Steryl esters and their relationship to normal and diseased human central nervous system. (65/88)

The composition and distribution of steryl esters in human diseased or developing brain tissue has been studied. The abnormal brain conditions included sudanophilic leukodystrophy, multiple sclerosis plaque, subacute sclerosing panencephalitis, and an old cerebral infarction and two types of brain-derived tumors. In addition to the above abnormal tissue, steryl esters were also examined in developing and normal adult human brain. It was found upon subcellular fractionation that the steryl ester was localized mainly in the soluble nonparticulate material. A cholesteryl ester-rich fraction, floating on top of distilled water after centrifugation, was recovered only in the developing brain or in instances where there was myelin damage. The sterol portion of the steryl ester was largely cholesterol. The fatty acid moiety was mainly composed of C(16), C(18), and C(20) fatty acids. The dominant fatty acid was oleic acid, and the proportion of this fatty acid increased in demyelination. Although there were great differences in the quantities of steryl ester found, the fatty acid profiles of normal developing and adult brain were quite similar. As has been noted by others, the fatty acid composition of brain steryl esters most closely resembles that of brain phosphatidylcholine.  (+info)

Synthesis of [24, 25-3H]cholesterol: a new substrate for determining the rate of cholesterol side chain oxidation. (66/88)

A procedure for the synthesis of [24,25-3H]cholesterol from the nonradioactive precursor desmosterol is described. The intermediate, isodesmosterol, which was purified by column chromatography, was formed to protect the original double bond (delta 5-6) from hydrogenation. Tritium was introduced into the side chain by catalytic reduction of the double bond (delta 24-25) of the isodesmosterol in the presence of carrier-free tritium. After ring rearrangement of the iso-[24,25-3H]cholesterol acetate, the acetate was hydrolyzed to form the free labeled cholesterol. Hepatic oxidation of the [24,25-3H]cholesterol side chain release tritium into water which freely equilibrates with cell and body water pools. Thus, the rate of 3H2O appearance corresponds to the rate of cholesterol side chain oxidation. Applications of this method to in vivo, isolated perfused liver, and isolated hepatocyte preparations of the rat are discussed.  (+info)

A novel olefinic rearrangement. The enzymic conversion of cholesta-7,9-dien-3 -ol into cholesta-8,14-dien-3 -ol. (67/88)

1. [3alpha-(3)H]Cholesta-7,9-dien-3beta-ol is converted in high yield into cholesterol by a 10000g(av.) supernatant fraction of rat liver homogenate. 2. Incubation of cholesta-7,9-dien-3beta-ol with [4-(3)H]NADPH and rat liver microsomal fractions under anaerobic conditions resulted in (3)H being incorporated into the 14alpha-position of cholest-7-en-3beta-ol. 3. Under anaerobic conditions in the absence of NADPH cholesta-7,9-dien-3beta-ol was isomerized into cholesta-8,14-dien-3beta-ol by rat liver microsomal fractions.  (+info)

Sterol biosynthesis by the sea urchin Echinus esculentus. (68/88)

1. The 4-demethyl sterols of Echinus esculentus consisted of cholesterol as the major component, with lower concentrations of nine other C(26), C(27), C(28) and C(29) Delta(5) sterols. 2. [2-(14)C]Mevalonic acid was readily incorporated by the urchin into squalene, lanosterol and desmosterol but only to a small extent into cholesterol. 3. [26-(14)C]Desmosterol did not appear to be reduced to give cholesterol, but conversion of 5alpha-[2-(3)H(2)]lanost-8-en-3beta-ol into cholesterol was observed. 4. No C-24 dealkylation of [4-(14)C]sitosterol or metabolism of [4-(14)C]cholesterol could be detected.  (+info)

Sterol structural requirements for inhibition of streptolysin O activity. (69/88)

Reduced streptolysin O, a toxin produced by certain beta-haemolytic streptococci, lyses human erythrocytes. The reaction is inhibited by cholesterol at concentrations of about 1.0mug/ml. Other sterols inhibit the lysin and there is a specific requirement for a 3beta-hydroxyl group. Inhibition was obtained with 3beta-hydroxychol-5-en-24-oic acid, containing a hydrophilic group at C-24. The mode of inhibition is likely to involve attachment to the fixation site of the lysin which attaches the molecule to cell membranes, probably to membrane cholesterol. A second streptolysin site, concerned in the final haemolytic event, may also be involved. Inhibitors of the latter site have not been characterized, other than antibody with specificity for the site.  (+info)

Distribution of steroid sulfotransferase in the male hamster reproductive tract. (70/88)

Steroid sulfotransferase activity has been assayed in cytosol extracts obtained from the male hamster reproductive tract. Dehydroisoandrosterone and desmosterol were used as substrates in the presence of phosphoadenosine phosphosulfate-35S as sulfate donor. No significant sulfotransferase activity was found in the testis. In the epididymis, a severalfold increase in activity was found in the tissue from the caput to the caudal regions. A lower but significant activity was detected in the vas deferens. The enzyme appears to be secreted into the luminal fluid while little activity is associated with the spermatozoa. This increase in activity along the epididymis is undoubtedly responsible for the accumulation of sterol sulfates reported previously. In view of the fact that sterol sulfates are potent and specific inhibitors of acrosin, as reported for the porcine and confirmed herein for hamster acrosin, the epididymal production of steroid and sterol sulfates may represent a protective mechanism against the premature release of proteolytic activity within the male reproductive tract.  (+info)

Aphidicolin, a specific inhibitor of DNA polymerase alpha, inhibits conversion of lanosterol to C-27 sterols in mouse L cells. (71/88)

Aphidicolin, a fungal metabolite which is a specific inhibitor of DNA polymerase alpha, inhibited the incorporation of [14C]acetate into desmosterol in mouse L cells by 50% at a concentration of 8.8 microM. It had no effect on acetate metabolism into fatty acids or CO2. The site of inhibition was determined to be distal to the formation of mevalonic acid since aphidicolin also inhibited the incorporation of [14C]mevalonolactone into desmosterol but had no effect on the activity of 3-hydroxy-3-methylglutaryl-CoA reductase (EC 1.1.1.34) or the incorporation of [14C]acetate into total nonsaponifiable lipids. High pressure liquid chromotographic analysis of the distribution of radioactivity among the nonsaponifiable lipids formed from [14C]acetate in the presence of aphidicolin indicated an accumulation of lanosterol accompanied by a proportional decrease in radiolabeled desmosterol and two of its precursors, delta 5,7,24-cholestatrienol, and 4 alpha-methyl-delta 8,24-cholestadienol. In cells exposed to aphidicolin, lanosterol accumulation was rapid (15 min) and reversible after a 3-h exposure when cells were rinsed and fresh medium added. It was concluded that aphidicolin inhibits the conversion of lanosterol to C-27 sterols. Although the exact mechanism of this inhibition has not yet been determined, addition of aphidicolin to 20,000 X g supernatant fractions of mouse liver homogenates inhibited the incorporation of [14C]mevalonolactone into cholesterol in a concentration-dependent manner, suggesting that aphidicolin may act directly on one or more of the enzymatic steps involved in lanosterol demethylation. The ubiquitous occurrence of an aphidicolin binding site on eukaryotic DNA alpha polymerases and the inhibitory action of aphidicolin at a proposed secondary regulatory site in sterol biosynthesis (lanosterol metabolism) suggest that a naturally occurring compound may exist which can regulate both DNA replication and cholesterogenesis.  (+info)

The relationship between the rate of hepatic sterol synthesis and the incorporation of [3H]water. (72/88)

The true rate of sterol synthesis in liver cells was determined by measurement of the weight of desmosterol produced over a given time period during incubations in the presence of triparanol. The simultaneous presence of tritiated water (3H2O) during the incubations permitted a direct observation of the weight of tritium incorporated into a given mass of newly synthesized sterol. The incorporation of tritium per atom of sterol carbon (H/C ratio) was lower than some previously reported values and suggests that a sizeable proportion of the reducing equivalents (NADPH) required for sterol synthesis arises via the pentose phosphate pathway. The H/C ratio changed significantly with length of the incubation period. The value of the ratio was also dependent upon whether the acetyl-CoA units utilized for sterol synthesis were derived predominantly from a carbohydrate or a fatty acid source.  (+info)