Epoxidation of 6,7- and 10,11-oxidosqualenes by the squalene epoxidase present in rat liver microsomes

Incubation of 6,7-oxidosqualene (2) or 10,11-oxidosqualene (3) with rat liver microsomes led to the formation of mixtures of the corresponding dioxidosqualenes (4 and 5, or 6 and 7, respectively), resulting from the epoxidation of 2 and 3 at their terminal double bonds. The epoxidation requires the presence of both NADPH and FAD. In addition, the HPLC analysis of the Mosher esters resulting from the controlled hydrolysis of dioxide 5 to give the corresponding epoxydiols 9 followed by derivatization with (R)-MTPA, showed that the epoxidation had been stereoselective. These facts support the hypothesis that these dioxidosqualenes had been generated by the squalene epoxidase present in the incubation medium.     

Stimulation by unsaturated fatty acid of squalene uptake in rat liver microsomes

Supernatant protein factor (SPF) and anionic phospholipids such as phosphatidylglycerol (PG) stimulate squalene epoxidase activity in rat liver microsomes by promoting [3H]squalene uptake as well as substrate translocation (Chin, J., and K. Bloch. 1984. J. Biol. Chem. 259: 11735-11738). This process is postulated to be membrane-mediated and not carrier-mediated. Here we show that treatment of PG with phospholipase A2 in the presence of bovine serum albumin abolishes the stimulatory effect of SPF on epoxidase activity. Disaturated fatty acyl-PGs are not as effective as egg yolk lecithin PG in the SPF effect. These findings suggest an important role for the unsaturated fatty acid moiety of PG. We also show that at submicellar concentrations, cis-unsaturated fatty acids stimulate microsomal epoxidase activity whereas saturated fatty acids do not. This effect is due to an increase in substrate uptake which in turn may facilitate substrate availability to the enzyme.     

The rabbit liver microsomal biotransformation of 1,1-dialkylethylenes: Enantioface selection of epoxidation and enantioselectivity of epoxide hydrolysis

The rabbit liver microsomal biotransformation of α-methylstyrene ( 1a ), 2-methyl-1-hexene ( 1b ), 2,4,4-trimethyl-1-pentene ( 1c ), and 2,3,3-trimethyl-1-butene ( 1d ) has been investigated with the aim at establishing the enantioface selection of the cytochrome P-450-promoted epoxidation of the double bond and the enantioselectivity of microsomal epoxide hydrolase (mEH)-catalyzed hydrolysis of the resulting epoxides. GLC on a Chiraldex G-TA (ASTEC) column was used to determine the enantiomeric composition of the products. The epoxides 2 first produced in incubations carried out in the presence of an NADPH regenerating system were not detected, being rapidly hydrolyzed by mEH to diols 3 . The enantiomeric composition of the latter showed that no enantioface selection occurred in the epoxidation of 1c and 1d , and a very low (8%) ee of the (R)-epoxide was formed from 1b . Incubation of racemic epoxides 2b–d with the microsomal fraction showed that the mEH-catalyzed hydrolysis of 2c and 2d was practically nonenantioselective, while that of 2b exhibited a selectivity E = 4.9 favoring the hydrolysis of the (S)-enantiomer. A comparison of these results with those previously obtained for linear and branched chain alkyl monosubstituted oxiranes shows that the introduction of the second alkyl substituent suppresses the selectivity of the mEH reaction of the latter and reverses that of the former substrates. © 1994 Wiley-Liss, Inc.     

Species difference in the metabolic activation of phenacetin by rat and hamster liver microsomes

Phenacetin is mutagenic in Salmonella typhimurium TA 100 when liver 9,000 X g supernatant fractions from PCB-treated hamsters instead of rats are used. A mechanism of the species difference in phenacetin mutagenicity was investigated. By high-performance liquid chromatography analysis, it was found that phenacetin is activated to direct-acting mutagens through N-hydroxylation and deacetylation by hamster liver microsomes. Although no significant species difference was observed in N-hydroxylation, rates of deacetylation were 9 to 150 times higher in hamsters than in rats. The results indicate that the marked species difference in phenacetin mutagenicity is due to the difference in deacetylation activity between rat and hamster liver microsomes.     

Radiosensitive antioxidant membrane-bound factors in rat liver microsomes: I. The roles of glutathione and vitamin E

In vitro lipid peroxidation initiated by NADPH/ADP/Fe3+ reveals an alteration of rat liver microsomal antioxidant factors at day D+4 after whole-body gamma irradiation (8Gy). This alteration is partly reversed by GSH, and more efficiently by Trolox C, a water-soluble analog of vitamin E. This reversion by Trolox C, together with the observed 50% decrease in vitamin E content in microsomes of irradiated rats as compared to those of control animals, indicate that Trolox C acts as a free-radical scavenger like and in place of vitamin E. The antioxidant action of Trolox C is not improved in the presence of GSH, which suggests that the former acts earlier than the latter on the autoxidative free-radical chain reactions. Neither GSH, nor Trolox C, nor both antioxidants totally inhibit in vitro lipid peroxidation, which appeals attention on the possible role of extra-microsomal antioxidant factors, especially cytosolic ones.     

The esterification of dolichol by rat liver microsomes.

The incubation of 1-[3H)dolichols with cell-free preparations from various rat tissues resulted in the formation of a labeled material which possessed the characteristics of synthetic dolichol palmitate. Rat liver microsomes were found to be a good source of the acyltransferase activity, and the properties of the reaction were investigated using microsomal preparations. The reaction did not require ATP, CoA, or Mg2+ and was stimulated by the addition of phosphatidylcholine. The esterification of dolichol appears to be similar to the esterification of retinol. The fact that the esterification of dolichol is not depressed even in the presence of a several-fold excess of retinol is evidence that the two reactions are catalyzed by different enzymes.     

Radiosensitive antioxidant membrane-bound factors in rat liver microsomes: II. The role of cytosol

In vitro lipid peroxidation initiated by NADPH/ADP/Fe3+ reveals an alteration of rat liver microsomal membrane at day D+4 after whole-body gamma irradiation (8Gy). This alteration is reversed by Trolox-C 100 microM plus GSH 2mM in association with the soluble supernatant from irradiated or control rats. The antioxidant capacity of the soluble supernatant is not inactivated by gamma irradiation. We conclude that the control of in vivo lipid peroxidation is membranous and cytosolic, and that the preservation of this activity is GSH and Vitamin E dependent.     

Degradation of heme by a soluble peptide of heme oxygenase obtained from rat liver microsomes by mild trypsinization.

A tryptic peptide of heme oxygenase obtained after solubilization of rat liver microsomes by mild trypsin treatment was purified. The purified peptide gave only a single protein band with a molecular mass of 28 kDa on SDS/PAGE. The tryptic peptide, like the native heme oxygenase, readily bound with substrate heme forming a hemeprotein transiently. The absorption spectra of the ferric, ferrous, ferrous-CO and ferrous-O2 forms of the resulting complex resembled those of the corresponding forms of the complex of heme and the native enzyme. Ferric heme bound to the tryptic peptide was quantitatively decomposed to biliverdin on incubation with a mixture of ascorbic acid and desferrioxamine, indicating that the tryptic peptide still retained catalytic activity. These observations suggest that heme oxygenase has two domains, a hydrophilic and a hydrophobic domain, and that the two domains are folded almost independently of each other. An NADPH-cytochrome-P-450 reductase system composed of NADPH and detergent-solubilized NADPH-cytochrome-P-450 reductase readily reduced the ferric heme bound to the tryptic peptide, but failed to transfer the second electron required for rapid heme degradation, suggesting that the hydrophobic domain of heme oxygenase is important for receiving the second electron from the reductase.     

Inhibition by polyamines of lipid peroxide formation in rat liver microsomes.

Both NADPH- and ascorbic acid-dependent lipid peroxidations were inhibited by spermine, the degree of inhibition being greater with the former peroxidation. The effective concentration of spermine required for inhibition was higher when larger amounts of microsomes were used. However, the activities of NADPH-cytochrome c reductase and NADPH-peroxidase were not influenced by spermine. These results suggest that spermine inhibits lipid peroxidation by binding to phospholipids in the microsomes.     

Biotransformation of myrislignan by rat liver microsomes in vitro

Myrislignan (1), erythro-(1R,2S)-2-(4-allyl-2,6-dimethoxyphenoxyl)-1-(4-hydroxy-3-methoxyphenyl) propan-1-ol, is a major acyclic neolignan in seeds of Myristica fragrans. Studies have suggested that myrislignan may deter feeding activity, but little is known about its metabolism. We investigated the biotransformation of myrislignan by rat liver microsomes in vitro. Seven metabolites were produced by liver microsomes from rats pre-treated with sodium phenobarbital. These were identified, using spectroscopic methods, as myrislignanometins A-G (2-8), respectively.     

PI3K/AKT通路在红细胞生成素肾保护中的作用

红细胞生成素作为临床上最常用的纠正贫血的药物,近年随着研究的不断深入,其非造血的组织器官保护作用逐渐被认识。PI3K/AKT通路作为介导红细胞生成素生物学作用的通路之一,在红细胞生成素对各种急慢性肾脏疾病的保护过程中占据重要地位。本文就PI3K/AKT通路在红细胞生成素肾保护中的作用方面的研究进展作一综述。     

The stereospecificity of biosynthesis of squalene and β-amyrin in Pisum sativum

The distribution of deuterium in squalene and β-amyrin, biosynthesized from mevalonic acid-6,6,6-d₃ in Pisum sativum, has been examined b     

Formation of lipid peroxides in isolated rat liver microsomes by singlet molecular oxygen.

Rat liver microsomes were incubated in neutral aqueous solution of potassium peroxychromate, a system which generates singlet molecular oxygen. Such incubation resulted both in a rapid decline in NADPH-cytochrome c reductase activity, and in an increase in formation of lipid peroxides. These reactions were not inhibited by either superoxide dismutase (SOD) or mannitol, nor were they entirely duplicated by incubating microsomes with hydrogen peroxide. However, a high concentration of 1,4-diazabicyclo-[2,2,2]octane (DABCO), a known scavenger of singlet oxygen, prevented both decline in reductase activity and formation of lipid peroxides. These results suggest that the observed effects are, in fact, attributable to singlet oxygen, and not to hydrogen peroxide, superoxide radical, or hydroxyl radical.     

Mutagenicity of dimethylnitrosamine in the metabolic process by rat liver microsomes

The mutagenicity of dimethylnitrosamine (DMN) for bacteria was investigated by means of the metabolic activation process of the compound with rat liver microsomes.Three strains of streptomycin (SM)-dependent Escherichia coli having tetracycline (TC)-resistance factor (Sd-E. coli(TC)) were derived for this study. The reverse mutation in these strains from SM dependence to non-dependence was used as the marker for mutagenicity. The drug resistance factor (R factor) which was transferred to these strains was used in order to get around the bacterial contamination throughout the experiments. The study of the mutagenicity of DMN metabolites has been made by incubating DMN with rat liver microsomes and cofactor system in the presence of indicator bacterial cells.The reverse mutation was markedly induced for all of three strains in the complete incubation mixture but it was not observed when the cofactor system was omitted or the liver microsomal suspension was replaced by the kidney cell sap. When the indicator bacterial cells were added to the mixture in which DMN was previously incubated with the microsomes and cofactor system, the mutagenicity was extremely decreased.     

The stimulatory effects of asbestos on NADPH-dependent lipid peroxidation in rat liver microsomes.

Lipid peroxidation in rat liver microsomes induced by asbestos fibres, crocidolite and chrysotile, is greatly increased in the presence of NADPH, leading to malondialdehyde levels comparable with those induced by CCl4, a very strong inducer of lipid peroxidation. This synergic effect only occurs during the first minutes and could be explained by an increase or a regeneration of the ferrous active sites of asbestos by NADPH, which in turn could rapidly be prevented by the adsorption of microsomal proteins on the surface of the fibres. It is not inhibited by superoxide dismutase, catalase and mannitol, indicating that oxygen radicals are not involved in the reaction. It is also not inhibited by desferrioxamine, indicating that it is not due to a release of free iron ions in solution from the fibres. Lipid peroxidation in NADPH-supplemented microsomes is also greatly increased upon addition of magnetite. This could be linked to the presence of ferrous ions in this solid iron oxide, since the ferric oxides haematite and goethite are completely inactive.     

The roles of signaling pathways in liver repair and regeneration

The liver has remarkable regeneration potency that restores liver mass and sustains body hemostasis. Liver regeneration through signaling pathways following resection or moderate damages are well studied. Various cell signaling, growth factors, cytokines, receptors, and cell types implicated in liver regeneration undergo controlled hypertrophy and proliferation. Some aspects of liver regeneration have been discovered and many investigations have been carried out to identify its mechanisms. However, for optimizing liver regeneration more should be understood about mechanisms that control the growth of hepatocytes and other liver cell types in adults. The current paper deals with the possible applicability of liver regeneration signaling pathways as a target for therapeutic approaches and preventing various liver damages. Furthermore, the latest findings of spectrum-specific signaling pathway mechanisms that underlie liver regeneration are briefly described.