Quantification and regulation of the subcellular distribution of bile acid coenzyme A:amino acid N-acyltransferase activity in rat liver

Bile acid coenzyme A:amino acid N-acyltransferase (BAT) is responsible for the amidation of bile acids with the amino acids glycine and taurine. To quantify total BAT activity in liver subcellular organelles, livers from young adult male and female Sprague-Dawley rats were fractionated into multiple subcellular compartments. In male and female rats, 65-75% of total liver BAT activity was found in the cytosol, 15-17% was found in the peroxisomes, and 5-10% was found in the heavy mitochondrial fraction. After clofibrate treatment, male rats displayed an increase in peroxisomal BAT specific activity and a decrease in cytosolic BAT specific activity, whereas females showed an opposite response. However, there was no overall change in BAT specific activity in whole liver homogenate. Treatment with rosiglitazone or cholestyramine had no effect on BAT activity in any subcellular compartment. These experiments indicate that the majority of BAT activity in the rat liver resides in the cytosol. Approximately 15% of BAT activity is present in the peroxisomal matrix. These data support the novel finding that clofibrate treatment does not directly regulate BAT activity but does alter the subcellular localization of BAT.     

Affinity and distribution of surface and intracellular hyaluronic acid receptors in isolated rat liver endothelial cells

125I-Hyaluronic acid (HA) uniquely modified only at the reducing end (Raja, R.H., LeBoeuf, R. D., Stone, G.W., and Weigel, P.H. (1984) Anal. Biochem. 139, 168-177) binds specifically to rat liver endothelial cells in suspension or in culture. About 67-85% of the HA binding sites in isolated cells in suspension and 50% in cultured cells were intracellular, since they were exposed after permeabilizing cells with digitonin. Specific 125I-HA binding at 4 degrees C varied from 60 to 80% for intact cells and from 70 to 90% for permeabilized cells. Freshly isolated permeabilized cells bound about 500,000 HA molecules/cell at saturation. Within 5 h of culture, however, total HA binding decreased to 250,000 molecules/cells and then remained constant for at least 36 h. Surface HA receptor activity was essentially the same on cultured cells or cells in suspension (approximately 10(5)/cell). Cultured cells had 1.8 x 10(5) fewer intracellular receptors/cell. The affinities of surface and intracellular receptors of cells in culture and in suspension were essentially the same. The average Kd, determined by equilibrium binding studies, was 5.8 +/- 2.8 x 10(-8) M (n = 12). Dissociation of bound 125I-HA from permeable cultured cells was rapid (t1/2 = 30.9 min;kappa off = 3.7 x 10(-4) s-1). A variety of carbohydrates had essentially identical effects on 125I-HA binding to surface or total cellular receptors in cells in culture or in suspension. Chondroitin sulfate and heparin competed almost as effectively as unlabeled HA for 125I-HA binding at 4 degrees C. Other saccharides including polygalacturonic acid, dextran, glucuronic acid, and N-acetylglucosamine competed poorly or not at all. We conclude that (i) the 125I-HA binding sites within liver endothelial cells are HA receptors, identical in affinity and specificity to those on the cell surface; (ii) the distribution of cellular HA receptors is similar to other receptor systems with about 50-80% being intracellular; (iii) the liver endothelial cell HA receptor recognizes several glycosaminoglycans; and (iv) the liver endothelial receptor is different in function and characteristics than the fibroblast HA receptor.     

Subcellular distribution of cholic acid:coenzyme a ligase and deoxycholic acid:Coenzyme a ligase activities in rat liver

Cholic acid:CoA ligase (EC 6.2.1.7, choloyl-CoA synthetase) and deoxycholic acid:CoA ligase catalyze the synthesis of choloyl-CoA and deoxycholoyl-CoA from their respective bile acids in rat liver. A modification of the phase partition assay was introduced which yields significantly (3-fold) higher specific activities for cholic acid:CoA ligase than previously reported. An independent method of separating choloyl-CoA from the substrates by high-pressure liquid chromatography was also developed and validates the modification. Both enzymic activities were found to be localized predominantly in the endoplasmic reticulum of rat liver. The level of either ligase in other purified, active subcellular fractions is consistent with the level of contamination by endoplasmic reticulum, estimated by using marker enzymes. Hence, the ligase assay can be used as a sensitive enzymic marker for endoplasmic reticulum in rat liver. The kinetic parameters of both enzymic activities were determined by using purified rough endoplasmic reticulum from rat liver. While the apparent maximal velocities for the two substrates are similar, the Michaelis constant for deoxycholate is significantly lower than that for cholate. Taurocholate and deoxycholate are shown to be competitive inhibitors of cholic acid:CoA ligase. The inhibition constant of deoxycholate is similar to its Michaelis constant for the deoxycholoyl-CoA-synthesizing reaction, suggesting that the same enzyme is responsible for both ligase activities.     

Changes in the content and intracellular distribution of coenzyme Q homologs in rabbit liver during growth

In order to determine whether coenzyme Q (CoQ) homologs which coexist in mammals play the same or different roles, the concentrations of coenzyme Q9 (CoQ9) and coenzyme Q10 (CoQ10) were analyzed in Japanese White (JW) rabbit tissues during growth, together with the intracellular distribution of these two CoQ homologs. In liver %CoQ9 (total [CoQ9] X 100/total [CoQ9] + total [CoQ10]) was approx. 40% until 3 weeks after birth, and then gradually decreased to 20%. In kidney, %CoQ9 decreased from 8% (1 week) to 1% (7 weeks). In heart, %CoQ9 was 3%, and in the brain, 2%, and these values did not change with growth. Most CoQ9 was present in the cytosolic fraction, whereas most CoQ10 was in the mitochondrial fraction. There was but minor change in the intracellular distribution of CoQ9 and CoQ10 in rabbit liver between 2 weeks and 7 weeks of age. These results suggest that CoQ9 and CoQ10 may play different roles in their physiological actions as antioxidant or component of the mitochondrial respiratory chain.