LAUSR

Water temperature is one of the key environmental factors for marine ectotherms and a change in temperature beyond and organism's capacity limits can cause a series of changes to physiological state and damage to the organism. Understanding how organisms adapt to complex environments is a central goal of evolutionary biology and ecology. Ruditapes philippinarum is an ecologically and scientifically important marine bivalve species. To uncover the molecular mechanisms of acclimation of R. philippinarum to low‐temperature stress, iTRAQ‐based quantitative proteomics was conducted to compare the proteomes of the north and south populations of R. philippinarum under low‐temperature stress. The results showed a total of 6355 and 6352 proteins were identified in two populations, respectively. Among these, 94 and 83 were differentially abundant proteins (DAPs), and most of DAPs were related to oxidation‐process, protein binding, or an integral component of membrane. According to the results of KEGG pathway enrichment analysis, most of DAPs in both populations are involved in immune‐related pathways, while other population‐specific significant abundance proteins of south population and north population were enriched in biosynthesis of amino acids (Enolase, Glutamine synthetase) and unsaturated fatty acids pathways (3‐ketoacyl‐CoA thiolase, Stearoyl‐CoA desaturase), respectively, indicating that two population of clams may have different cold‐stress regulation mechanisms. Our study provides new insights into different cold stress tolerance mechanisms in northern and southern populations of R. philippinarum using iTRAQ‐based proteomics. This work contributes to a better understanding of molecular basis on cold stress response and adaptations, which shed lights on evolutionary biology and general ecophysiology of R. philippinarum.