Podocytes are highly specialized and terminally differentiated glomerular cells that play a vital role in renal physiology, including the prevention of proteinuria. Cyclin-dependent kinase 5 (CDK5) has been shown to influence several cellular processes in other terminally differentiated cells, in particular neurons. In this study, we examined the role of CDK5 in podocyte differentiation, proliferation, and morphology. In conditionally immortalized mouse podocytes in culture, CDK5 increased in association with podocyte differentiation. During mouse glomerulogenesis in vivo, CDK5 expression was predominantly detected in podocytes from the capillary loop stage to maturation and persisted in the podocytes of adult glomeruli. In contrast, CDK5 was markedly decreased in the proliferating and dedifferentiated podocytes of mice with anti-glomerular basement membrane nephritis and in human immunodeficiency virus transgenic mice. p35, the activator of CDK5, was also detected in podocytes and the p35/CDK5 complex was active. Cell fractionation studies showed that active p35/ CDK5 was mainly localized to the plasma membrane. Specific inhibition of CDK5 in differentiated cultured podocytes, either pharmacologically or with siRNA, induced shape changes, with cellular elongation and loss of process formation compared to the characteristic arborized phenotype. These data suggest a role for CDK5 as a regulator of podocyte differentiation, proliferation, and morphology. 1 Injury to podocytes is associated with proteinuria and progressive glomerulosclerosis. Podocytes derive from epithelial cells originating in the metanephric mesenchyme, which develop into postmitotic terminally differentiated cells, 3 and therefore have similarities to neurons. 4 During glomerulogenesis, podocytes proliferate until the S-shape body stage, and exit the cell cycle at the capillary loop stage. 5,6 Podocytes then acquire their fully differentiated phenotype, a process that in the mouse is not complete until 1 week after birth. Mature podocytes tightly regulate and maintain their quiescent and differentiated phenotype, and therefore the majority of diseases involving podocytes are not associated with proliferation and an increase in cellularity. Indeed, studies have shown that the inability to proliferate contributes to glomerular scarring. 7 In contrast, podocytes may dedifferentiate, and proliferate, in human immunodeficiency virus (HIV)-associated nephropathy, which is characterized by a rapid decline in renal function, emphasizing the importance of podocyte quiescence for glomerular function. 8 These studies show that the state of podocyte differentiation is closely linked with its proliferative potential. Studies have also shown that podocyte morphology is critical for normal function. 9,10 After injury, flattening and effacement of podocytes leads to loss of normal function.
