A Newly Identified Protective Role of C5a Receptor 1 in Kidney Tubules against Toxin-Induced Acute Kidney Injury

Abstract

Acute kidney injury (AKI) remains a major reason for hospitalization with limited therapeutic options. While complement activation is implicated in AKI, the role of C5a receptor 1 (C5aR1) in kidney tubular cells is unclear. We used aristolochic acid nephropathy (AAN) and folic acid nephropathy (FAN) models to establish the role of C5aR1 in kidney tubules during AKI in germline C5ar1-/- mice, myeloid cell-specific, and kidney tubule-specific C5ar1 knockout mice. After aristolochic acid and folic acid injection, C5ar1-/- mice had increased AKI severity and a higher degree of tubular injury. Macrophage depletion in C5ar1-/- mice or myeloid cell-specific C5ar1 deletion did not affect the outcomes of AA-induced AKI. RNA-sequencing data from RTECs showed that C5ar1 deletion was associated with the downregulation of mitochondrial metabolism and ATP production transcriptional pathways. Metabolic studies confirmedreduced mitochondrial membrane potential at baseline and increased mitochondrial oxidative stress after injury in C5ar1-/- RTECs. Moreover, C5ar1-/- RTECs had enhanced glycolysis, glucose uptake, and lactate production upon injury, corroborated by metabolomics analysis of kidneys from AAN mice. Kidney tubule-specific C5ar1 knockout mice recapitulated exacerbated AKI observed in C5ar1-/- mice in AAN and FAN. Our data indicate that C5aR1 signaling in kidney tubules exerts renoprotective effects against toxin-induced AKI by limiting overt glycolysis and maintaining mitochondrial function, revealing a novel link between the complement system and tubular cell metabolism.