Institute of Ecological Science, Guangzhou Key Laboratory of Subtropical Biodiversity and Biomonitoring, Guangdong Provincial Key Laboratory of Biotechnology for Plant Development, School of Life Sciences, South China Normal University, Guangzhou, People's Republic of China.
School of Life Sciences, Sun Yat-sen University, Guangzhou, People's Republic of China.
mSystems. 2023 Feb 23;8(1):e0073622. doi: 10.1128/msystems.00736-22. Epub 2022 Dec 12.
Methylmercury (MeHg) is a notorious neurotoxin, and its production and degradation in the environment are mainly driven by microorganisms. A variety of microbial MeHg producers carrying the gene pair and degraders carrying the gene have been separately reported in recent studies. However, surprisingly little attention has been paid to the simultaneous investigation of the diversities of microbial MeHg producers and degraders in a given habitat, and no studies have been performed to explore to what extent these two contrasting microbial groups correlate with MeHg accumulation in the habitat of interest. Here, we collected 86 acid mine drainage (AMD) sediments from an area spanning approximately 500,000 km in southern China and profiled the sediment-borne putative MeHg producers and degraders using genome-resolved metagenomics. 46 metagenome-assembled genomes (MAGs) containing and 93 MAGs containing were obtained, including those from various taxa without previously known MeHg-metabolizing microorganisms. These diverse MeHg-metabolizing MAGs were formed largely via multiple independent horizontal gene transfer (HGT) events. The putative MeHg producers from Deltaproteobacteria and as well as MeHg degraders from were closely correlated with MeHg accumulation in the sediments. Furthermore, these three taxa, in combination with two abiotic factors, explained over 60% of the variance in MeHg accumulation. Most of the members of these taxa were characterized by their metabolic potential for nitrogen fixation and copper tolerance. Overall, these findings improve our understanding of the ecology of MeHg-metabolizing microorganisms and likely have implications for the development of management strategies for the reduction of MeHg accumulation in the AMD sediments. Microorganisms are the main drivers of MeHg production and degradation in the environment. However, little attention has been paid to the simultaneous investigation of the diversities of microbial MeHg producers and degraders in a given habitat. We used genome-resolved metagenomics to reveal the vast phylogenetic and metabolic diversities of putative MeHg producers and degraders in AMD sediments. Our results show that the diversity of MeHg-metabolizing microorganisms (particularly MeHg degraders) in AMD sediments is much higher than was previously recognized. Via multiple linear regression analysis, we identified both microbial and abiotic factors affecting MeHg accumulation in AMD sediments. Despite their great diversity, only a few taxa of MeHg-metabolizing microorganisms were closely correlated with MeHg accumulation. This work underscores the importance of using genome-resolved metagenomics to survey MeHg-metabolizing microorganisms and provides a framework for the illumination of the microbial basis of MeHg accumulation via the characterization of physicochemical properties, MeHg-metabolizing microorganisms, and the correlations between them.
甲基汞(MeHg)是一种臭名昭著的神经毒素,其在环境中的产生和降解主要由微生物驱动。最近的研究分别报道了携带基因对 和 基因的各种微生物 MeHg 产生菌和降解菌。然而,令人惊讶的是,对于在给定生境中同时调查微生物 MeHg 产生菌和降解菌的多样性,几乎没有给予关注,也没有研究探索这两个相反的微生物群落在多大程度上与生境中 MeHg 的积累相关。在这里,我们从中国南方约 50 万平方公里的地区收集了 86 个酸性矿山排水(AMD)沉积物,并使用基因组解析宏基因组学对悬浮于沉积物中的假定 MeHg 产生菌和降解菌进行了分析。获得了 46 个含有 和 93 个含有 的宏基因组组装基因组(MAG),其中包括来自先前未知的 MeHg 代谢微生物的各种分类群的 MAG。这些多样化的 MeHg 代谢 MAG 主要通过多种独立的水平基因转移(HGT)事件形成。来自 Delta 变形菌和 的假定 MeHg 产生菌以及来自 的 MeHg 降解菌与沉积物中 MeHg 的积累密切相关。此外,这三个分类群与两个非生物因素一起,解释了 MeHg 积累方差的 60%以上。这些分类群的大多数成员的特点是其固氮和耐铜的代谢潜力。总的来说,这些发现提高了我们对 MeHg 代谢微生物生态学的理解,并且可能对制定减少 AMD 沉积物中 MeHg 积累的管理策略具有重要意义。微生物是环境中 MeHg 产生和降解的主要驱动因素。然而,对于在给定生境中同时调查微生物 MeHg 产生菌和降解菌的多样性,几乎没有给予关注。我们使用基因组解析宏基因组学揭示了 AMD 沉积物中假定 MeHg 产生菌和降解菌的广泛的系统发育和代谢多样性。我们的结果表明,AMD 沉积物中 MeHg 代谢微生物(特别是 MeHg 降解菌)的多样性高于先前的认识。通过多元线性回归分析,我们确定了影响 AMD 沉积物中 MeHg 积累的微生物和非生物因素。尽管多样性很大,但只有少数几类 MeHg 代谢微生物与 MeHg 积累密切相关。这项工作强调了使用基因组解析宏基因组学来调查 MeHg 代谢微生物的重要性,并为通过表征物理化学性质、MeHg 代谢微生物以及它们之间的相关性来阐明 MeHg 积累的微生物基础提供了一个框架。
