Chronic kidney diseases affect more than 700 million people worldwide, and are a frequent cause of kidney failure and death. A key event leading to kidney failure is filter damage, caused by the loss of podocytes. This is a cause of a kidney disease known as Focal segmental Glomerulosclerosis (FSGS). Despite the growing prevalence of kidney diseases, there are currently no FDA approved therapies to prevent the loss of podocytes. The goal of this grant application is to gain a deep understanding of the molecular mechanisms involved in podocyte injury related to the BRAF signaling pathway, so that it may be targeted for therapeutic benefit. We started with a rare genetic kidney disease caused by mutations in an enzyme called PDSS2. Interestingly, we found that the loss of function of this enzyme causes podocytes to die, resulting in FSGS. We subsequently found that a key molecule in preventing podocyte death is BRAF and a small molecule that activates BRAF, called GDC-0879, can protect podocytes from cell death. In fact, GDC-0879 was able to protect podocytes from several injuries including toxic lipids and other stress-causing molecules. Most excitingly, we now have evidence that GDC-0879 protects mice from podocyte injury and the resulting kidney filter damage (called proteinuria). Here, we will explore the precise molecular mechanisms involved in BRAF-related podocyte injury, and the potential for GDC-0879 to become a treatment for FSGS. Successful completion of this work may provide a new, much needed treatment for FSGS and chronic kidney diseases, and one that may be easily brought to the clinic, since GDC-0879 is already an FDA approved drug for other indications.
The goal of this grant application is to gain a deep understanding of the molecular mechanisms involved in podocyte injury mediated by BRAF signaling, and to harness these insights for the development of much needed, targeted therapies for prevalent forms of FSGS.
Showing the most recent 10 out of 14 publications
