Heterogeneous marine environments diversify microbial-driven polymetallic nodule formation in the South China Sea

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Mingyan Lai, Qian Liu, Xiaogu Wang, Dong Sun, Lihua Ran, Xiaohu Li, Chenghao Yang, Bo Lu, Xue-Wei Xu, Chun-Sheng Wang
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Abstract

Most studies on the genesis of polymetallic nodules suggested that nodules in the South China Sea (SCS) are hydrogenetic; however, the complexity and the heterogeneity in hydrology and geochemistry of the SCS might cause different processes of nodule formation, impacting their application and economic value. Microbial-mediated ferromanganese deposition is an important process in nodule formation, but the related microbial potentials are still unclear in the SCS. In this study, we sampled in three typical regions (A, B, and C) of the SCS enriched with polymetallic nodules. Firstly, we investigated environmental and microbial characteristics of the water columns to determine the heterogeneity of upper seawater that directly influenced deep-sea environments. Then, microbial compositions and structures in sediment cores, overlying waters, and nodules (inside and outside) collected within the same region were analyzed for inferring features of nodule environments. Microbial interactions between nodules and surrounding environments were estimated with collinear network analysis. The microbial evidence indicated that geochemical characteristics in deep sea of the SCS that were key to the polymetallic nodule formation were severely affected by organic matter flux from upper water column. The sediment in region A was sub-oxic due to the large input of terrigenous and phytoplankton-derived organic matter, potentially enhancing the overflow of reduced metals from the porewater. The intense microbial interaction between nodules and surface sediment reinforced the origin of metals for the ferromanganese deposition from the sediment (diagenetic type). Contrarily, the sediments in regions B and C were relatively rich in oxygen, and metal ions could be majorly supplied from seawater (hydrogenetic type). The large discrepancy in microbial communities between nodule inside and remaining samples suggested that nodules experienced a long-term formation process, consistent with the feature of hydrogenetic nodules. Overall, distributions and interactions of microbial communities in nodules and surrounding environments significantly contributed to the nodule formation in the SCS by manipulating biogeochemical processes that eventually determined the source and the fate of metal ions.
异质海洋环境使南海微生物驱动的多金属结核形成多样化
大多数关于多金属结核成因的研究认为,中国南海(SCS)的结核是水成的;然而,SCS 水文和地球化学的复杂性和异质性可能会导致不同的结核形成过程,影响其应用和经济价值。微生物介导的铁锰沉积是结核形成的一个重要过程,但相关微生物在 SCS 中的潜力尚不清楚。在本研究中,我们在富含多金属结核的 SCS 三个典型区域(A、B 和 C)取样。首先,我们调查了水柱的环境和微生物特征,以确定直接影响深海环境的上层海水的异质性。然后,分析了在同一区域内采集的沉积岩芯、上覆海水和结核(内部和外部)中的微生物组成和结构,以推断结核环境的特征。利用平行网络分析估算了结核与周围环境之间的微生物相互作用。微生物证据表明,南中国海深海的地球化学特征是多金属结核形成的关键,受到上层水体有机质通量的严重影响。由于大量输入陆生和浮游植物生成的有机物,A 区的沉积物处于亚缺氧状态,这可能会加剧孔隙水中还原金属的溢出。结核与表层沉积物之间强烈的微生物相互作用加强了沉积物(成岩型)铁锰沉积的金属来源。相反,B 区和 C 区的沉积物含氧量相对较高,金属离子主要来自海水(水成型)。结核内部与其余样本之间微生物群落的巨大差异表明,结核经历了一个长期的形成过程,这与水成结核的特征一致。总之,结核和周围环境中微生物群落的分布和相互作用,通过操纵生物地球化学过程,最终决定了金属离子的来源和归宿,从而在很大程度上促进了 SCS 中结核的形成。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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