SIK2 Is Involved in the Negative Modulation of Insulin-Dependent Muller Cell Survival and Implicated in Hyperglycemia-Induced Cell Death

Abstract

PURPOSE. To investigate the role of the serine/threonine kinase SIK2, a member of the saltinducible kinase (SIK) family, in insulin-dependent cell survival and hyperglycemia-induced cell death in Muller glia. METHODS. Expression studies were performed by RT-PCR, immunostaining, Northern blotting, and immunoblotting. Insulin-dependent changes in SIK2 activity were investigated by in vitro kinase assays in MIO-M1 Muller cell line. Akt activation was studied by immunoblotting and cell death by TUNEL assay. The potential role of SIK2 in insulin signaling was explored by overexpression and sh-RNA knock-down approaches. Effects of hyperglycemia were studied in vitro and in vivo in streptozotocin-injected rats. RESULTS. SIK2 expression was detected throughout adult retina, except for the outer nuclear layer. Insulin stimulation of MIO-M1 cells resulted in a rapid 2-fold increase of SIK2 activity, increased insulin receptor substrate 1 (IRS1)-SIK2 interaction, and reduced cell death. pAkt levels following insulin treatment were modulated by SIK2 activity. Under hyperglycemia, increased SIK2 activity/expression was concomitant to decreased Akt activation and enhanced apoptosis; whereas knockdown of SIK2 under normo-and hyperglycemic conditions resulted in a rapid increase in pAkt levels and blunted cell death. SIK2 overexpression under normoglycemia had an opposite effect. SIK2 activity increased significantly within 2 weeks of induction of hyperglycemia in the rat retina. CONCLUSIONS. Results indicate that SIK2 functions as a negative modulator of the insulindependent survival pathway and contributes to hyperglycemia-induced cell death of Muller glia in vitro. Although still hypothetical at this point, our study suggests that SIK2 could serve a similar role during the development of diabetic retinopathy in vivo and that it represents a potential target to control disease progression.