Along the east coast of North America, mummichogs (Fundulus heteroclitus) are subjected to a broad range of salinities in their nearshore habitats. However, there is a paucity of information regarding the molecular and cellular processes that mummichogs (and other highly osmotolerant fishes) engage to survive environmental salinities greater than seawater (SW). To reveal branchial processes underlying their extraordinarily broad salinity tolerance, we performed an RNA-Seq analysis to identify differentially expressed genes (DEGs) in mummichogs residing in 3, 35, and 105 ppt conditions. We identified a series of DEGs previously associated with both freshwater (FW)- and SW-type ionocytes; however, the heightened expression of anoctamin 1a, a Ca2+-activated Cl- channel, in 35 and 105 ppt indicates that an undescribed Cl--secretion pathway may operate within the SW-type ionocytes of mummichogs. Concerning FW-adaptive branchial processes, we identified claudin 5a as a gene whose product may limit the diffusive loss of ions between cellular tight junctions. Further, in response to hypersaline conditions, we identified DEGs linked with myo-inositol synthesis and kinase signaling. This study provides new molecular targets for future physiological investigations that promise to reveal the mechanistic bases for how mummichogs and other euryhaline species tolerate hypersaline conditions.
Keywords: Anoctamin 1; Atlantic killifish; Freshwater; Gill; Ionocytes; Osmoregulation; RNA-Seq; Seawater.
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