State Key Laboratory of Marine Environmental Science, College of Ocean and Earth Sciences, Xiamen University, Xiamen, China.
Xiamen City Key Laboratory of Urban Sea Ecological Conservation and Restoration (USER), Xiamen University, Xiamen, China.
Microbiol Spectr. 2024 Nov 5;12(11):e0144824. doi: 10.1128/spectrum.01448-24. Epub 2024 Oct 14.
The microbial communities associated with sponges contribute to the adaptation of hosts to environments, which are essential for the trophic transformation of benthic-marine coupling. However, little is known about the symbiotic microbial community interactions and adaptative strategies of high- and low-microbial abundance (HMA and LMA) sponges, which represent two typical ecological phenotypes. Here, we compared the 1-year dynamic patterns of microbiomes with the HMA sponge and two LMA sponge species sp. and widespread on the coast of China. Symbiotic bacterial communities with the characteristic HMA-LMA dichotomy presented higher diversity and stability in than in sp. and , while archaeal communities showed consistent diversity across all sponges throughout the year. Dissolved oxygen, dissolved inorganic phosphorus, dissolved organic phosphorus, and especially temperature were the major factors affecting the seasonal changes in sponge microbial communities. -associated microbiome had higher diversity, stronger stability, and closer interaction, which adopted a relatively isolated strategy to cope with environmental changes, while sp. and were more susceptible and shared more bacterial Amplicon Sequence Variants (ASVs) with surrounding waters, with an open way facing the uncertainty of the environment. Meta-analysis of the microbiome in composition, diversity, and ecological function from 13 marine sponges further supported that bacterial communities associated with HMA and LMA sponges have evolved two distinct environmental adaptation strategies. We propose that the different adaptive ways of sponges responding to the environment may be responsible for their successful evolution and their competence in global ocean change.
During long-term evolution, sponge holobionts, among the oldest symbiotic relationships between microbes and metazoans, developed two distinct phenotypes with high- and low-microbial abundance (HMA and LMA). Despite sporadic studies indicating that the characteristic microbial assemblages present in HMA and LMA sponges, the adaptation strategies of symbionts responding to environments are still unclear. This deficiency limits our understanding of the selection of symbionts and the ecological functions during the evolutionary history and the adaptative assessment of HMA and LMA sponges in variable environments. Here, we explored symbiotic communities with two distinct phenotypes in a 1-year dynamic environment and combined with the meta-analysis of 13 sponges. The different strategies of symbionts in adapting to the environment were basically drawn: microbes with LMA were more acclimated to environmental changes, forming relatively loose-connected communities, while HMA developed relatively tight-connected and more similar communities beyond the divergence of species and geographical location.
与海绵相关的微生物群落有助于宿主适应环境,这对底栖海洋耦合的营养转化至关重要。然而,对于高微生物丰度(HMA)和低微生物丰度(LMA)海绵的共生微生物群落相互作用和适应性策略,我们知之甚少,这两种海绵代表了两种典型的生态表型。在这里,我们比较了微生物组的 1 年动态模式与具有 HMA 的海绵 和两种在中国沿海广泛分布的 LMA 海绵物种 sp. 和 。具有 HMA-LMA 二分法特征的共生细菌群落,在 中比在 sp. 和 中具有更高的多样性和稳定性,而古菌群落全年在所有海绵中都表现出一致的多样性。溶解氧、溶解无机磷、溶解有机磷,尤其是温度是影响海绵微生物群落季节性变化的主要因素。与微生物组具有更高的多样性、更强的稳定性和更紧密的相互作用,采用相对孤立的策略来应对环境变化,而 sp. 和 则更容易受到影响,与周围水域共享更多的细菌扩增子序列变异(ASV),以开放的方式面对环境的不确定性。对来自 13 种海洋海绵的微生物组在组成、多样性和生态功能方面的元分析进一步支持了与 HMA 和 LMA 海绵相关的细菌群落已经进化出两种截然不同的环境适应策略。我们提出,海绵对环境的不同适应方式可能是其成功进化和在全球海洋变化中竞争力的原因。
在长期进化过程中,海绵全菌,作为微生物和后生动物之间最古老的共生关系之一,形成了高微生物丰度(HMA)和低微生物丰度(LMA)两种截然不同的表型。尽管零星的研究表明,HMA 和 LMA 海绵中存在特征性微生物群落,但共生体对环境的适应策略仍不清楚。这一缺陷限制了我们对共生体选择和进化历史中生态功能的理解,以及对可变环境中 HMA 和 LMA 海绵的适应性评估。在这里,我们在 1 年的动态环境中探索了具有两种截然不同表型的共生群落,并结合了对 13 种海绵的元分析。共生体适应环境的不同策略基本上可以概括为:具有 LMA 的微生物对环境变化的适应性更强,形成相对松散连接的群落,而 HMA 则形成相对紧密连接且更加相似的群落,超越了物种和地理位置的差异。
