Proprotein convertase subtilisin/kexin type 9 (PCSK9) affects gene expression pathways beyond cholesterol metabolism in liver cells.

Proprotein convertase subtilisin/kexin type 9 (PCSK9) induces degradation of low-density lipoprotein receptor (LDLR) in the liver. It is being pursued as a therapeutic target for LDL-cholesterol reduction. Earlier genome-wide gene expression studies showed that PCSK9 over-expression in HepG2 cells resulted in up-regulation of genes in cholesterol biosynthesis and down-regulation of genes in stress response pathways; however, it was not known whether these changes were directly regulated by PCSK9 or were secondary to PCSK9-induced changes to the intracellular environment. In order to further understand the biological function of PCSK9 we treated HepG2 cells with purified recombinant wild type (WT) and D374Y gain-of-function PCSK9 proteins for 8, 24, and 48 h, and used microarray analysis to identify genome-wide expression changes and pathways. These results were compared to the changes induced by culturing HepG2 cells in cholesterol-free medium, mimicking the intracellular environment of cholesterol starvation. We determined that PCSK9-induced up-regulation of cholesterol biosynthesis genes resulted from intracellular cholesterol starvation. In addition, we identified novel pathways that are presumably regulated by PCSK9 and are independent of its effects on cholesterol uptake. These pathways included "protein ubiquitination," "xenobiotic metabolism," "cell cycle," and "inflammation and stress response." Our results indicate that PCSK9 affects metabolic pathways beyond cholesterol metabolism in HepG2 cells.

Human NPC1L1 and NPC1 can functionally substitute for the ncr genes to promote reproductive development in C. elegans.

The NPC1 and NPC1L1 are related genes whose general role is in cholesterol trafficking. However, reduction of activity of these genes results in very different phenotypes. Niemann-Pick C disease type 1 is a neurodegenerative disease with no current treatment, where cholesterol accumulates in lysosomes. The disease arises due to autosomal recessive mutations in the NPC1 gene. The NPC1L1 gene has recently been identified as the target for the drug ezetimibe (Zetia), a cholesterol absorption inhibitor, and has been shown to be an intestinal cholesterol transporter. We demonstrate that human NPC1L1, as well as human NPC1, can functionally substitute for the Caenorhabditis elegans genes ncr-1 and/or ncr-2. These genes are known to play a role in the process of dauer formation, a process which can be modulated by cholesterol in sensitized genetic backgrounds. Our results demonstrate that these human proteins retain some functional conservation, though their biological roles are vastly different.

The target of ezetimibe is Niemann-Pick C1-Like 1 (NPC1L1).

Ezetimibe is a potent inhibitor of cholesterol absorption that has been approved for the treatment of hypercholesterolemia, but its molecular target has been elusive. Using a genetic approach, we recently identified Niemann-Pick C1-Like 1 (NPC1L1) as a critical mediator of cholesterol absorption and an essential component of the ezetimibe-sensitive pathway. To determine whether NPC1L1 is the direct molecular target of ezetimibe, we have developed a binding assay and shown that labeled ezetimibe glucuronide binds specifically to a single site in brush border membranes and to human embryonic kidney 293 cells expressing NPC1L1. Moreover, the binding affinities of ezetimibe and several key analogs to recombinant NPC1L1 are virtually identical to those observed for native enterocyte membranes. KD values of ezetimibe glucuronide for mouse, rat, rhesus monkey, and human NPC1L1 are 12,000, 540, 40, and 220 nM, respectively. Last, ezetimibe no longer binds to membranes from NPC1L1 knockout mice. These results unequivocally establish NPC1L1 as the direct target of ezetimibe and should facilitate efforts to identify the molecular mechanism of cholesterol transport.

The Caenorhabditis elegans homolog of the putative prostate cancer susceptibility gene ELAC2, hoe-1, plays a role in germline proliferation.

The potential prostate cancer susceptibility gene ELAC2 has a Caenorhabditis elegans homolog (which we call hoe-1, for homolog of ELAC2). We have explored the biological role of this gene using RNAi to reduce gene activity. We found that worms subjected to hoe-1 RNAi are slow-growing and sterile. The sterility results from a drastic reduction in germline proliferation and cell-cycle arrest of germline nuclei. We found that hoe-1 is required for hyperproliferation phenotypes seen with mutations in three different genes, suggesting hoe-1 may be generally required for germline proliferation. We also found that reduction of hoe-1 by RNAi suppresses the multivulva (Muv) phenotype resulting from activating mutations in ras and that this suppression is likely to be indirect. This is the first demonstration of a biological role for this class of proteins in a complex eukaryote and adds important information when considering the role of ELAC2 in prostate cancer.