Environmental selection and evolutionary process jointly shape genomic and functional profiles of mangrove rhizosphere microbiomes.

IF 4.5 Q1 MICROBIOLOGY mLife Pub Date : 2023-09-03 eCollection Date: 2023-09-01 DOI:10.1002/mlf2.12077
Xiaoli Yu, Qichao Tu, Jihua Liu, Yisheng Peng, Cheng Wang, Fanshu Xiao, Yingli Lian, Xueqin Yang, Ruiwen Hu, Huang Yu, Lu Qian, Daoming Wu, Ziying He, Longfei Shu, Qiang He, Yun Tian, Faming Wang, Shanquan Wang, Bo Wu, Zhijian Huang, Jianguo He, Qingyun Yan, Zhili He
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Abstract

Mangrove reforestation with introduced species has been an important strategy to restore mangrove ecosystem functioning. However, how such activities affect microbially driven methane (CH4), nitrogen (N), and sulfur (S) cycling of rhizosphere microbiomes remains unclear. To understand the effect of environmental selection and the evolutionary process on microbially driven biogeochemical cycles in native and introduced mangrove rhizospheres, we analyzed key genomic and functional profiles of rhizosphere microbiomes from native and introduced mangrove species by metagenome sequencing technologies. Compared with the native mangrove (Kandelia obovata, KO), the introduced mangrove (Sonneratia apetala, SA) rhizosphere microbiome had significantly (p < 0.05) higher average genome size (AGS) (5.8 vs. 5.5 Mb), average 16S ribosomal RNA gene copy number (3.5 vs. 3.1), relative abundances of mobile genetic elements, and functional diversity in terms of the Shannon index (7.88 vs. 7.84) but lower functional potentials involved in CH4 cycling (e.g., mcrABCDG and pmoABC), N2 fixation (nifHDK), and inorganic S cycling (dsrAB, dsrC, dsrMKJOP, soxB, sqr, and fccAB). Similar results were also observed from the recovered Proteobacterial metagenome-assembled genomes with a higher AGS and distinct functions in the introduced mangrove rhizosphere. Additionally, salinity and ammonium were identified as the main environmental drivers of functional profiles of mangrove rhizosphere microbiomes through deterministic processes. This study advances our understanding of microbially mediated biogeochemical cycling of CH4, N, and S in the mangrove rhizosphere and provides novel insights into the influence of environmental selection and evolutionary processes on ecosystem functions, which has important implications for future mangrove reforestation.

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环境选择和进化过程共同塑造了红树林根瘤微生物组的基因组和功能特征。
利用引进物种进行红树林再造林一直是恢复红树林生态系统功能的重要策略。然而,这些活动如何影响根瘤微生物群的微生物驱动的甲烷(CH4)、氮(N)和硫(S)循环仍不清楚。为了了解环境选择和进化过程对原生和引进红树林根瘤菌圈微生物驱动的生物地球化学循环的影响,我们利用元基因组测序技术分析了原生和引进红树林物种根瘤菌圈微生物组的关键基因组和功能图谱。与原生红树林(Kandelia obovata,KO)相比,引进红树林(Sonneratia apetala,SA)根瘤微生物组在循环(如 mcrABCDG 和 pmoABC)、N2 固定(nifHDK)和无机 S 循环(dsrAB、dsrC、dsrMKJOP、soxB、sqr 和 fccAB)方面有显著差异(p 4)。从回收的蛋白细菌元基因组中也观察到了类似的结果,这些基因组在引入的红树林根瘤中具有更高的 AGS 和独特的功能。此外,通过确定性过程,盐度和铵被确定为红树林根瘤微生物组功能特征的主要环境驱动因素。这项研究加深了我们对红树林根瘤菌层中微生物介导的 CH4、N 和 S 的生物地球化学循环的理解,并为环境选择和进化过程对生态系统功能的影响提供了新的见解,这对未来的红树林再造林具有重要意义。
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