Postnatal development of cholesterol ester hydrolase activity in the rat adrenal

In certain circumstances the activity of cholesterol ester hydrolase (CEH) activity is believed to be rate-limiting for corticosterone production by the adrenal. The principal aim of the current study was to determine whether the activity of CEH displays a developmental increase in the infant rat which could, in part, account for the marked increase in serum corticosterone which begins at the end of the second postnatal week. The data show that the specific activity of CEH (units/mg cytosolic protein) during development is actually a mirror image of the pattern seen for serum corticosterone, i.e. CEH activities are high when serum corticosterone concentrations are low and then fall when serum corticosterone is rising. Even when total activities of CEH in the adrenal were calculated, there was no increase in parallel with the initial rise of serum corticosterone. At each age studied, stressed pups displayed significant increases of serum corticosterone; however, their CEH activities were no different from those in the non-stressed littermates. It is concluded that the activity of CEH is not the rate-determining factor for the developmental surge of basal concentrations of serum corticosterone nor for stress-induced elevation of corticosterone during the developmental period. A second aim of the current study was to address the more general question of whether steroidogenesis in the developing adrenal is limited by substrate supply. Measurement of the cholesterol content of adrenal mitochondria showed no ontogenic increase, suggesting that substrate supply, from any source, is not rate-limiting for steroidogenesis at these ages.     

The activity of cholesterol ester hydrolase in the enzymatic determination of cholesterol: comparison of five enzymes obtained commercially

The use of five cholesterol ester hydrolases (CEH), numbered 1 to 5, for the enzymatic determination of total cholesterol of human and rat serum are compared. All CEH gave approximately the same value (no statistical difference) for human serum. However, when rat serum cholesterol was determined, CEH-2 yielded a value significantly lower when compared to the four other CEH. The ability of each CEH to hydrolyze individual cholesterol esters was tested. During a 15-min incubation, all CEH were capable of hydrolyzing nearly 100% of cholesteryl oleate and linoleate. In contrast, the hydrolysis of cholesteryl arachidonate was only partial and varied from 20 to 80% depending on the CEH used. The highest hydrolysis was obtained by CEH-1 while the value given by CEH-2 was only 22% of that obtained by CEH-1. The rate of hydrolysis of cholesteryl arachidonate differed markedly among the CEH. The CEH-2-hydrolyzed the cholesteryl arachidonate at a rate seven times lower than the rate obtained with CEH-1. The data suggest that, Under our incubation conditions, CEH-2 did not properly hydrolyze the cholesteryl arachidonate. This phenomenon may be crucial whenever total cholesterol has to be determined enzymatically in the serum of species that contain large amount of cholesteryl arachidonate such as rat, mouse, or dog serum.     

Topological studies on rat liver microsomal cholesterol ester hydrolase

Lateral and transversal distribution of cholesterol ester hydrolase activity in rat liver microsomal membranes has been studied. Total cholesterol ester hydrolase activity was found predominantly (75%) in rough microsomes though specific esterase activities were similar in rough and smooth microsomal fractions. The transversal asymmetry of the enzyme was examined using the criteria of protease sensitivity and latency of mannose-6-phosphate phosphatase. Cholesterol ester hydrolase resulted drastically inhibited by proteolysis with trypsin when microsomal integrity had been previously disrupted with sodium deoxycholate or sodium taurocholate. Under these conditions, most lumenal mannose-6-phosphate phosphatase activity was destroyed. However, cholesterol esterase was unaffected by preincubating microsomes with the detergent alone, which led to the complete expression of latent mannose-6-phosphate phosphatase or by preincubating them with trypsin, where less than a 15% of the lumenal mannose-6-phosphate phosphatase was lost. These findings suggest that cholesterol ester hydrolase activity is located on the lumenal surface of the hepatic microsomal vesicles.     

Regulation of hepatic cholesterol ester hydrolase and acyl-coenzyme A:cholesterol acyltransferase in the rat

Cholesterol exists within the hepatocyte as free cholesterol and cholesteryl ester. The proportion of intrahepatic cholesterol in the free or ester forms is governed in part by the rate of cholesteryl ester formation by acyl-coenzyme A:cholesterol acyltransferase (ACAT) and cholesteryl ester hydrolysis by neutral cholesterol ester (CE) hydrolase. In other cell types both ACAT and CE hydrolase activities are regulated in response to changes in the need for cellular free cholesterol. In rats, we performed a variety of experimental manipulations in order to vary the need for hepatic free cholesterol and to examine what effect, if any, this had on the enzymes that govern cholesteryl ester metabolism. Administration of a 20-mg bolus of lipoprotein cholesterol or a diet supplemented with 2% cholesterol resulted in an increase in microsomal cholesteryl ester content with little change in microsomal free cholesterol. This was accomplished by an increase in cholesteryl esterification as measured by ACAT but no change in CE hydrolase activity. An increased need for hepatic free cholesterol was experimentally induced by intravenous bile salt infusion or cholestyramine (3%) added to the diet. ACAT activity was decreased with both experimental manipulations compared to controls, while CE hydrolase activity did not change. Microsomal cholesteryl ester content decreased significantly with little change in microsomal free cholesterol content. Addition of exogenous liposomal cholesterol to liver microsomes from cholestyramine-fed and control rats resulted in a 784 +/- 38% increase in ACAT activity. Nevertheless, the decrease in ACAT activity with cholestyramine feeding was maintained. These studies allowed us to conclude that changes in hepatic free cholesterol needs are met in part by regulation of the rate of cholesterol esterification by ACAT without a change in the rate of cholesteryl ester hydrolysis by CE hydrolase.     

Effect of adrenocorticotrophic hormone on the activity of sterol ester hydrolase from rat brain

Adrenocorticotrophic hormone (ACTH) stimulates in vitro the hydrolysis of oleoylcholesterol by a sterol ester hydrolase from rat brain synaptosomes. The stimulatory effect involves an alkaline shift of the pH optimum of catalysis and culminates at pH 6 with a 15 to 20-fold increase in lipolytic rates. The effect requires trace amount of organic solvent in the substrate emulsion and is dependent on the NH₂-terminal sequence extending through the basic amino acid residues at positions 15–18. The hormonal stimulation is decreased when a lipid-depleted preparation is used as enzyme source, and fully restored upon addition of lecithin. The results raise the possibility that ACTH may have a neuro-hormonal role in brain via modulation of local lipolytic processes.     

Kinetic properties and solubilization of microsomal cholesterol ester hydrolase from rat liver

Some kinetic properties of the microsomal cholesterol ester hydrolase (CEH) have been examined in rat liver. The reaction was linear with time up to 60 min and with enzyme concentration up to 0.3 mg/mL, and a pH optimum of 6.7 for enzyme activity was observed. Cholesterol esterase exhibited the following apparent kinetic constants: Km, 68.88 microM and Vmax, 33 Units/mg protein. Cholesteryl palmitate was hydrolyzed to a much greater extent than cholesteryl oleate by the enzyme. Product inhibition with cholesterol and palmitic acid was not apparent; however, oleic acid added to the system reduced markedly microsomal CEH activity. The present paper also reports the solubilization of cholesteryl palmitate hydrolase from the microsomal fraction by pretreating it with Triton X-100, sodium deoxycholate, and sodium dodecylsulfate. All ionic and non-ionic detergents tested are capable of making the enzyme soluble, and maximal effects were found at higher concentrations of detergents although the esterase activity was strongly inhibited. Triton X-100 was found to be more effective than sodium deoxycholate and sodium dodecylsulfate in enzyme and protein solubilization. When the direct effects of detergents on CEH activity were studied, progressive concentration-dependent inhibitions were observed.     

Hormonal and stressor-associated changes in porcine adrenocortical cholesterol ester hydrolase activity.

Cholesterol ester hydrolase (CEH) activity was characterized in the porcine adrenal gland and experiments conducted to determine the nature of its hormonal regulation. CEH activity was studied in the 14,000 gmax pellet (F4) and in the 192,000 gmax supernatant (F6). Characteristics associated with pH optima, product formation with time, linearity with increasing protein concentration, and equilibration of exogenous cholesterol esters added in acetone with endogenous cholesterol esters were determined. Scatchard analyses of saturation data demonstrated two-site models, which indicated the presence of lower velocity lower Km enzymes (catalytic sites) (L-VKm) and higher velocity higher Km enzymes (catalytic sites) (H-VKm) in both subcellular fractions. Neither ACTH (0.4 micrograms/kg body weight) nor 30-min restraint affected CEH activities at 0.5, 2, and 5 h after injection or initiation of restraint. However, 1 h after a longer restraint period (45 min), F4 H-VKm CEH activity increased concomitantly with decreased F6 L-VKm (P = 0.003). More modest increases in F4 H-VKm (P = 0.03) were still apparent 1 h after the last of nine daily 45-min restraints. Bromocriptine (CB154, a dopamine agonist) administration for 6 days (9.6 mg/daily) reduced plasma prolactin (PRL) by 53% (P < 0.05), but had no effect on CEH activities. ACTH treatment to CB154-induced hypoprolactinemic barrows dramatically reduced F4 (63%) and F6 (49%) L-VKm CEH activity (P = 0.03). These data are the first concerned with regulation of adrenal CEH activity in swine, and are the first to evaluate in vivo treatments on in vitro CEH activity in any species evolutionarily higher than rodents. In vivo regulation of porcine adrenal CEH activity appears complex. Stressor-associated hormonal perturbations apparently must surpass a certain threshold of duration and/or magnitude before they alter CEH activity. Differing Km and Vmax of CEH within and between the two subcellular fractions studied and the differential responses to restraint stressor suggest that as many as four different enzymes with CEH activity are involved. Additionally, the combined effect of ACTH and CB154-induced hypoprolactinemia argues for an interrelated modulatory function of ACTH and PRL (or dopamine) on specific porcine adrenal CEH activities.     

Hormonal regulation of acid cholesterol ester hydrolase activity: effects of triiodothyronine and 17 alpha-ethynylestradiol

Cholesterol ester hydrolase activity was measured in isolated rat hepatocytes and adipocytes. Administration of triiodothyronine to rats resulted in a specific and selective increase in lysosomal acid (pH 4.5) cholesterol ester hydrolase activity in hepatocytes. Since the majority of lipoprotein degradation occurs in liver parenchymal cells (hepatocytes), the stimulation of liver (hepatocyte) acid cholesterol ester hydrolase activity by triiodothyronine could contribute to the hypocholesterolemic action of thyroid hormones. Treatment of rats with 17 alpha-ethynylestradiol to increase the hepatic degradation of lipoprotein did not change acid cholesterol ester hydrolase activity in liver, indicating that the thyroid hormone induced stimulation of acid cholesterol ester hydrolase activity in hepatocytes is not a secondary effect owing to the increased hepatic catabolism of low density lipoproteins (LDL). In contrast to the results with hepatocytes, hyperthyroidism did not increase acid cholesterol ester hydrolase activity in rat adipocytes.     

Effect of substrate composition and concentration on aortic cholesterol ester hydrolase activity.

Cholesterol ester hydrolase activity of pig aorta has been examined under optimum experimental conditions for hydrolysis of different cholesterol esters. The enzyme specific activity values were in the numerical order of substrates hydrolyzed: cholesteryl linoleate larger than or equal to linolenate greater than palmitate larger than or equal to stearate greater than oleate. The results are discussed in relation to the arterial accumulation of cholesterol esters.     

Cholesterol esters in developing rat brain: enzymes of cholesterol ester metabolism

Abstract— Three enzymes of cholesterol ester metabolism, a cholesterol-esterifying enzyme which incorporates free fatty acids into cholesterol esters without participation of CoA, and two cholesterol ester hydrolases with differing pH optima, all showed distinct changes in developing rat brains. The specific activity of the esterifying enzyme was approx. 20 percent of the adult level at birth, increased gradually to the adult level by 20 days of age and remained constant thereafter. The pH 4.2 hydrolase at birth also had a specific activity of about 20 per cent of the adult level but it increased rapidly to reach a peak at 13 days, by which time the activity had increased eight-fold. The activity declined somewhat thereafter to reach the adult level by 23–30 days. In contrast, there already was 60 per cent of the adult specific activity of the pH 6.6 cholesterol ester hydrolase at birth. The activity remained constant until 12 days and then doubled during the next two weeks, reaching a broad peak, then declining slightly to reach the adult activity by 50 days. Therefore, the developmental changes of both of the hydrolases appeared to be related to the process of myelination. The period of active myelination (10–30 days) was characterized by the sharp rise in the activity of pH 6.6 cholesterol ester hydrolase and by the rapid decrease of pH 4.2 cholesterol ester hydrolase.     

Hormone-sensitive lipase is responsible for the neutral cholesterol ester hydrolase activity in macrophages

Anti-hormone-sensitive lipase (HSL) immunoglobulin selectively immunoprecipitates a single 84 kDa 32P-phosphoprotein from macrophage homogenates previously phosphorylated by cyclic AMP-dependent protein kinase in the presence of [gamma-32P]ATP-Mg. This immunoglobulin also completely removes the neutral cholesterol ester hydrolase activity from macrophage homogenates. These data demonstrate that HSL is responsible for the neutral cholesterol ester hydrolase activity in macrophages and hence plays a key role in cholesterol metabolism in these cells.     

Effect of thyroid hormones on acid cholesterol ester hydrolase activity in rat liver,heart and epididymal fat pads

The regulation of acid cholesterol ester hydrolase activity by thyroid hormones was studied in subcellular fractions from rat liver, heart, and epididymal fat pads; hydrolase activity was determined at pH 5 with a glycerol-dispersed cholesterol oleate substrate preparation. Acid cholesterol ester hydrolase activity was decreased in liver preparations from thyroidectomized rats relative to activity in livers from euthyroid control rats. Administration of triidothyronine to either euthyroid or hypothyroid (thyroidectomized) rats resulted in an increase in acid cholesterol ester hydrolase activity in liver preparations. Similar effects of thyroidectomy and the administration of triiodothyronine on acid cholesterol ester hydrolase activity were observed with fat pad preparations. In contrast, no effect of thyroid hormones was observed on acid cholesterol ester hydrolase activity in heart. These results suggest that thyroid hormones may regulate the catabolism of serum lipoproteins, in part, by alterations in lysosomal acid cholesterol ester hydrolase activity in liver and epididymal fat pads.     

Regulation of cholesterol ester hydrolase by cyclic AMP-dependent protein kinase

Phosphorylation of cholesterol ester hydrolase by cyclic AMP-dependent protein kinase results in activation of both cholesterol ester and triacylglycerol hydrolase activities. Activation against both substrates correlates closely with phosphorylation in time course experiments. Proteolytic digestion of phosphorylated cholesterol ester hydrolase, followed by peptide mapping, indicates the presence of a single phosphorylation site on the enzyme. Phosphoserine is the only phosphoamino acid detected following partial acid hydrolysis of the phosphorylated enzyme.     

Glucagon- and dibutyryl cyclic AMP-produced inhibition of cholesterol ester hydrolase in isolated rat hepatocytes: role of calcium

The regulation of neutral cytosolic cholesterol ester hydrolase was studied in isolated rat liver cells. Addition of glucagon to cell suspensions caused a decrease in the enzyme activity which was significant at 1 nM concentration. The cyclic nucleotide analogue bibutyryl cyclic AMP (10 and 100 microM) also inhibited the esterase activity. In the absence of calcium, glucagon did not produce any effect on the enzyme. To see if calcium was involved in a regulatory mechanism, cholesterol ester hydrolase activity was measured in cytosol from cells preincubated in a medium without calcium and containing EGTA. This treatment produced a marked reduction in cytosolic Ca2+ concentration with a concomitant threefold stimulation of the esterase activity. Readdition of calcium to Ca2(+)-deprived cells diminished the activation due to calcium deficiency. The present results suggest that 1) cholesterol ester hydrolase could be modulated by a cAMP-mediated mechanism elicited by glucagon in which Ca2+ appears to be involved and 2) the enzyme activity may also be regulated by changes in the intracellular calcium concentration.     

Subcellular localization of cholesterol ester hydrolase in the human intestine

Immunocytochemistry and subcellular fractionation were used to localize the cholesterol ester hydrolase in the human small intestine. A positive immunoreaction, when using antibodies directed against pancreatic cholesterol ester hydrolase, was mainly found in endocytotic vesicles. Moreover, a label by gold particles was observed in intercellular spaces where lymphatic tissue merges. No specific immunoreactivity was obtained with the mucosa when sera directed against human pancreatic chymotrypsinogen and human pancreatic lipase were used. Conventional subcellular fractionation was performed after extensive washing of enterocytes to rule out any possible contamination by pancreatic enzymes. In these conditions a bile salt-dependent cholesterol ester hydrolase activity was detected in the soluble fraction of cells. Data agree with the concept that the intestinal cholesterol ester hydrolase may have a pancreatic origin. The absorption, if any, of this enzyme by enterocytes seems specific since other pancreatic (pro)enzymes tested (lipase, chymotrypsinogen) are not detected in these cells.