Nicotinic acid (niacin) has long been used for the treatment of lipid disorders and
cardiovascular disease. Niacin favorably affects apolipoprotein (apo) B-containing
lipoproteins (eg, very-low-density lipoprotein [VLDL], low-density lipoprotein [LDL],
lipoprotein[a]) and increases apo A-I-containing lipoproteins (high-density lipoprotein
[HDL]). Recently, new discoveries have enlarged our understanding of the mechanism
of action of niacin and challenged older concepts. There are new data on (1) how niacin
affects triglycerides (TGs) and apo B-containing lipoprotein metabolism in the liver,
(2) how it affects apo A-I and HDL metabolism, (3) how it affects vascular anti-inflammatory
events, (4) a specific niacin receptor in adipocytes and immune cells, (5) how niacin
causes flushing, and (6) the characterization of a niacin transport system in liver
and intestinal cells. New findings indicate that niacin directly and noncompetitively
inhibits hepatocyte diacylglycerol acyltransferase-2, a key enzyme for TG synthesis.
The inhibition of TG synthesis by niacin results in accelerated intracellular hepatic
apo B degradation and the decreased secretion of VLDL and LDL particles. Previous
kinetic studies in humans and recent in vitro cell culture findings indicate that
niacin retards mainly the hepatic catabolism of apo A-I (vs apo A-II) but not scavenger
receptor BI-mediated cholesterol esters. Decreased HDL-apo A-I catabolism by niacin
explains the increases in HDL half-life and concentrations of lipoprotein A-I HDL
subfractions, which augment reverse cholesterol transport. Initial data suggest that
niacin, by inhibiting the hepatocyte surface expression of beta-chain adenosine triphosphate
synthase (a recently reported HDL-apo A-I holoparticle receptor), inhibits the removal
of HDL-apo A-I. Recent studies indicate that niacin increases vascular endothelial
cell redox state, resulting in the inhibition of oxidative stress and vascular inflammatory
genes, key cytokines involved in atherosclerosis. The niacin flush results from the
stimulation of prostaglandins D(2) and E(2) by subcutaneous Langerhans cells via the
G protein-coupled receptor 109A niacin receptor. Although decreased free fatty acid
mobilization from adipose tissue via the G protein-coupled receptor 109A niacin receptor
has been a widely suggested mechanism of niacin to decrease TGs, physiologically and
clinically, this pathway may be only a minor factor in explaining the lipid effects
of niacin.