两种共生深海对虾定居后阶段的共生体获取策略

IF 2.3 2区 生物学 Q2 ECOLOGY
Marion Guéganton, Pierre Methou, Johanne Aubé, Cyril Noël, Ouafae Rouxel, Valérie Cueff-Gauchard, Nicolas Gayet, Lucile Durand, Florence Pradillon, Marie-Anne Cambon-Bonavita
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引用次数: 0

摘要

在缺乏光照的深海热液喷口,大多数生物群落都由化学合成微生物提供燃料。这些微生物可以与元虫宿主形成共生关系,这些宿主被称为全生物。其中,大西洋中脊(MID-ATlantic Ridge)特有的两种共栖对虾 Rimicaris exoculata 和 Rimicaris chacei 在其头胸腔和消化系统中都有密集和多样化的化合共生群落。虽然这两种虾蕴藏着相似的群落,但它们的种群密度、小规模分布模式和食性却大相径庭,定居后的形态变化也各不相同,最终都进入了成体阶段。这些截然不同的生物特征可能与它们的共生发展成功与否有关。因此,与共生群落的获得和三个共生器官的发育有关的关键问题仍未解决。在此,我们利用 16S 代谢编码技术研究了 TAG 和蛇坑中 R. exoculata 和 R. chacei 幼体的共生发育情况,以确定在每个幼体阶段存在哪些共生系。此外,我们还利用荧光原位杂交(FISH)和扫描电子显微镜(SEM)突出显示了每个阶段微生物的丰度和分布。首次在幼体晚期发现了微鞭毛虫科念珠菌属念珠菌,包括Rimicarispirillum spp.(中肠管)、Candidatus Foregutplasma rimicarensis和Candidatus BG2-rimicarensis(前肠)。然而,这些菌系在幼虫早期阶段并不存在,这与我们观察到的中肠管组织未成熟、无微绒毛的情况相吻合。相反,来自头胸腔的共生菌系在两个物种最早的幼年阶段就出现了,其总体多样性与成虫相似。这些结果表明,头胸腔和消化系统之间存在不同的共生体获取动态,可能还涉及不同的传播机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Symbiont Acquisition Strategies in Post-Settlement Stages of Two Co-Occurring Deep-Sea Rimicaris Shrimp

Symbiont Acquisition Strategies in Post-Settlement Stages of Two Co-Occurring Deep-Sea Rimicaris Shrimp

At deep-sea hydrothermal vents, deprived of light, most living communities are fueled by chemosynthetic microorganisms. These can form symbiotic associations with metazoan hosts, which are then called holobionts. Among these, two endemic co-occurring shrimp of the Mid-Atlantic Ridge (MAR), Rimicaris exoculata and Rimicaris chacei are colonized by dense and diversified chemosynthetic symbiotic communities in their cephalothoracic cavity and their digestive system. Although both shrimp harbor similar communities, they exhibit widely different population densities, distribution patterns at small scale and diet, as well as differences in post-settlement morphological modifications leading to the adult stage. These contrasting biological traits may be linked to their symbiotic development success. Consequently, key questions related to the acquisition of the symbiotic communities and the development of the three symbiotic organs are still open. Here we examined symbiotic development in juveniles of R. exoculata and R. chacei from TAG and Snake Pit using 16S metabarcoding to identify which symbiotic lineages are present at each juvenile stage. In addition, we highlighted the abundance and distribution of microorganisms at each stage using Fluorescence in situ Hybridization (FISH) and Scanning Electron Microscopy (SEM). For the first time, Candidatus Microvillispirillaceae family with Candidatus Rimicarispirillum spp. (midgut tube), Candidatus Foregutplasma rimicarensis and Candidatus BG2-rimicarensis (foregut) were identified in late juvenile stages. However, these lineages were absent in early juvenile stages, which coincides for the midgut tube with our observations of an immature tissue, devoid of microvilli. Conversely, symbiotic lineages from the cephalothoracic cavity were present from the earliest juvenile stages of both species and their overall diversities were similar to those of adults. These results suggest different symbiont acquisition dynamics between the cephalothoracic cavity and the digestive system, which may also involve distinct transmission mechanisms.

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来源期刊
CiteScore
4.40
自引率
3.80%
发文量
1027
审稿时长
3-6 weeks
期刊介绍: Ecology and Evolution is the peer reviewed journal for rapid dissemination of research in all areas of ecology, evolution and conservation science. The journal gives priority to quality research reports, theoretical or empirical, that develop our understanding of organisms and their diversity, interactions between them, and the natural environment. Ecology and Evolution gives prompt and equal consideration to papers reporting theoretical, experimental, applied and descriptive work in terrestrial and aquatic environments. The journal will consider submissions across taxa in areas including but not limited to micro and macro ecological and evolutionary processes, characteristics of and interactions between individuals, populations, communities and the environment, physiological responses to environmental change, population genetics and phylogenetics, relatedness and kin selection, life histories, systematics and taxonomy, conservation genetics, extinction, speciation, adaption, behaviour, biodiversity, species abundance, macroecology, population and ecosystem dynamics, and conservation policy.
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