Tolerance Patterns and Transcriptomic Response to Extreme and Fluctuating Salinities across Populations of the Intertidal Copepod Tigriopus californicus

Populations that tolerate extreme environmental conditions with frequent fluctuations can give valuable insights into physiological limits and adaptation. In some estuarine and marine ecosystems, organisms must adapt to extreme and fluctuating salinities, but not much is known about how varying salinities impact local adaptation across a wide geographic range. We used eight geographically and genetically divergent populations of the intertidal copepod Tigriopus californicus to test whether northern populations have greater tolerance to low salinity stresses, as they experience greater precipitation and less evaporation. We used a common-garden experiment approach and exposed all populations to acute low (1 and 3 ppt) and high (110 and 130 ppt) salinities for 24 h and to a fluctuation between baseline salinity and moderate low (7 ppt) and high (80 ppt) salinities for over 49 h. We also performed RNA sequencing at several time points during the fluctuation between baseline and salinity of 7 ppt to understand the molecular basis of divergence between two populations with differing physiological responses. We present these novel findings: (1) acute low salinity conditions caused more deaths than high salinity; (2) molecular processes that elevate proline levels increased in salinity of 7 ppt, which contrasts with other physiological studies in T. californicus that mainly associated accumulation of proline with hyperosmotic stress; and (3) tolerance to a salinity fluctuation did not follow a latitudinal trend but was instead governed by a complex interplay of factors, including population and duration of salinity stress. This highlights the importance of including a wider variety of environmental conditions in empirical studies to understand local adaptation.

Automated summary

The study found that acute low salinity conditions caused more deaths in Tigriopus californicus populations than high salinity; molecular processes increasing proline levels were significantly elevated at 7ppt salinity, contrary to other physiological studies; tolerance to salinity fluctuation was not determined by latitude but influenced by a complex interplay of factors including population and duration of salinity stress.