PROJECT SUMMARY Acute kidney injury (AKI) is a major health problem, afflicting 1.2 million hospitalized patients annually in the US. Maladaptive renal repair after AKI promotes development of chronic kidney disease (CKD), leaving affected patients at high risk for dialysis dependency, cardiovascular events, and mortality. Studies show that males are disproportionately and more severely affected by AKI than females, including COVID-19-associated AKI. However, the molecular mechanisms underlying this sexual dimorphism remain poorly understood. Moreover, there are no targeted therapies that interrupt this devastating disease process in both sexes. Using single-cell transcriptomics and mouse genetics, our ongoing studies found that the female sex confers marked protection against ferroptosis, a distinct, non-apoptotic form of regulated cell death and a critical driver of maladaptive repair after AKI in mice and humans. Ferroptosis is triggered by the inability of glutathione peroxidase 4 (GPX4) to remove toxic lipid peroxides from cell membranes, leading to the accelerated accumulation of toxic lipid peroxides (ferroptotic stress) and cell rupture. Acute ischemic and toxic kidney injuries reduce GPX4 in proximal tubular (PT) cells, thus making these cells vulnerable to ferroptosis. Severe AKI also induces pathologic transcriptional alteration of PT cells into an inflammatory phenotype and prevents their recovery to a healthy state (impaired plasticity). Our data show that in males but not in females, genetic deletion of Gpx4 promotes the accumulation of inflammatory PT cells and triggers their death by ferroptosis. To advance these clinically impactful lines of investigation, we will test our overarching hypothesis that sexual dimorphism in resilience to ferroptosis underlies sex differences in clinical outcomes after AKI. We further hypothesize that uncovering the mechanisms of how sex hormones regulate ferroptosis sensitivity will enable identification of targetable downstream pathways that improve AKI outcomes for both sexes. Directly testing these hypotheses, we will integrate unbiased single-cell transcriptomics, genetic mouse models, pharmacological studies, and human kidney organoids with two Specific Aims. In Aim 1, we will determine sex-dependent mechanisms by which ferroptosis promotes maladaptive repair at single-cell resolution using our tubule-specific, doxycycline-inducible Gpx4 knockout mouse model. We will also investigate the therapeutic effects of ferroptosis inhibitors to enhance renal repair in our murine kidney injury models in vivo and in human in vitro AKI models using organoids. In Aim 2, we will test our hypothesis that sex hormones regulate the sensitivity to ferroptosis and PT cell plasticity after AKI using gonadectomy and genetic inhibition of estrogen receptor signaling. The results of these studies will provide compelling preclinical mechanistic evidence for how ferroptotic stress governs PT cell fate. Our studies will...