Caenorhabditis elegans OSR-1 Regulates Behavioral and Physiological Responses to Hyperosmotic Environments

doi:10.1534/genetics.167.1.161

Caenorhabditis elegans OSR-1 Regulates Behavioral and Physiological Responses to Hyperosmotic Environments

Aharon Solomon^a, Sricharan Bandhakavi^a, Sean Jabbar^a, Rena Shah^a, Greg J. Beitel^a, and Richard I. Morimoto^a
^a Department of Biochemistry, Molecular Biology and Cell Biology, Rice Institute for Biomedical Research, Northwestern University, Evanston, Illinois 60208

Corresponding author: Richard I. Morimoto, Molecular Biology, and Cell Biology, Northwestern University, 2205 Tech Dr., Hogan 2-100, Evanston, IL 60208-3500., r-morimoto{at}northwestern.edu (E-mail)

Communicating editor: B. J. MEYER

The molecular mechanisms that enable multicellular organismsto sense and modulate their responses to hyperosmotic environmentsare poorly understood. Here, we employ Caenorhabditis elegansto characterize the response of a multicellular organism toosmotic stress and establish a genetic screen to isolate mutantsthat are osmotic stress resistant (OSR). In this study, we describethe cloning of a novel gene, osr-1, and demonstrate that itregulates osmosensation, adaptation, and survival in hyperosmoticenvironments. Whereas wild-type animals exposed to hyperosmoticconditions rapidly lose body volume, motility, and viability,osr-1(rm1) mutant animals maintain normal body volume, motility,and viability even upon chronic exposures to high osmolarityenvironments. In addition, osr-1(rm1) animals are specificallyresistant to osmotic stress and are distinct from previouslycharacterized osmotic avoidance defective (OSM) and generalstress resistance age-1(hx546) mutants. OSR-1 is expressed inthe hypodermis and intestine, and expression of OSR-1 in hypodermalcells rescues the osr-1(rm1) phenotypes. Genetic epistasis analysisindicates that OSR-1 regulates survival under osmotic stressvia CaMKII and a conserved p38 MAP kinase signaling cascadeand regulates osmotic avoidance and resistance to acute dehydrationlikely by distinct mechanisms. We suggest that OSR-1 plays acentral role in integrating stress detection and adaptationresponses by invoking multiple signaling pathways to promotesurvival under hyperosmotic environments.

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