Fernandes Sheryl Oliveira, Paul Dhiraj, Lankalapalli Surya Prakash, Arvapalli Srinivas Rao, Pj Vidya, Palayil John Kurian
National Center for Polar and Ocean Research, Ministry of Earth Sciences, Vasco-da-Gama, Goa, India.
National Center for Microbial Resource, National Center for Cell Science, Pune, India.
Microbiol Spectr. 2025 Feb 4;13(2):e0330623. doi: 10.1128/spectrum.03306-23. Epub 2024 Dec 27.
Deep sea microbial communities play a significant role in global biogeochemical processes. However, the depth-wise metabolic potential of microbial communities in hydrothermally influenced Central Indian Ridge (CIR) and Southwest Indian Ridge (SWIR) remains elusive. In this study, a comprehensive functional microarray-based approach was used to understand factors influencing the metabolic potential of microbial communities and depth-driven differences in microbial functional gene composition in CIR and SWIR. Stratified water column sampling at surface, mid, turbid/plume layer, and near bottom was done along with pertinent environmental variables at various locations along the ridges. The majority of genes (~38%-41%) throughout the water column in both regions encoded for C-cycling, particularly starch degradation indicating the predominance of heterotrophy. Genes encoding for nitrate reduction and arsenic and mercury resistance were enriched in the turbid and/or near-bottom waters, suggesting a localized influence of hydrothermally derived substrates on the metabolic potential of microbial communities. Indices for microbial functional gene diversity ( = 9.18) and evenness ( = 0.90) were highest for samples from turbid waters at SWIR. Potential temperature-salinity profiles showed the presence of nutrient-rich upper circumpolar deep water (UCDW) at >2,000 m in the study areas. Principal component analysis revealed that inorganic nutrient availability largely influenced functional gene diversity in deeper waters. The study signifies that rather than hydrothermal input, nutrients brought into the region through the UCDW could have a larger impact on metabolic processes mediated by autochthonous microbial communities and consequently have implications on deep-sea productivity.IMPORTANCELittle is known about depth-wise metabolic potential of microbial communities in hydrothermally influenced Central Indian Ridge (CIR) and Southwest Indian Ridge (SWIR) waters. In the present study, a comprehensive functional gene microarray approach was used to reveal the metabolic potential and depth-wise variation in microbial functional genes along the ridges. Up to 41% of microbial functional genes at both locations encoded for C-cycling. Availability of hydrothermally derived substrates in plumes detected along the ridges triggered an increase in the abundance of genes encoding for remediation of polycyclic aromatics, nitrate reduction, and arsenic and mercury resistance. Rather than hydrothermal input, the functional gene diversity at >2,000 m was largely influenced by inorganic nutrients transported by the nutrient-rich upper circumpolar deep water. Findings of this study are expanding the existing knowledge on new sites of hydrothermal activity along CIR and SWIR and gaining insights into ecosystem functioning in the deep sea.
深海微生物群落在全球生物地球化学过程中发挥着重要作用。然而,受热液影响的中印度洋海岭(CIR)和西南印度洋海岭(SWIR)中微生物群落的深度代谢潜力仍不清楚。在本研究中,采用了一种基于功能微阵列的综合方法,以了解影响微生物群落代谢潜力的因素,以及CIR和SWIR中微生物功能基因组成的深度驱动差异。在海岭沿线的不同位置,进行了表层、中层、浑浊/羽流层和近底层的分层水柱采样,并同步测量了相关环境变量。两个区域水柱中的大多数基因(约38%-41%)编码碳循环,特别是淀粉降解,这表明异养占主导地位。编码硝酸盐还原以及抗砷和抗汞的基因在浑浊和/或近底层水域中富集,这表明热液来源的底物对微生物群落代谢潜力存在局部影响。SWIR浑浊水域样本的微生物功能基因多样性指数(=9.18)和均匀度指数(=0.90)最高。潜在温度-盐度剖面显示,研究区域中深度大于2000米处存在富含营养的上环极深层水(UCDW)。主成分分析表明,无机养分的可利用性在很大程度上影响了较深水域的功能基因多样性。该研究表明,通过UCDW带入该区域的养分对当地微生物群落介导的代谢过程可能产生更大影响,进而对深海生产力产生影响,而不是热液输入。
重要性
关于受热液影响的中印度洋海岭(CIR)和西南印度洋海岭(SWIR)水域中微生物群落的深度代谢潜力,人们了解甚少。在本研究中,采用了一种综合功能基因微阵列方法,以揭示海岭沿线微生物功能基因的代谢潜力和深度变化。两个位置高达41%的微生物功能基因编码碳循环。沿海岭检测到的羽流中热液来源底物的可利用性,引发了编码多环芳烃修复、硝酸盐还原以及抗砷和抗汞的基因丰度增加。在深度大于2000米处,功能基因多样性很大程度上受富含营养的上环极深层水输送的无机养分影响,而非热液输入。本研究结果正在拓展关于CIR和SWIR沿线热液活动新地点的现有知识,并深入了解深海生态系统功能。
