Regulation of cellular LDL uptake by PROX1 and CHD7

Abstract

AbstractAn elevated level of low-density lipoprotein (LDL) in the bloodstream is a causal risk factor for atherosclerotic cardiovascular disease (ASCVD). The low-density lipoprotein receptor (LDLR) is a critical regulator of circulating LDL, and increasing LDLR activity is an effective therapeutic approach to reduce circulating LDL cholesterol levels. In this study, we characterize PROX1 and CHD7, two genes we previously identified in a genome-scale CRISPR screen as positive regulators of LDL uptake in HuH7 cells. We found that although disruption of either PROX1 or CHD7 significantly reduced LDL uptake, only PROX1 disruption significantly reduced the cellular levels of LDLR mRNA and surface-displayed LDLR protein. Consistent with a direct role for PROX1 in LDLR gene regulation, we also observed in publicly available data sets the presence of two liver-specific PROX1 binding sites near the LDLR locus, one of which colocalized with biochemical hallmarks of enhancer activity in hepatic tissue. Both PROX1 LDLR binding sites contained predicted PROX1 transcription factor binding motifs and colocalized with binding sites for HNF4α, a known interactor for PROX1 and regulator of hepatic lipid metabolism and LDL uptake. In contrast to PROX1, no CHD7 binding sites were detected near the LDLR locus. Together, our results support a model in which both PROX1 and CHD7 promote cellular LDL uptake through distinct mechanisms, with PROX1 directly promoting LDLR gene expression and CHD7 functioning through an LDLR-independent pathway.