Liver Storage and Release of Retinol

1 Liver Storage and Release of Retinol Tissues can take up retinyl esters from chylomicrons, but most is left in the chylomicron remnants that are taken up into the liver by endocytosis. The retinyl esters are hydrolyzed at the hepatocyte cell membrane, and free retinol is transferred to the rough endoplasmic reticulum, where it binds to apo-RBP. Holo-RBP then migrates through the smooth endoplasmic reticulum to the Golgi and is secreted as a 1 1 complex with the thyroid hormone binding protein, transthyretin (Section 2.2.3). 

Studies in vitamin A replete animals suggest that most of the retinol is transferred from hepatocytes to the perisinusoidal stellate cells of the liver. Here, it is again esterified by LRAT to form mainly retinyl palmitate (76% to 80%), with smaller amounts of stearate (9% to 12%), oleate (5% to 7%), and linoleate (3% to 4%). The stellate cells contain 90% to 95% of hepatic vitamin A, as cytoplasmic lipid droplets that consist of between 12% to 65% retinyl esters (Batres and Olson, 1987). Studies with [ C]retinyl palmitate show that much of the recently ingested retinol appears more or less immediately in the 

Release of retinol from stellate cells into the circulation may occur either directly, as free retinol bound to RBP, or indirectly as a result of the transfer of retinol from stellate cells to hepatocytes. The release of retinol from stores is impaired in iron deficiency, as is the absorption of dietary vitamin A (fang et al., 2000). 

Although the major storage of vitamin A is in the liver (50% to 80% of the total body content), adipose tissue may contain 15% to 20% of total body vitamin A. Much of this is taken up from chylomicrons retinyl esters are hydrolyzed 

A variety of other tissues synthesize RBP this provides a mechanism for return to the liver of retinol in excess of requirements that has heen taken up from chylomicrons hy the action of Upoprotein lipase. Because these tissues do not synthesize transthyretin, the hinding of holo-RBP to transthyretin must occur in the circulation after release. 

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Altered vitamin A homeostasis, primarily manifested as decreased hepatic storage of vitamin A, is another established effect of PBBs in animals. Vitamin A is essential for normal growth and cell differentiation, particularly differentiation of epithelial cells, and some PBB-induced epithelial lesions resemble those produced by vitamin A deficiency. Because it is the primary storage site for vitamin A, the liver has a major role in retinol metabolism. Esterification of dietary vitamin A, hydrolysis of stored vitamin A, mobilization and release into the blood of vitamin A bound to retinol-binding protein, and much of the synthesis of retinol-binding protein occurs in the liver. 

The retinyl esters are incorporated into chylomicrons, which in turn enter the lymph. Once in the general circula-tion. chylomicrons arc converted into chylomicron remnants, which arc cleared primarily by the liver. As the c.stcrs enter the hepalocytes. they are hydrolyzed. In the endoplasmic reticulum, the retinol is bound to retinol-binding protein (RBP). This cotnplex is released into the blood or transferred to liver stellate cells fur storage. Within the stellate cells, the retinol is bound to CRBP(I) and e.stcnTicd for storage by ARAT and LRAT. Stellate cells contain up to 95% of the liver vitamin A. stores. The RBP-retinol complex released into the general circulation from hepalocytes or stellate cells, in turn, is bound to transthyretin (TTR), which protects retinol from metabolism and renal excretion. ... 

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