Chronic hyperosmolarity mediates constitutive expression of molecular chaperones and resistance to injury

doi:10.1152/ajprenal.00058.2002

Chronic hyperosmolarity mediates constitutive expression of molecular chaperones and resistance to injury

Bento C. Santos¹, James M. Pullman², Alejandro Chevaile¹, William J. Welch³, and Steven R. Gullans¹

¹ Department of Medicine, Brigham and Women's Hospital, Harvard Institutes of Medicine, Boston 02115; ² Department of Pathology, University of Massachusetts Medical School, Worcester, Massachusetts 01655; and ³ Department of Surgery, University of California, San Francisco, California 94143

Renal medullary cells are exposed to elevated and variable osmolarities and low oxygen tension. Despite the harsh environment,these cells are resistant to the effects of many harmful events.To test the hypothesis that this resistance is a consequence ofthese cells developing a stress tolerance phenotype to survivein this milieu, we created osmotically tolerant cells [hypertonic(HT) cells] by gradually adapting murine inner medullary collectingduct 3 cells to hyperosmotic medium containing NaCl and urea.HT cells have a reduced DNA synthesis rate, with the majorityof cells arrested in the G₀/G₁ phase of the cell cycle, and showconstitutive expression of heat shock protein 70 that is proportionalto the degree of hyperosmolarity. Unlike acute hyperosmolarity,chronic hyperosmolarity failed to activate MAPKs. Moreover, HTcells acquired protein translational tolerance to further stresstreatment, suggesting that HT cells have an osmotolerant phenotypethat is analogous to thermotolerance but is a permanent condition.In addition to osmotic shock, HT cells were more resistant toheat, H₂O₂, cyclosporin, and apoptotic inducers, compared withisotonic murine inner medullary duct 3 cells, but less resistantto amphotericin B and cadmium. HT cells demonstrate that in renalmedullary cells, hyperosmotic stress activates biological processesthat confer cross-tolerance to other stressfulconditions.

heat shock protein 70; nephrotoxins; thermotolerance; cell cycle; inner medullary collecting duct 3

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