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Origin of biogeographically distinct ecotypes during laboratory evolution.

Jacob J ValenzuelaSelva Rupa Christinal ImmanuelJames WilsonSerdar TurkarslanMaryann RuizSean M GibbonsKristopher A HuntNejc StopnisekManfred AuerMarcin ZemlaDavid A StahlNitin S Baliga
Published in: Nature communications (2024)
Resource partitioning is central to the incredible productivity of microbial communities, including gigatons in annual methane emissions through syntrophic interactions. Previous work revealed how a sulfate reducer (Desulfovibrio vulgaris, Dv) and a methanogen (Methanococcus maripaludis, Mm) underwent evolutionary diversification in a planktonic context, improving stability, cooperativity, and productivity within 300-1000 generations. Here, we show that mutations in just 15 Dv and 7 Mm genes within a minimal assemblage of this evolved community gave rise to co-existing ecotypes that were spatially enriched within a few days of culturing in a fluidized bed reactor. The spatially segregated communities partitioned resources in the simulated subsurface environment, with greater lactate utilization by attached Dv but partial utilization of resulting H 2 by low affinity hydrogenases of Mm in the same phase. The unutilized H 2 was scavenged by high affinity hydrogenases of planktonic Mm, producing copious amounts of methane. Our findings show how a few mutations can drive resource partitioning amongst niche-differentiated ecotypes, whose interplay synergistically improves productivity of the entire mutualistic community.
Keyphrases
  • climate change
  • anaerobic digestion
  • mental health
  • healthcare
  • genome wide
  • single cell
  • mass spectrometry
  • transcription factor
  • municipal solid waste
  • dna methylation
  • capillary electrophoresis