could be one genomic mechanism supporting the metabolic flexibility of symbiotic SOB enabling them and their hosts to thrive in a range of different and dynamic environments.IMPORTANCESulfur metabolism is thought to be one of the most ancient mechanisms for energy generation in microorganisms. A diverse range of microorganisms today rely on sulfur oxidation for their metabolism. They can be free-living, or they can live in symbiosis with animal hosts, where they power entire ecosystems in the absence of light, such as in the deep sea. In the millions of years since they evolved, sulfur-oxidizing bacteria have adopted several highly successful strategies; some are ecological "specialists," and some are "generalists," but which genetic features underpin these ecological strategies are not well understood. We discovered a gene family that has become expanded in those species that also seem to be "generalists," revealing that duplication, repurposing, and reshuffling existing genes can be a powerful mechanism driving ecological lifestyle shifts.
硫氧化细菌 (SOB) 已经发展出独特的生态策略来获取生长所需的还原态硫化合物。这些策略的范围从只能使用有限数量的还原态硫化合物的专家到可以作为电子供体使用许多不同形式的通才。与动物宿主形成亲密共生关系是 SOB 另一种非常成功的生态策略,因为动物通过其行为和生理特性,可以使它们能够获得硫化合物。共生关系已经在多种动物宿主和 SOB 的多个谱系中多次进化。它们已经成功地在从海草床到热液喷口等各种不同的栖息地中定植,共生能源来源的可用性也各不相同。我们对 234 个共生和自由生活 SOB 的基因组中的硫转化途径进行了广泛的分析,发现来自不同宿主物种和环境的共生体中硫氧化的代谢途径广泛保守,这提出了一个问题,即它们如何适应如此广泛的不同栖息地。我们发现,在这些基因组中,有一个基因家族的扩张,每个基因组多达五个不同的拷贝。只含有“经典”的共生体通常是与特定宿主亚科或环境(例如热液喷口、红树林)相关的生态“专家”。相反,具有多个不同的 基因的共生体在各种海洋环境中形成了多样化的宿主之间的多功能共生关系。我们假设,基因家族的扩张和多样化可能是支持共生 SOB 代谢灵活性的一种基因组机制,使它们及其宿主能够在一系列不同和动态的环境中茁壮成长。
