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Rapid plant trait evolution can alter coastal wetland resilience to sea level rise.

Megan L VahsenMichael J BlumJames Patrick MegonigalScott J EmrichJames R HolmquistB StillerKatherine Todd-BrownJason S McLachlan
Published in: Science (New York, N.Y.) (2023)
Rapid evolution remains a largely unrecognized factor in models that forecast the fate of ecosystems under scenarios of global change. In this work, we quantified the roles of heritable variation in plant traits and of trait evolution in explaining variability in forecasts of the state of coastal wetland ecosystems. A common garden study of genotypes of the dominant sedge Schoenoplectus americanus , "resurrected" from time-stratified seed banks, revealed that heritable variation and evolution explained key ecosystem attributes such as the allocation and distribution of belowground biomass. Incorporating heritable trait variation and evolution into an ecosystem model altered predictions of carbon accumulation and soil surface accretion (a determinant of marsh resilience to sea level rise), demonstrating the importance of accounting for evolutionary processes when forecasting ecosystem dynamics.
Keyphrases
  • climate change
  • genome wide
  • human health
  • wastewater treatment
  • gene expression
  • dna methylation
  • social support
  • depressive symptoms
  • plant growth
  • water quality