<p>Solar salt pans are extreme hypersaline environments that represent functionally specialised microbial communities mediating essential biogeochemical transformation. Vedaranyam, a coastal region of the Bay of Bengal containing artificially constructed solar salterns for salt production. There is limited information available on the metagenome diversity and functional profiling of this saltpan, which prompted us to investigate it. Here, we report the first whole metagenome sequencing to explore the dynamics of the functional structure of microbial communities in saltpan during the preharvest and postharvest phases of salt production. <i>Methanobacteriota</i> and <i>Pseudomonadota</i> dominated both phases at the phylum level, while <i>Halobacteria</i> comprised the most abundant class (53.2% preharvest; 48% postharvest). A notable bloom of <i>Dactylococcopsis salina</i> was observed during postharvest (4.28% to 12.67%) and flock doubling of <i>Cyanobacterota</i> relative abundance (5.5% to 10.6%), reflecting photosynthetic primary production following salt removal. Conversely, during postharvest phase sulfur oxidising <i>Guyparkeria halophila</i> reduced 23 fold, while the DMSP accumulating osmolyte producer <i>Salinibaculum marinum</i> dominated preharvest (6.98%). However, functional classification of the metagenome revealed active participation of the microbial community across five major biogeochemical cycles. Encompassing carbon fixation by <i>cyanobacteria</i> and diverse haloarchaea, nitrogen cycling through diazotrophy and denitrification, a cryptic preharvest sulfur cycle coupling sulfate reduction and sulphide oxidation, phase shifted DMSP catabolism, and light driven bacteriorhodopsin through archaeal energy conservation. Metagenomic assembly yielded ten metagenomic assembled genomes (MAGs), revealing the taxonomic diversity and metabolic potential of the dominant halophilic community across biogeochemical cycles. These results provide critical insights into the ecological succession from an anaerobic, chemolithotrophy-rich preharvest microbial community to an aerobic, photosynthetically driven postharvest assemblage, advancing our understanding of microbial biogeochemistry in managed hypersaline ecosystems.</p> Graphical Abstract <p></p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Unravelling Extremophilic Microbiome Diversity and Functional Dynamics in Hypersaline Environment

  • Steffy Joseph,
  • L. Stanley Abraham,
  • Krishnamanikumar Premachandran,
  • Antony V Samrot,
  • R. Thirugnanasambandam,
  • K. Ragavendhar,
  • Hissah Abdulrahman Alodaini,
  • Nadine MS Moubayed,
  • Ashraf Atef Hatamleh,
  • Ravishankar Ram Mani,
  • Soon Woong Chang,
  • Balasubramani Ravindran

摘要

Solar salt pans are extreme hypersaline environments that represent functionally specialised microbial communities mediating essential biogeochemical transformation. Vedaranyam, a coastal region of the Bay of Bengal containing artificially constructed solar salterns for salt production. There is limited information available on the metagenome diversity and functional profiling of this saltpan, which prompted us to investigate it. Here, we report the first whole metagenome sequencing to explore the dynamics of the functional structure of microbial communities in saltpan during the preharvest and postharvest phases of salt production. Methanobacteriota and Pseudomonadota dominated both phases at the phylum level, while Halobacteria comprised the most abundant class (53.2% preharvest; 48% postharvest). A notable bloom of Dactylococcopsis salina was observed during postharvest (4.28% to 12.67%) and flock doubling of Cyanobacterota relative abundance (5.5% to 10.6%), reflecting photosynthetic primary production following salt removal. Conversely, during postharvest phase sulfur oxidising Guyparkeria halophila reduced 23 fold, while the DMSP accumulating osmolyte producer Salinibaculum marinum dominated preharvest (6.98%). However, functional classification of the metagenome revealed active participation of the microbial community across five major biogeochemical cycles. Encompassing carbon fixation by cyanobacteria and diverse haloarchaea, nitrogen cycling through diazotrophy and denitrification, a cryptic preharvest sulfur cycle coupling sulfate reduction and sulphide oxidation, phase shifted DMSP catabolism, and light driven bacteriorhodopsin through archaeal energy conservation. Metagenomic assembly yielded ten metagenomic assembled genomes (MAGs), revealing the taxonomic diversity and metabolic potential of the dominant halophilic community across biogeochemical cycles. These results provide critical insights into the ecological succession from an anaerobic, chemolithotrophy-rich preharvest microbial community to an aerobic, photosynthetically driven postharvest assemblage, advancing our understanding of microbial biogeochemistry in managed hypersaline ecosystems.

Graphical Abstract