Gao Lei, Huang Yin, Liu Yonghong, Mohamed Osama Abdalla Abdelshafy, Fan Xiaorong, Wang Lei, Li Li, Ma Jinbiao
State Key Laboratory of Desert and Oasis Ecology, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi 830011, China.
College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 100049, China.
Microorganisms. 2022 May 30;10(6):1124. doi: 10.3390/microorganisms10061124.
Halophytes play a crucial ecological role in drought and saline-alkali environments. However, there is limited knowledge about the structure of bacterial communities and the potential microbial coexistence mechanism associated with halophytes. This study investigated the diversity and community structure of endophytic and rhizospheric bacteria associated with three halophytes by applying high-throughput sequencing and geochemistry analyses on the studied soils. We collected 18 plant and 21 soil samples, and sequenced the V3 and V4 hypervariable regions of the 16S rRNA gene using next-generation sequencing (NGS). We also assessed geochemistry of the studied soils. The research suggested that rhizospheric bacterial richness and diversity associated with three halophytes were all significantly higher than for endophytic bacteria. The microbial community analysis indicated that , , and were the dominating bacterial phyla. Most unassigned operational taxonomic units (OTUs) implied that the microbes associated with halophytes contained abundant potential novel taxa, which are significant microbial resources. The high-abundance OTU phylogenetic tree supported the above views as well. Additionally, network analysis indicated that some conditional rare taxa (CRT) also might be keystone taxa during halophyte microbial community construction. The results of non-metric multidimensional scaling (NMDS) ordination analysis indicated significant dissimilarities in the microbial community among different sample groups. Sixty-two biomarkers were detected from seven different sample groups by linear discriminant analysis effect size (LEFSe) analysis. Microbial functions predicted based on phylogenetic investigation of communities by reconstruction of unobserved states (PICRUSt2) demonstrated that the abundances of nitrogen metabolism genes of endophytic bacteria were significantly higher than in rhizobacteria. Environmental factor analysis confirmed that different soil properties have different degrees of influence on the abundance and composition of the microbiota. To better adapt to the extreme hypersaline environment, halophytes could specifically recruit some plant beneficial bacterial taxa, such as nitrogen-fixing bacteria and extremely halophilic or halotolerant bacteria, to help them robustly grow and proliferate. All our preliminary results highlight microbial diversity and community related to halophytes grown on saline-alkali land of arid areas. Simultaneously, this work also advanced our further understanding of the halophyte microbiome associated with plants, and their role in plant adaptation to the extremely hypersaline environment.
盐生植物在干旱和盐碱环境中发挥着至关重要的生态作用。然而,关于与盐生植物相关的细菌群落结构以及潜在的微生物共存机制的了解有限。本研究通过对研究土壤进行高通量测序和地球化学分析,调查了与三种盐生植物相关的内生细菌和根际细菌的多样性及群落结构。我们收集了18个植物样本和21个土壤样本,并使用下一代测序(NGS)对16S rRNA基因的V3和V4高变区进行测序。我们还评估了研究土壤的地球化学性质。研究表明,与三种盐生植物相关的根际细菌丰富度和多样性均显著高于内生细菌。微生物群落分析表明, 、 、 和 是主要的细菌门类。大多数未分类的操作分类单元(OTU)表明,与盐生植物相关的微生物包含丰富的潜在新分类群,这些是重要的微生物资源。高丰度OTU系统发育树也支持上述观点。此外,网络分析表明,一些条件性稀有分类群(CRT)在盐生植物微生物群落构建过程中也可能是关键分类群。非度量多维尺度(NMDS)排序分析结果表明,不同样本组之间的微生物群落存在显著差异。通过线性判别分析效应大小(LEFSe)分析,从七个不同样本组中检测到62个生物标志物。基于未观察状态重建的群落系统发育调查(PICRUSt2)预测的微生物功能表明,内生细菌的氮代谢基因丰度显著高于根际细菌。环境因素分析证实,不同的土壤性质对微生物群落的丰度和组成有不同程度的影响。为了更好地适应极端高盐环境,盐生植物可以特异性地招募一些对植物有益的细菌分类群,如固氮细菌和极端嗜盐或耐盐细菌,以帮助它们茁壮成长和增殖。我们所有的初步结果都突出了干旱地区盐碱地生长的盐生植物相关的微生物多样性和群落。同时,这项工作也进一步增进了我们对与植物相关的盐生植物微生物组及其在植物适应极端高盐环境中的作用的理解。
