Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.2.2.7 (heparinase)
 1,270 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An in vitro model is presented for the study of glycosaminoglycans in human skin. The synthesis of six glycosaminoglycan species in both dermis and epidermis was measured by D-[3H]glucosamine labelling. Punched biopsies (epidermis + entire dermis) of 3 mm in diameter were cultured at 37 degrees C in 5% carbon dioxide-95% air. When the label was added 18 h after explantation, the incorporation started immediately, and for all glycosaminoglycans the time-dependent incorporation was linear for 16 h. The experimental variation was minimized by expressing the measurements in epidermis "per explant" and in dermis "per mg of wet explant". A ratio to dermal hydroxyproline did not improve the precision. Most of the variation arose "before" isolation and separation of the glycosaminoglycans. The labelled products were macromolecules and were converted to small molecules by chondroitinase ABC + heparinase. The total incorporation in dermis was 2 1/2 times higher than in epidermis. Hyaluronic acid was the predominant synthesized product in dermis, and hyaluronic acid and heparan sulphate were the predominant products in epidermis. The proportions (%) in dermis/epidermis were as follows: hyaluronic acid, 61/44; heparan sulphate, 18/31; dermatan sulphate, 5/8; chondroitin 4/6-sulphate, 10/7 and heparin-like glycosaminoglycan, 1/2. The same species were also demonstrated as native constituents of uncultured human skin. Hyaluronic acid and dermatan sulphate predominated in dermis, whereas no single species predominated in epidermis. Their concentrations in uronic acid equivalents per mg of wet skin (pmol/mg of epidermis + dermis) were as follows in dermis/epidermis: hyaluronic acid, 243/0.48; heparan sulphate, 22/0.44; dermatan sulphate, 170/0.56; chondroitin 4/6-sulphate, 72/0.50; and heparin-like glycosaminoglycan, 5/0.22. Thus, only 0.4% of the in vivo synthesized glycosaminoglycan was present in epidermis.
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PMID:D-[3H]glucosamine labelling of epidermal and dermal glycosaminoglycans in cultured human skin. 338 61

The metabolism of chylomicron remnants in mice deficient in low density lipoprotein receptor (LDLr) or apolipoprotein E (apoE) was compared with that of control C57BL/6J mice. Mice were injected intravenously with chylomicron-like emulsions labeled with radioactive lipids. Blood samples were taken at fixed time intervals from the retro-orbital sinus, and clearance rates of the lipoproteins were assessed from the decline in plasma radioactivities. To follow the intracellular pathway of remnants in the liver, emulsions labeled with a fluorescent cholesteryl ester (BODIPY) were injected, and liver sections were processed and assayed by laser confocal microscopy. Catabolism of remnant cholesteryl esters was assessed by injecting emulsions labeled with cholesteryl[1-14C]oleate and measuring the expired CO2 from each animal. In apoE-deficient mice, remnant removal from plasma was totally impeded, while the clearance of remnants in LDLr-deficient mice was similar to that in C57BL/6J control mice. The confocal micrographs of livers 20 min after injection of fluorescent chylomicron-like emulsions showed evenly distributed fluorescent particles in the hepatocytes from control mice. In contrast, the fluorescent particles were mainly located in sinusoidal spaces in LDLr-deficient mice. Three hours after injection the livers from control mice showed few fluorescent particles, indicating that remnants have been catabolized, while the sections from LDLr-deficient mice were still highly fluorescent. Micrographs from apoE-deficient mice showed no fluorescent particles in the liver at any time after injection. Measurement of expired radioactive CO2 after injection of emulsions labeled in the fatty acid moiety of cholesteryl oleate indicated that remnant metabolism was slower in the LDLr-deficient mice and essentially nil in the apoE-deficient mice. Control mice had expired 50% of the injected label by 3 h after injection. We conclude that under normal circumstances, chylomicron remnants are rapidly internalized by LDLr and catabolized in hepatocytes, with a critical requirement for apoE. When LDLr is absent, remnants are taken up by a second apoE-dependent pathway, first to the sinusoidal space of the liver, with subsequent slow endocytosis and slow catabolism. Hepatic clearance via this second pathway is increased by heparin, inhibited by lactoferrin, heparinase, and suramin, and down-regulated by feeding a high fat diet.
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PMID:Intracellular localization and metabolism of chylomicron remnants in the livers of low density lipoprotein receptor-deficient mice and apoE-deficient mice. Evidence for slow metabolism via an alternative apoE-dependent pathway. 749 99