CPT1a Controls the Function of Long-Term Hematopoietic Stem Cells By Regulating the Balance between Fatty Acid Oxidation and Oxphos in Mitochondria

Abstract

Hematopoietic stem cells (HSCs) rely on the balance in place of quiescence and self-renewal to sustain stem cell potential and differentiation to generate mature blood cells. Appropriate regulation of cellular and mitochondrial metabolic processes such as glycolysis, OXPHOS, fatty acid metabolism, and amino acid metabolism are required for HSC maintenance. However, the mechanisms by which cellular and mitochondrial metabolisms regulate HSC quiescence, proliferation, and differentiation remain to be fully understood. Fatty acid oxidation (FAO) is a metabolic process involving the breakdown of fatty acids into acetyl-CoA, which is then transported into mitochondria by carnitine palmitoyltransferase 1a (CPT1a). It has been reported that inhibiting FAO using non-specific inhibitors of CPT1a impairs HSC maintenance. Interestingly, CPT1a forms a complex with the Fanconi anemia complementation group D2 (FANCD2) protein (T Zhang et al., Scientific Reports, 2017). Given that Fanconi anemia is associated with HSC defects, this CPT1a complex may play a critical role in maintaining fatty acid dependent mitochondrial metabolism that mediates HSC dormancy and stemness. However, the exact role, in HSCs, of mitochondrial CPT1a, the rate-limiting enzyme in FAO, remains unknown. Here, we find that CPT1a is highly enriched in hematopoietic stem cells. Further, we investigated the role of CPT1a in hematopoiesis utilizing a CPT1aconditional knockout in mice driven by Vav1-Cre. The CPT1a knockout ( Cpt1a Δ/Δ) displays profound HSC defects, including loss of HSC self-renewal and accelerated differentiation. Mechanistically, we find that loss of Cpt1a results in increased ATP production, mitochondrial membrane potential (Δφm), and mitochondrial ROS accumulation in long-term HSCs (LT-HSCs), as well as defective LT-HSC function indicated by bone marrow transplantation and 5-FU genotoxic stress assays. Furthermore, utilizing mitochondrial complex formation assays and measurements of mitochondrial complex activity, BM cells of Cpt1a Δ/Δ mice display enhanced mitochondrial complex formation and up-regulation of mitochondrial complex activity. Our results suggest that Cpt1a regulates FAO transport and that loss of Cpt1a deregulates mitochondrial metabolisms including oxidative phosphorylation (OXPHOS). Taken together, our study suggests that CPT1a plays a key role in LT-HSC maintenance by controlling the balance between FAO and OXPHOS in mitochondria. Because of the noncanonical relationship between CPT1a and FANCD2 for the regulation of mitochondrial metabolism, correction of fatty acid metabolism and OXPHOS may present a novel therapeutic avenue for Fanconi anemia.