AI Article Synopsis
- Scientists are trying to understand how plants and animals adapt to different environments and how their genes affect their chances of survival.
- They studied two groups of plants from Italy and Sweden to see how a specific gene affected their ability to survive cold temperatures.
- They found that changes in this gene made survival harder, especially in Sweden, where plants survived less than before, showing that adapting to cold has its costs, especially with climate change happening.
Article Abstract
Identifying the genetic basis of local adaptation and fitness trade-offs across environments is a central goal of evolutionary biology. Cold acclimation is an adaptive plastic response for surviving seasonal freezing, and costs of acclimation may be a general mechanism for fitness trade-offs across environments in temperate zone species. Starting with locally adapted ecotypes of from Italy and Sweden, we examined the fitness consequences of a naturally occurring functional polymorphism in . This gene encodes a transcription factor that is a major regulator of cold-acclimated freezing tolerance and resides within a locus responsible for a genetic trade-off for long-term mean fitness. We estimated the consequences of alternate genotypes of on 5-y mean fitness and fitness components at the native field sites by comparing near-isogenic lines with alternate genotypes of to their genetic background ecotypes. The effects of were validated at the nucleotide level using gene-edited lines in the native genetic backgrounds grown in simulated parental environments. The foreign genotype in the local genetic background reduced long-term mean fitness in Sweden by more than 10%, primarily via effects on survival. In Italy, fitness was reduced by more than 20%, primarily via effects on fecundity. At both sites, the effects were temporally variable and much stronger in some years. The gene-edited lines confirmed that encodes the causal variant underlying this genetic trade-off. Additionally, we demonstrated a substantial fitness cost of cold acclimation, which has broad implications for potential maladaptive responses to climate change.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10861903 | PMC |
| http://dx.doi.org/10.1073/pnas.2317461121 | DOI Listing |
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