SUMMARY Renal cell cancer (RCC) is the most common type of kidney cancer, and despite therapeutic advances, mortality remains high. While there are over a dozen RCC subtypes with different genomic drivers, metabolic reprogramming is a shared feature of tumorigenesis and progression across most of the major forms of kidney cancer and represents a targetable vulnerability in RCC. Our preliminary results show that RCCs and other cancers rely on the amino acid asparagine for tumor mTORC1 activity and growth, and methods to deplete tumor asparagine levels impair cancer cell proliferation and block cancer growth. Cancers acquire asparagine through two main routes: 1) consumption from the environment, and 2) biosynthesis from aspartate via asparagine synthetase (ASNS). Over the last 5 years, we found that simultaneous reduction of tumor asparagine consumption and biosynthesis blocks growth of lung, breast, and pancreas cancers in mice. Tumor asparagine consumption can be targeted using L-Asparaginase (ASNase), which hydrolyzes serum asparagine, or dietary asparagine restriction, which reduces serum asparagine levels. Tumor asparagine biosynthesis can be targeted using metformin, which through inhibiting complex I of the electron transport chain (ETC), reduces cancer cell production of aspartate, an obligate substrate for ASNS biosynthesis of asparagine. In this renewal proposal, we will investigate kidney cancer asparagine dependency to determine whether asparagine depletion can be broadly applied to treat patients with various subtypes of RCC. We will also determine the mechanism by which asparagine is sensed in cancer cells to impact mTORC1 activity and whether asparagine depletion impacts immune cell activation within the RCC tumor microenvironment.