Regulation of acyl coenzyme A reductase by a heat-stable cytosolic protein during preputial gland development

A low-molecular-weight protein located in the cytosol of mouse preputial glands has been shown to stimulate the activity of a microsomal acyl coenzyme A (CoA) reductase in the gland. This cytoplasmic protein was stable to heating and lyophilization, but was destroyed by trypsin digestion. It was able to bind palmitoyl-CoA and gel elution behavior indicated it had a molecular weight of 10,000–12,000. The level of this stimulatory cytosolic protein and the activity of acyl-CoA reductase were shown to correlate with differentiation of the preputial gland during development of puberty in male mice; the acyl-CoA reductase activity first appeared at 4 weeks of age and increased dramatically up to 6 weeks of age. By 8 weeks, when sexual maturity was attained, the reductase activity decreased to that level found in mature male mice. The cytosol from the preputial glands of the youngest mice (3 weeks) contained sufficient heat-stable acyl-CoA binding protein to stimulate acyl-CoA reduction; however, the 3-week-old preputial gland microsomes had little or no acyl-CoA reductase activity. As the animal matured, the stimulatory capacity in the heat-treated cytosol increased, reaching a maximum at 6 weeks; by 8 weeks, the stimulatory capacity of the soluble fraction had decreased to that found in mature male mouse. Results of this study suggest that the concentration of acyl-CoA, cytoplasmic acyl-CoA binding protein, and acyl-CoA reductase activity regulate the level of fatty alcohols in vivo and that the reductase activity and binding protein have similar patterns of development during puberty.     

Characterization of acyl-CoA:cholesterol acyltransferase from neonatal chick liver

Endogenous cholesterol esterification in chick liver microsomes was catalyzed by acyl-CoA:cholesterol acyltransferase using palmitoyl-CoA as substrate. An acyl-CoA hydrolase activity was also found in our microsomal preparations. Acyltransferase activity was stable after microsomes storage at -40 degrees C for 6 weeks and increased linearly with the preincubation time between 0 and 45 min. In our assay conditions, cholesteryl ester formation was linear up to 0.3 mg of microsomal protein in the reaction vial and 10 min of incubation. Maximal activity was found in reactions carried out in the presence of 1-2 mM dithiothreitol and 1.2 mg of bovine serum albumin, while acyl-CoA hydrolase was clearly inhibited by increasing albumin amounts.     

Stearyl-CoA desaturase of bovine mammary microsomes

Stearyl-CoA desaturase from the microsomal fraction of lactating bovine mammary tissue had a specific activity of 0.4 nmoles oleate formed min^?1 mg^?1 protein. NADH was required for desaturase activity. However, oxidized NAD⁺ and NADP⁺ supported measurable desaturase activity. K_m values for stearyl-CoA and NADH were 25.0 μm and 3.0 μm, respectively. Desaturase was depressed by increasing concentrations of other acyl-CoA esters, i.e., palmityl-CoA and oleyl-CoA (>10 μm). Sn-1,2 diglycerides (1–2.0 μm) depressed desaturase slightly in the order 0–20%, as did l-α-glycerolphosphate (0.2–3.6 μm). 1-Acyl-sn-glycerol-3-phosphorylcholine (>0.1 μm) depressed desaturase activity markedly. Sonication of the microsomal preparation stimulated desaturase activity. The addition of ethanol depressed desaturation, and EDTA inhibited desaturation. Palmityl CoA was equally desaturated by the microsomes. The acyl-CoA desaturase was very stable when stored at ?30 °C as a freeze-dried microsomal preparation, i.e., activity was retained after 12-month storage.Labeled stearate and oleate were isolated as esters (triglycerides and phospholipids) and as free fatty acids, indicating the presence of acyl transferases and acyl-CoA hydrolase in mammary microsomes.     

Characterization of a fatty acyl-CoA reductase from Marinobacter aquaeolei VT8: a bacterial enzyme catalyzing the reduction of fatty acyl-CoA to fatty alcohol

Fatty alcohols are of interest as a renewable feedstock to replace petroleum compounds used as fuels, in cosmetics, and in pharmaceuticals. One biological approach to the production of fatty alcohols involves the sequential action of two bacterial enzymes: (i) reduction of a fatty acyl-CoA to the corresponding fatty aldehyde catalyzed by a fatty acyl-CoA reductase, followed by (ii) reduction of the fatty aldehyde to the corresponding fatty alcohol catalyzed by a fatty aldehyde reductase. Here, we identify, purify, and characterize a novel bacterial enzyme from Marinobacter aquaeolei VT8 that catalyzes the reduction of fatty acyl-CoA by four electrons to the corresponding fatty alcohol, eliminating the need for a separate fatty aldehyde reductase. The enzyme is shown to reduce fatty acyl-CoAs ranging from C8:0 to C20:4 to the corresponding fatty alcohols, with the highest rate found for palmitoyl-CoA (C16:0). The dependence of the rate of reduction of palmitoyl-CoA on substrate concentration was cooperative, with an apparent K(m) ~ 4 μM, V(max) ~ 200 nmol NADP(+) min(-1) (mg protein)(-1), and n ~ 3. The enzyme also reduced a range of fatty aldehydes with decanal having the highest activity. The substrate cis-11-hexadecenal was reduced in a cooperative manner with an apparent K(m) of ~50 μM, V(max) of ~8 μmol NADP(+) min(-1) (mg protein)(-1), and n ~ 2.     

A recommended procedure for the estimation of bovine testicular hyaluronidase in the presence of human serum

A procedure is described for the assay of bovine testicular hyaluronidase in human blood following intravenous administration of the enzyme. Inhibition of hyaluronidase by the reported nonspecific serum inhibitor is minimal. However, the presence of human serum does alter the pH profile of hyaluronidase and enhances the activity of the enzyme at low pH values. Preliminary data indicates that the effects caused by serum on the pH optimum and activity of the enzyme are largely associated with the albumin fraction and are not due to the presence of endogenous serum hyaluronidase. The activation effect is not specific for any particular blood type and is independent of whether serum or citrated plasma is used. A similar effect to that of serum on hyaluronidase activity is produced by different buffer mixtures or increased NaCl concentration. It is recommended that bovine testicular hyaluronidase be measured at pH 4.0 in 0.1 m sodium citrate buffer containing 0.15 m NaCl as under these conditions the addition of human serum or citrated plasma does not alter the pH optimum of the enzyme. These recommendations necessitate certain modifications of the reducing N-acetylhexosamine assay method of Reissig et al. (J. L. Reissig, J. L. Strominger, and L. F. Leloir, 1955, J. Biol. Chem.217, 959–966).     

Effects of bovine serum albumin and phospholipids on activity of microsomal 3-hydroxy-3-methylglutaryl coenzyme A reductase in sweet potato roots

Sweet potato microsomal 3-hydroxy-3-methylglutaryl coenzymeA (HMG-CoA) reductase preincubated at 30?C was inactivated 50to 60%. The inactivation depended on temperature and was muchless with preincubation below 20?C. High concentration (above0.6%, w/v) of bovine serum albumin not only prevented inactivationbut also increased the activity. Even after preincubation fora given time without bovine serum albumin, its addition at 1%(w/v) prevented inactivation during further incubation, althoughit was unable to restore the activity to the initial level. Microsomal lipids were hydrolyzed during preincubation at 30?C.There was a positive correlation between formation of fattyacids during the preincubation and loss of HMG-CoA reductaseactivity. The micelles prepared from sweet potato microsomalphospholipids also prevented enzyme inactivation. These resultssuggest that the hydrolysis of microsomal phospholipids inducesthe instability of microsomal HMG-CoA reductase by alteringmicrosomal membrane structures and that the enzyme requiresphospholipids for its activity. Besides bovine serum albumin and phospholipids, NADPH₂ and HMG-CoAadded together prevented inactivation of this enzyme but notwhen added separately. ¹ This paper constitutes Part 128 in the series "The PhytopathologicalChemistry of Sweet Potato with Black Rot and Injury." This workwas supported in part by a grant from the Ministry of Education. (Received October 28, 1976; )     

Biosynthesis of fatty alcohols,alkane-1,2-diols and wax esters in particulate preparations from the uropygial glands of white-crowned sparrows (Zonotrichia leucophrys)

Biosynthesis of sebaceous gland waxes was studied with the uropygial gland of the white-crowned sparrow as the experimental tissue. A 27,000g particulate preparation from this gland catalyzed reduction of palmitoyl-CoA to hexadecanol at an optimum pH near 5.0 with NADPH as the preferred reductant. At low protein concentrations, palmitoyl-CoA inhibited the reductase and bovine serum albumin prevented this inhibition. An apparent K_m of 0.3 mm was calculated for palmitoyl-CoA from linear double-reciprocal plots ignoring the inhibitory concentration of the substrate. An apparent K_m of 3 mm was calculated for NADPH from linear double-reciprocal plots. Palmitoyl-CoA reduction was inhibited by thiol directed reagents such as p-chloromercuribenzoate, N-ethylmaleimide, and iodoacetamide. The particulate fraction also catalyzed esterification of hexadecanol with endogenous C₁₆ and C₁₈ acyl moieties with an optimum pH of 7.5. Stimulation of esterification of hexadecanol by ATP and CoA as well as by low concentrations of palmitoyl-CoA suggests that the CoA esters of fatty acids are involved in esterification. Tween-20 stimulated esterification of hexadecanol and hexadecyl dodecanoate was the major wax ester formed in the presence of Tween-20 suggesting that the C₁₂ acid of Tween-20 participated in esterification. Ignoring the inhibitory concentrations of hexadecanol (>0.2 mm), an apparent K_m of 0.1 mm was calculated from linear double-reciprocal plots. α-Hydroxylation of palmitic acid was demonstrated in cell-free extracts of the uropygial gland. A 27,000g particulate preparation from the gland catalyzed the reduction of α-hydroxypalmitic acid to hexadecane-1,2-diol with NADPH as the preferred reductant at an optimum pH near 6.5. This reduction required both ATP and CoA, suggesting that α-hydroxyacyl-CoA was the true substrate for the reductase. With stereospecifically labeled NADP³H, it was shown that both acyl-CoA reduction and α-hydroxy acid reduction involved transfer of the hydride specifically from the B-side of the nicotinamide ring of NADPH. Subcellular fractionation using sucrose density gradient centrifugation strongly suggested that the enzymes which catalyzed reduction of palmitoyl-CoA and α-hydroxypalmitic acid as well as the esterification of hexadecanol are localized in the microsomal membranes of the gland.     

Microsomal phosphatidate phosphatase in maturing safflower seeds

An assay system comprising sodium phosphatidate, phosphatidylcholine, and bovine serum albumin has been developed for the reproducible determination of phosphatidate phosphatase activity in maturing seeds of safflower (Carthamus tinctorius L.). The activity was detected in both membrane and soluble fractions, and the microsomal phosphatidate phosphatase was characterized. The optimum pH for Pi release was 6.7, and the activity depended on the concentration of Mg²⁺. Phosphatidylcholine and bovine serum albumin stimulated the phosphatase reaction. This phosphatase was highly specific for phosphatidate; lysophosphatidate, and water-soluble phosphate esters did not serve as substrate. The specific activity was approximately 20 nanomoles per minute per milligram of protein, which was close to that of glycerol-phosphate acyltransferase and higher than that of diacylglycerol acyltransferase. Furthermore, the activity per seed was enough to account for the rate of triacylglycerol accumulation in vivo. The step of diacylglycerol formation by phosphatidate phosphatase does not appear to be rate-limiting for triacylglycerol synthesis during seed maturation.     

Carnitine palmitoyltransferase activities: Effects of serum albumin,acyl-CoA binding protein and fatty acid binding protein

The carnitine palmitoyltransferase activity of various subcellular preparations measured with octanoyl-CoA as substrate was markedly increased by bovine serum albumin at low M concentrations of octanoyl-CoA. However, even a large excess (500 M) of this acyl-CoA did not inhibit the activity of the mitochondrial outer carnitine palmitoyltransferase, a carnitine palmitoyltransferase isoform that is particularly sensitive to inhibition by low M concentrations of palmitoyl-CoA. This bovine serum albumin stimulation was independent of the salt activation of the carnitine palmitoyltransferase activity. The effects of acyl-CoA binding protein (ACBP) and the fatty acid binding protein were also examined with palmitoyl-CoA as substrate. The results were in line with the findings of stronger binding of acyl-CoA to ACBP but showed that fatty acid binding protein also binds acyl-CoA esters. Although the effects of these proteins on the outer mitochondrial carnitine palmitoyltransferase activity and its malonyl-CoA inhibition varied with the experimental conditions, they showed that the various carnitine palmitoyltransferase preparations are effectively able to use palmitoyl-CoA bound to ACBP in a near physiological molar ratio of 1:1 as well as that bound to the fatty acid binding protein. It is suggested that the three proteins mentioned above effect the carnitine palmitoyltransferase activities not only by binding of acyl-CoAs, preventing acyl-CoA inhibition, but also by facilitating the removal of the acylcarnitine product from carnitine palmitoyltransferase. These results support the possibility that the acyl-CoA binding ability of acyl-CoA binding protein and of fatty acid binding protein have a role in acyl-CoA metabolismin vivo.Abbreviations ACBP acyl-CoA binding protein - BSA bovine serum albumin - CPT carnitine palmitoyltransferase - CPT₀ malonyl-CoA sensitive CPT of the outer mitochondrial membrane - CPT malonyl-CoA insensitive CPT of the inner mitochondrial membrane - OG octylglucoside - OMV outer membrane vesicles - IMV inner membrane vesicles Affiliated to the Department of Experimental Medicine, University of Montreal     

Biosynthesis of dimethyl selenide from sodium selenite in rat liver and kidney cell-free systems

A pathway for the synthesis of dimethyl seledine from sodium selenite was studied in rat liver and kidney fractions under anaerobic conditions in the presence of GSH, a NADPH-generating system, and S-adenosylmethionine. Chromatography of liver or kidney soluble fraction on Sephadex G-75 yielded a Fraction C (30 000 molecular weight) which synthesized dimethyl selenide, but at a low rate. Addition of proteins eluting at the void volume (Fraction A) to Fraction C restored full activity. Fractionation of Fraction A on DEAE-cellulose revealed that its ability to stimulate Fraction C was associated with two fractions, one containing glutathione reductase and the other a NADPH-dependent disulfide reductase. It was concluded that Fraction C contains a methyltransferase acting on small amounts of hydrogen selenide produced non-enzymically by the reaction of selenite with GSH, and that stimulation by Fraction A results partly from the NADPH-linked formation of hydrogen selenide catalyzed by glutathione reductase present in Fraction A. Washed liver microsomal fraction incubated with selenite plus 20 mM GSH also synthesized dimethyl selenide, but addition of soluble fraction stimulated activity. A synergistic effect was obtained when liver soluble fraction was added to microsomal fraction in the presence of a physiological level of GSH (2 mM), whereas at 20 mM GSH the effect was merely additive. The microsomal component of the liver system was labile, had maximal activity around pH 7.5, and was exceedingly sensitive to NaAsO₂ (93% inhibition by 10^?6 M arsenite in the presence of a 20 000-fold excess of GSH). The microsomal activity apparently results from a Se-methyltransferase, possibly a dithiol protein, that methylates hydrogen selenide produced enzymically by the soluble fraction or non-enzymically when a sufficiently high concentration of GSH is used.     

Hepatic lipid metabolism: effect of spermine, albumin, and Z protein on microsomal lipid formation.

Effects of spermine, bovine serum albumin, and Z protein on microsomal lipid formation from sn-glycerol 3-phosphate and [¹⁴C]palmitoyl CoA were investigated. In the presence of these agents, microsomal lipid formation was stimulated. This was attributed to the activation of sn-glycerol 3-phosphate acyltransferase and to the inhibition of palmitoyl CoA hydrolase. In addition to palmitoyl CoA, spermine also reacted with microsomal membranes in causing their aggregation, and ATP reversed the effect of spermine. Further studies indicated that the interaction of spermine with palmitoyl CoA, rather than with microsomal membranes, was responsible for the activation of glycerolipid formation or to the inhibition of palmitoyl CoA reductase. Examination of the intravesicular distribution of sn-glycerol 3-phosphate acyltransferase and palmitoyl CoA hydrolase and the effects of structural integrity of microsomal vesicles on these two membrane-bound enzymes indicated that the activation of glycerolipid formation and the inhibition of palmitoyl CoA hydrolase by spermine, bovine serum albumin, or Z protein may be closely linked with the structural integrity of microsomal vesicles.     

Purification and characterization of carbonyl reductases from bovine liver cytosol and microsome. the cytosolic enzyme has a novel 3α/17β-hydroxysteroid dehydrogenase activity

• 1.1. Carbonyl reductase, which is distributed in both cytosolic and microsomal fractions in bovine liver, were purified to homogeneity on 12.5% sodium dodecylsulfate-polyacrylamide gel electrophoresis and shown to have molecular weights of 32 kDa and 68 kDa, respectively.
• 2.2. Both carbonyl reductases can catalyze the reduction of many carbonyl compounds including ketone, quinones and aldehyde with relatively low K_m values.
• 3.3. From the absorption spectrum result, microsomal carbonyl reductase closely resembles cytochrome P-450 reductase.
• 4.4. Cytosolic carbonyl reductase is a novel enzyme which can act on both testosterone and androsterone at low concentration.

     

Interaction between NADPH-cytochrome P-450 reductase and hepatic microsomes

Solubilized NADPH-cytochrome P-450 reductase has been purified from liver microsomes of phenobarbital-treated rats. When added to microsomes, the reductase enhances the monoxygenase, such as aryl hydrocarbon hydroxylase, ethoxycoumarin O-dealkylase, and benzphetamine N-demethylase, activities. The enhancement can be observed with microsomes prepared from phenobarbital- or 3-methylcholanthrene-treated, or non-treated rats. The added reductase is believed to be incorporated into the microsomal membrane, and the rate of the incorporation can be assayed by measuring the enhancement in ethoxycoumarin dealkylase activity. It requires a 30 min incubation at 37°C for maximal incorporation and the process is much slower at lower temperatures. The temperature affects the rate but not the extent of the incorporation. After the incorporation, the enriched microsomes can be separated from the unbound reductase by gel filtration with a Sepharose 4B column. The relationship among the reductase added, reductase bound and the enhancement in hydroxylase activity has been examined. The relationship between the reductase level and the aryl hydrocarbon hydroxylase activity has also been studied with trypsin-treated microsomes. The trypsin treatment removes the reductase from the microsomes, and the decrease in reductase activity is accompanied by a parallel decrease in aryl hydrocarbon hydroxylase activity. When purified reductase is added, the treated microsomes are able to gain aryl hydrocarbon hydroxylase activity to a level comparable to that which can be obtained with normal microsomes. The present study demonstrates that purified NADPH-cytochrome P-450 reductase can be incorporated into the microsomal membrane and the incorporated reductase can interact with the cytochrome P-450 molecules in the membrane, possibly in the same mode as the endogenous reductase molecules. The result is consistent with a non-rigid model for the organization of cytochrome P-450 and NADPH-cytochrome P-450 reductase in the microsomal membrane.     

Biochemical properties of short- and long-chain rat liver microsomal trans-2-enoyl coenzyme A reductase

This study describes the biochemical properties of the rat hepatic microsomal NADPH-specific short-chain enoyl CoA reductase and NAD(P)H-dependent long-chain enoyl CoA reductase. Of the substrates tested, crotonyl CoA and trans-2-hexenoyl CoA are reduced by the short-chain reductase only in the presence of NADPH. The trans-2-octenoyl CoA and trans-2-decenoyl CoA appear to undergo reduction to octanoate and decanoate, respectively, catalyzed by both enzymes; 64% conversion of the C8:1 is catalyzed by the short-chain reductase, while 36% conversion is catalyzed by the long-chain enzyme. For the C10:1 substrate, 45% is converted by the short-chain reductase, while 55% is reduced by the long-chain reductase. trans-2-Hexadecenoyl CoA is a substrate for the long-chain enoyl CoA reductase only. Reduction of C4 and C6 enoyl CoA's was unaffected by bovine serum albumin (BSA), whereas BSA markedly stimulated the conversion of C10 and C16 enoyl CoA's to their respective saturated product. Reduction rates as a function of microsomal protein concentration, incubation time, pH, and cofactors are reported including the apparent Km and Vmax for substrates and cofactors. In general, the apparent Km's for the substrates ranged from 19 to 125 microM. The apparent Vmax for the short-chain enoyl CoA reductase was greatest with trans-2-hexenoyl CoA, having a turnover of 65 nmol/min/mg microsomal protein, while the apparent Vmax for the long-chain enzyme was greatest with trans-2-hexadecenoyl CoA, having a turnover of 55 nmol/min/mg microsomal protein. With respect to electron input, NADPH-cytochrome P-450 reductase, either alone, mixed with phospholipid, or incorporated into phospholipid vesicles, possessed no enoyl CoA reductase activity. Cytochrome c did not affect the NADPH-dependent conversion of the trans-2-enoyl CoA. In addition, anti-NADPH-cytochrome P-450 reductase IgG did not inhibit the reduction of trans-2-hexadecenoyl CoA in hepatic microsomes. Finally, the NADPH-specific short-chain and NAD(P)H-dependent long-chain enoyl CoA reductases were solubilized and completely separated from NADPH-cytochrome P-450 reductase by employing DE-52 column chromatography. These studies demonstrate the noninvolvement of NADPH-cytochrome P-450 reductase in either the short-chain (13) or long-chain enoyl CoA reductase system. Thus, the role of NADPH-cytochrome P-450 reductase in the microsomal elongation of fatty acids appears to be at the level of the first reduction step.     

The synthesis and hydrolysis of long-chain fatty acyl-coenzyme A thioesters by soluble and microsomal fractions from the brain of the developing rat.

1. The specific activities of long-chain fatty acid-CoA ligase (EC6.2.1.3) and of long-chain fatty acyl-CoA hydrolase (EC3.1.2.2) were measured in soluble and microsomal fractions from rat brain. 2. In the presence of either palmitic acid or stearic acid, the specific activity of the ligase increased during development; the specific activity of this enzyme with arachidic acid or behenic acid was considerably lower. 3. The specific activities of palmitoyl-CoA hydrolase and of stearoyl-CoA hydrolase in the microsomal fraction decreased markedly (75%) between 6 and 20 days after birth; by contrast, the corresponding specific activities in the soluble fraction showed no decline. 4. Stearoyl-CoA hydrolase in the microsomal fraction is inhibited (99%) by bovine serum albumin; this is in contrast with the microsomal fatty acid-chain-elongation system, which is stimulated 3.9-fold by albumin. Inhibition of stearoyl-CoA hydrolase does not stimulate stearoyl-CoA chain elongation. Therefore it does not appear likely that the decline in the specific activity of hydrolase during myelogenesis is responsible for the increased rate of fatty acid chain elongation. 5. It is suggested that the decline in specific activity of the microsomal hydrolase and to a lesser extent the increase in the specific activity of the ligase is directly related to the increased demand for long-chain acyl-CoA esters during myelogenesis as substrates in the biosynthesis of myelin lipids.     

Partial purification of the NADPH-dependent aldehyde reductase from bovine cardiac muscle.

An aldehyde reductase catalyzing the NADPH-dependent reduction of long-chain aldehydes has been purified 690-fold from bovine cardiac muscle. Based on the results obtained during gel filtration, this enzyme has an apparent molecular weight of 34,000. The pI of the aldehyde reductase was 6.1 and the enzymatic activity had a sharp pH optimum at 6.4. The enzyme catalyzed the reduction of aromatic aldehydes and aliphatic aldehydes having eight or more carbon atoms. Short-chain aldehydes, aldoses, or ketoses or long-chain methyl ketones were not utilized as substrates by this enzyme. However, the methyl ketone, pentadecan-2-one, was a competitive inhibitor of this enzyme with an apparent K_i = 10 μm when tetradecanal was the variable substrate. The reaction was not reversible when ethanol or hexadecanol was employed as substrate, utilizing either NAD⁺, or NADP⁺ as a cofactor. The addition of 10 mm pyrazole to the incubation medium had no effect on the enzymatic activity.     

Properties of rat liver microsomal stearoyl-coenzyme A desaturase.

1. Rat liver microsomal stearoyl-CoA desaturase activity was shown to be stimulated by both bovine serum albumin and a basic cytoplasmic protein from rat liver. 2. Partially purified desaturase is unaffected by either of these two proteins. 3. Bovine serum albumin appears to exert its effect on the crude system by protecting the desaturase substrate, stearoly-CoA, from the action of endogenous thiolesterases. 4. By using partially purified enzyme preparations, it was possible to establish the substate specificity of the delta9-fatty acyl-CoA desaturase with the C14, C15, C16, C17, C18 and C19 fatty acyl-CoA substrates. Maximum enzyme activity was shown with stearoyl-CoA decreasing with both palmitoyl-CoA and nonadecanoyl-CoA, as reported previously for free fatty acids. 5. Both cytochrome b5 and NADH-cytochrome b5 reductase (EC 1.6.2.2) are required for these studies and a method is described for the purification of homogeneous preparations of detergent-isolated cytochrome b5 from rat liver. 6. From amino acid analyses, a comparison was made of the hydrophobicity of the membrane portion of cytochrome b5 with the hydrophobicity reported for stearoyl-CoA desaturase. The close resemblance of the two values suggested that unlike cytochrome b5 and its reductase, the stearoyl-CoA desaturase may be largely buried in the endoplasmic reticulum.     

3-Hydroxy-3-methylglutaryl coenzyme A reductase from avian liver. Catalytic properties.

The catalytic properties of microsomal 3-hydroxy-3-methylglutaryl coenzyme A reductase from avian liver have been investigated. Solubilized and highly purified reductase preparations were not cold labile, and enzymic activity remained unchanged following preincubation at 37 degrees C. The pH optimum was 6.8--7.0 and maximal catalytic activity was achieved with 2 mM dithiothreitol and 0.75 M KCl. The heat stability of the enzyme was studied and the addition of 0.75 M KCl, 0.8 mg/ml bovine serum albumin and 5 mM NADPH reduced the inactivation of the purified reductase associated with heat treatment at 65 degrees C. At 37 degrees C, 0.8 mg/ml bovine serum albumin enhanced the purified reductase activity by 100 (+/- 20)%. An improved assay was developed for the avian hydroxymethylglutaryl-CoA reductase and the specific activity of the purified enzyme increased from 1550 to 3300 nmol . min-1 . mg-1. The Km values of solubilized and purified reductase for D-hydroxymethylglutaryl-CoA were 1.05 micrometer and 1.62 micrometer, and for NADPH, 1 mM and 263 micrometer, respectively. The activities of the reductase preparations were non-competitively inhibited by coenzyme A, acyl-CoA esters, and hydroxymethylglutarate. MgATP also reduced avian reductase activity. These modulators may play a role in the cellular regulation of the reductase activity.     

Activity of acyl-CoA: cholesterol acyltransferase and 3-hydroxy-3-methylglutaryl-CoA reductase in subfractions of hepatic microsomes enriched with cholesterol

The influence of membrane cholesterol on the activities of acyl-CoA: cholesterol acyltransferase and 3-hydroxy-3-methylglutaryl-CoA reductase was examined in three microsomal subfractions (RNA-rich, RNA-poor, and smooth) that had been enriched with cholesterol by incubation with mixed lipoproteins from hypercholesterolemic rabbit serum. Acyl-CoA: cholesterol acyltransferase activity was significantly stimulated in the three subfractions, particularly in the RNA-rich microsomal component. 3-Hydroxy-3-methylglutaryl-CoA reductase, on the other hand, was suppressed (30%) in only one (RNA-poor) of the three microsomal subfractions, despite a 1.4-fold increase in the concentration of membrane cholesterol. An attempt was made to distinguish between an effect based exclusively on an increase in available cholesterol substrate and an activation of acyl-CoA: cholesterol acyltransferase in RNA-rich microsomes enriched with cholesterol. An experimental design was devised so that substrate cholesterol was provided in the form of heated smooth microsomes and acyl-CoA: cholesterol acyltransferase was provided as a separate preparation in the form of RNA-rich microsomes. Appropriate controls were carried out to test for transfer of cholesteryl ester between the two sets of particles. The results suggested that cholesterol enhanced acyl-CoA: cholesterol acyltransferase activity by serving both as a substrate and as a non-substrate modulator.     

Comparison of the carnitine acyltransferase activities from rat liver peroxisomes and microsomes

Carnitine acyltransferase activities for acetyl- and octanoyl-CoA (coenzyme A) occur in isolated peroxisomal, mitochondrial, and microsomal fractions from rat and pig liver. Solubility studies indicated that both peroxisomal carnitine acyltransferases were in the soluble matrix. In contrast, the microsomal carnitine acyltransferases were tightly associated with their membrane. The microsomal short-chain transferase, carnitine acetyltransferase, was solubilized and stabilized by extensive treatment of the membrane with 0.4 m KCl or 0.3 m sucrose in 0.1 m pyrophosphate at pH 7.5. The same treatment only partially solubilized the microsomal medium-chain transferase, carnitine octanoyltransferase.Although half of the total carnitine acetyltransferase activity in rat liver resides in peroxisomes and microsomes, previous reports have only investigated the mitochondrial activity. Transferase activity for acetyl- and octanoyl-CoA were about equal in peroxisomal and in microsomal fractions. A 200-fold purification of peroxisomal and microsomal carnitine acetyltransferases was achieved using O-(diethylaminoethyl)-cellulose and cellulose phosphate chromatography. This short-chain transferase preparation contained less than 5% as much carnitine octanoyltransferase and acyl-CoA deacylase activities. This fact, plus differences in solubility and stability of the microsomal transferase system for acetyl- and octanoyl-CoA indicate the existence of two separate enzymes: a carnitine acetyltransferase and a carnitine octanoyltransferase in peroxisomes and in microsomes.Peroxisomal and microsomal carnitine acetyltransferases had similar properties and could be the same protein. They showed identical chromatographic behavior and had the same pH activity profiles and major isoelectric points. They also had the same apparent molecular weight by gel filtration (59,000) and the same relative velocities and K_m values for several short-chain acyl-CoA substrates. Both were active with propionyl-, acetyl-, malonyl-, and acetyacetyl-CoA, but not with succinyl- and β-hydroxy-β-methylglutaryl-CoA as substrates.