Abstract
In spite of much progress in understanding the mechanisms of lipoprotein metabolism at the cellular level, much less is known quantitatively about what actually occurs in vivo. A new tool for understanding the catabolic fates of lipoproteins in vivo is the use of noncatabolizable ligands for labeling proteins. These ligands are incorporated into cells with the labeled protein. The protein is catabolized but the ligand remains intact and trapped at the sites of hydrolysis as a cumulative marker of the extent of protein uptake. This tool was first applied to LDL in pigs, rats, and rabbits. In all three, hepatic catabolism predominated. Adrenal gland was the most active per unit wet weight. The trapped label methodology was also applied to the apoA-I component of HDL in rats. [3H]Cholesteryl ethers were also incorporated as noncatabolized, intracellularly trapped tracers of cholesteryl esters. Liver was the predominant site of HDL cholesteryl ether uptake, consistent with a role of HDL in reverse cholesterol transport; adrenal was the most active per unit wet weight. In adrenal, ovary, and liver, the cholesteryl ether tracer was taken up at a much greater rate than apoA-I, suggesting a mechanism for cholesteryl ester uptake independent of holo-particle uptake. Such a mechanism was verified in primary cultures of rat adrenal cells and hepatocytes.
Highlights
In spite of much progress in understanding the mechanisms of lipoprotein metabolism at the cellular level, much less is known quantitatively about what occurs in vivo
While it was recognized that each major class of lipoproteins was somewhat heterogeneous, there seemed at least to be a modal composition and a degree of kinetic homogeneity that justified dealing with each class as an entity
It was recognized rather early that chylomicrons and VLDL were not metabolized as intact entities; most of the triglyceride was taken up peripherally while most of the cholesteryl ester was taken up by the liver
Summary
Our concepts of lipoprotein molecules have gone through a considerable evolution over the past 25 years-and they are still evolving. While it was recognized that each major class of lipoproteins was somewhat heterogeneous, there seemed at least to be a modal composition and a degree of kinetic homogeneity that justified dealing with each class as an entity. This notion received important reinforcement from studies of LDL uptake and metab olism which indicated that LDL particles were bound and internalized as entities, that is, as holoLDL particles. The concept of a basic unit structure was retained with respect to the “remnants” generated from chylomicrons and VLDL These products, not degraded further by lipoprotein lipase, were presumed to be metabolized as unit particles. The models will be ever more elaborate and validations more difficult, but not impossible
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
