on the hepatocyte surface and which is the main mechanism for the removal of
LDL from plasma. This observation stimulated the research for drugs that would
increase LDL receptor expression and a reduction in plasma LDL. However, to date
the main attention for the therapeutic reduction of plasma cholesterol has focussed
on the metabolic pathway, starting with acetyl CoA, which leads to its biosynthesis.
The controlling enzyme in this pathway is hydroxymethylglutaryl CoA reductase
(HMG CoA reductase):Dietary
fat
Intestine
ABCA1
BloodChylomicronsMuscle
LiverLDLRABCA1SR-BIChylomicron
remnantsFatty acids Fatty acids
Adipose
tissue
Nascent
HDLapoA–I
Cholesteryl
esterMature HDLapoBPLTP CETPLCATNascent
HDLTriglyceride
Cholesteryl esterVLDL and LDLPeripheral tissuesFree cholesterol
ABCG1NucleusABCA1 MacrophageLXRFig. 18.4Lipoprotein metabolism. The intestine absorbs dietary fat and packages it into chylomicrons that are
transported to peripheral tissues through the blood. In muscle and adipose tissues the enzyme lipoprotein
lipase breaks down the chylomicrons, and fatty acids enter these tissues. The liver takes up the chylomicron
remnants, loads lipids onto apoB and secretes VLDL that undergoes lipolysis by lipoprotein lipase to form
LDL. LDLs are taken up by LDL receptors (LDLR) on liver cells. The intestine and liver generate HDL particles
through the secretion of lipid-free apoA1. This recruits cholesterol through the action of the transporter ABCA1
forming nascent HDLs. The free cholesterol in nascent HDLs is esterified by the enzyme lecithin cholesterol
acyltransferase (LCAT) creating mature HDLs. The cholesterol in mature HDLs is returned to the liver
directly through the receptor SR-B1 and indirectly by transfer to LDLs and VLDLs through the enzyme cholesteryl
ester transfer protein (CETP). The lipid content of HDLs is also altered by the enzymes hepatic lipase and
endothelial lipase and the phospholipids transfer protein (PLTP). (Adapted from Rader, D. J. and Daugherty,
A. (2008). Translating molecular discoveries into new therapies for atherosclerosis.Nature, 451 , 904–912, by
permission of the Nature Publishing Group.)Acetyl CoA HMG CoA2NADPH + 2H+2NADPCoAFeedback inhibition (–)HMG CoA reductaseMevalonic acid CholesterolStatins®® ®®®®®721 18.2 Drug discovery