Heme-Oxygenase 1 Mediated Activation of Cyp3A11 Protects Against Non-Steroidal Pain Analgesics Induced Acute Liver Damage in Sickle Cell Disease Mice

Pain constitutes a significant comorbidity associated with sickle cell disease (SCD). Analgesics serve as the primary method for pain management; however, the long-term effects of these drugs on the liver of SCD patients remain not completely understood. Using real-time intravital imaging, we analyzed the effect of non-steroidal analgesics (NSA) in the liver of control and SS (SCD) mice. Remarkably, we found completely opposing effects in the liver of control and SS mice post-NSA treatment. Whereas SS mice were able to better tolerate the NSA treatment acutely compared to their littermate controls, in the long term, these mice showed delayed resolution of liver injury and exacerbated fibrosis compared to control mice. Mechanistically, we found that SS mice were protected from cytotoxicity caused by NSA at baseline due to the significant activation of hepatic Kupffer cells, which produced heme-oxygenase 1 (HO-1). HO-1 promoted the activation of the cytoprotective enzyme Cyp3A11, which inhibited hepatic damage caused by NSA. However, in the long term, depletion of hepatic Kupffer cells led to reduced expression of HO-1, which blocked the activation of Cyp3A11, resulting in fibrosis and a delay in the resolution of liver injury and inflammation. These preclinical data provide a strong proof-of-concept for HO-1 as well as Cyp3A11 as cytoprotectors against NSA-induced liver damage in the Townes model of SCD and support further development of these compounds as potential novel therapies for end-organ damage in SCD.