Abstract
Rapid fluctuation of environmental conditions can impose severe stress upon living organisms. Surviving such episodes of stress requires a rapid acclimation response, e.g., by transcriptional and post-transcriptional mechanisms. Persistent change of the environmental context, however, requires longer-term adaptation at the genetic level. Fast-growing unicellular aquatic eukaryotes enable analysis of adaptive responses at the genetic level in a laboratory setting. In this study, we applied continuous cold stress (28°C) to the thermoacidophile red alga G. sulphuraria, which is 14°C below its optimal growth temperature of 42°C. Cold stress was applied for more than 100 generations to identify components that are critical for conferring thermal adaptation. After cold exposure for more than 100 generations, the cold-adapted samples grew ∼30% faster than the starting population. Whole-genome sequencing revealed 757 variants located on 429 genes (6.1% of the transcriptome) encoding molecular functions involved in cell cycle regulation, gene regulation, signaling, morphogenesis, microtubule nucleation, and transmembrane transport. CpG islands located in the intergenic region accumulated a significant number of variants, which is likely a sign of epigenetic remodeling. We present 20 candidate genes and three putative cis-regulatory elements with various functions most affected by temperature. Our work shows that natural selection toward temperature tolerance is a complex systems biology problem that involves gradual reprogramming of an intricate gene network and deeply nested regulators.
Highlights
Small changes in average global temperature significantly affect the species composition of ecosystems
During the 240 days of this experiment, a total of 181 generations of G. sulphuraria RT22 were obtained for the culture grown at 42◦C, whereas 102 generations were obtained for G. sulphuraria RT22 grown at 28◦C
Perhaps G. sulphuraria RT22, which originated from the Rio Tinto river near Berrocal (Spain), may be able to thrive at high temperatures, but not for such a prolonged period
Summary
Small changes in average global temperature significantly affect the species composition of ecosystems. 252 Ma years ago up to ∼95% of marine species and ∼70% of terrestrial vertebrates ceased to exist (Benton, 2008; Sahney and Benton, 2008) This event, known as the Permian–Triassic extinction, was triggered by a sharp increase in worldwide temperature (+8◦C) and CO2 concentrations (+2000 ppm) during a period spanning 48,000–60,000 years (McElwain and Punyasena, 2007; Shen et al, 2011; Burgess et al, 2014). Higher temperatures and CO2 concentrations result in increased seawater acidity, increased UV radiation, Microevolution to Cold Temperatures and changes in oceanwide water circulation and upwelling patterns. Aquatic unicellular eukaryotes are well-suited to addressing this question due to their short generation time and straightforward temperature control of their growth environment
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