7-Hydroperoxycholesterol as a marker of oxidative stress in rat kidney induced by paraquat

The in vivo paraquat-induced oxidative stress in rat tissue was studied by analyzing cholesterol-derived hydroperoxide as an index of lipid peroxidation. Paraquat (10 mg/kg) was administered i.p. to rats. Rats were sacrificed and lung, liver, and kidney were collected 2, 24 h, and 5 d after paraquat injection. Lipids were extracted and analyzed by HPLC with post-column chemiluminescence. We found that two cholesterol-derived hydroperoxides, 7alpha-hydroperoxycholest-5-en-3beta-ol (7alpha-OOH) and 7beta-hydroperoxycholest-5-en-3beta-ol (7beta-OOH) were present in lungs of control animals (0.06 and 0.06 nmol/g, respectively), in livers (6.5 and 15.8 nmol/g, respectively) and in kidneys (3.7 and 8.9 nmol/g, respectively). In liver paraquat increased lipid peroxidation approximately by 60% over the levels of control animals only at 2 h after paraquat treatment. In kidney, augmented lipid peroxidation, 7alpha-OOH and 7beta-OOH (by 70% and 147%, respectively) above levels was found at 2 h after paraquat treatment. Interestingly, these increase remained in kidney of rats 5 d after a single dose of paraquat. In contrast, cholesterol-derived hydroperoxides were not affected in lung of paraquat dosed rats. This is the first report on 7alpha-OOH and 7beta-OOH accumulations in rat liver and kidney, and it seems to reflect greater oxidative stress in the pathology of kidney of rats treated with acute paraquat at low dose.     

Oxysterols increase in diabetic rats

To address whether diabetes enhances lipid peroxidation and attenuates nitric oxide (NO) generation resulting in tissue complications, we measured oxysterols and NO metabolites (NOx) in the tissues of diabetic Wistar rats. After 4 weeks of streptozotocin injection (STZ, 80?mg/kg, i.p.), we measured 7α- and 7β-hydroperoxycholest-5-en-3β-ol (7α-OOH and 7β-OOH), 7α- and 7β-hydroxycholesterol (7α-OH and 7β-OH) and 7-ketocholesterol (7-keto) by HPLC in the kidneys, heart, and liver. All the oxysterols were much higher in the diabetic than in sham rats, while the extent of the increase was higher in the order of the kidney, heart, and liver. Together with high blood urea nitrogen, the data indicate that the kidney is the predominant target of early diabetic complications. Plasma NOx were decreased by 20% in the STZ rats. The enhanced oxidative stress in diabetes would increase oxysterols by peroxidation, while superoxide is known to reduce NO by reaction to form another potent oxidant peroxynitrite.     

Oxysterols As Indices of Oxidative Stress in Man After Paraquat Ingestion

The aim of this study is to evaluate oxidative stress in man after paraquat ingestion by analyzing 7 &#102 - and 7 &#103 -hydroperoxycholest-5-en-3 &#103 -ol (7 &#102 - and 7 &#103 -OOH) as well as oxysterols, cholesterol oxidation products, as indices of lipid peroxidation. Lung, kidney, and liver were collected at autopsy from seven patients with paraquat poisoning and seven controls matched for age and sex. We identified for the first time 7-ketocholesterol (7-keto) and 7-hydroxycholesterol (7 &#102 -OH and 7 &#103 -OH) in human kidney by LC-MS. Next, we quantified 7 &#102 -OOH and 7 &#103 -OOH by HPLC with postcolumn chemiluminescence as well as oxysterols by HPLC-UV. Both 7 &#102 -OOH and 7 &#103 -OOH detected in lung and kidney from the controls were as low as the paraquat group. In contrast, we found both 7-keto and 7 &#103 -OH in lung and 7-keto in kidney from the paraquat group were significantly higher than from the controls. This is the first report on accumulated oxysterols in lung and kidney from human paraquat poisoning. It seems to reflect greater oxidative stress in the pathology of paraquat intoxication.     

Effect of Chronic Ethanol Feeding on Oxysterols in Rat Liver

It was our hypothesis that, as a consequence of increased oxidative stress, cholesterol-derived hydroperoxides and oxysterols are increased in livers of rats exposed to ethanol. To test this we dosed Wistar rats (approximately 0.1 kg initial body weight) with ethanol chronically (rats fed a nutritionally complete liquid diet containing ethanol as 35% of total calories; sampled liver at approximately 6-7 weeks). We measured concentrations of 7 &#102 - and 7 &#103 -hydroperoxycholest-5-en-3 &#103 -ol (7 &#102 -OOH and 7 &#103 -OOH) as well as 7 &#102 - and 7 &#103 -hydroxycholesterol (7 &#102 -OH and 7 &#103 -OH), and 3 &#103 -hydroxycholest-5-en-7-one (also termed 7-ketocholesterol; 7-keto). In response to chronic alcohol feeding, there were significant elevations in the concentrations of 7 &#102 -OOH (+169%, P =0.005 ) and 7 &#103 -OOH (+199%, P =0.011 ). Increases in the concentrations of hepatic 7-keto (+74%, P =0.01 ) and decreases in cholesterol ( &#109 43%; P =0.03 ) also occurred. In contrast, the concentrations of both 7 &#102 -OH and 7 &#103 -OH were not significant (NS). However, when oxysterols in chronic ethanol-fed rats were expressed relative to cholesterol there were significant increases in 7-keto/cholesterol ( P =0.0006), 7 &#102 -OH/cholesterol ( P =0.0018) and 7 &#103 -OH/cholesterol ( P =0.0047). In conclusion, this is the first report of increased 7 &#102 -OOH, 7 &#103 -OOH, and 7-keto in liver of rats and their elevation in chronic experimental alcoholism represent evidence of increased oxidative stress.     

Enzymatic isomerization (Δ7 → Δ8) of the nuclear double bond of 14α-alkyl substituted sterol precursord of cholesterol

The catalysis by rat liver microsomes under anaerobic conditions, of the conversion of [3α-³H]14α-methyl-5α-cholest-7-en-3β-ol and of [2,4-³H]14α-hydroxymethyl-5α-cholest-7-en-3β-ol to labeled 14α-methyl-5α-cholest-8-en-3β-ol and 14α-hydroxymethyl-5α-cholest-8-en-3β-ol, respectively, has been demonstrated. This finding is of importance in evaluating past research in this area and in consideration of pathways and mechanisms involved in enzymatic removal of carbon atom 32 of 14α-methyl sterols. Also described herein are syntheses of [2,4-³H]14α-hydroxymethyl-5α-cholest-7-en-3β-ol and 3β-acetoxy-14α-methyl-5α-cholest-8-ene.     

Presence of regio-isomeric cholesteryl linoleate hydroperoxides and hydroxides in plasma from healthy humans as evidence of free radical-mediated lipid peroxidation in vivo

Abstract

Lipid hydroperoxides are the primary stable products of lipid peroxidation. We have developed an ultrasensitive method for the detection of lipid hydroperoxides¹ and found about 3 nM cholesteryl ester hydroperoxides (CE-OOH), mostly cholesteryl linoleate hydroperoxides (Ch18:2-OOH), in blood plasma obtained from healthy subjects.² Autoxidation of cholesteryl linoleate (Ch18:2) gives cholesteryl 13-hydroperoxy-9Z,11E-octadecadienoate (13ZE-Ch18:-OOH), cholesteryl 13-hydroperoxy-9E,11E-octadecadienoate (13EE-Ch18:2-OOH), cholesteryl 9-hydroperoxy-10E,12Z-octadecadienoate (9EZ-Ch18:2-OOH), and cholesteryl 9-hydroperoxy-10E,12E-octadecadienoate (9EE-Ch18:2-OOH). Enzymatic oxidation of Ch18:2 with 15-lipoxygenase gives predominantly only one product (13ZE-Ch18:2-OOH).³ To help elucidate the production mechanisms of cholesteryl linoleate hydroperoxides in vivo, we examined the distribution of Ch18:2-O(O)H regioisomers in human blood plasma.     

Inhibitors of sterol biosynthesis. Syntheses of 14α-alkyl substituted 15-oxygenated sterols

The chemical syntheses of a number of 14α-alkyl substituted 15-oxygenated sterols have been pursued to permit evaluation of their activity in the inhibition of the biosynthesis of cholesterol and other biological effects. Described herein are the first chemical syntheses of 14α-ethyl-5α-cholest-7-en-3β-ol-15-one, bis-3β,15α-acetoxy-14α-ethyl-5α-cholest-7-ene, 3β-acetoxy-14α-ethyl-5α-cholest-7-en-15β-ol, 14α-ethyl-5α-cholest-7-en-3β,15β-diol, 14α-ethyl-5α-cholest-7-en-3β,15α-diol, 3β-hexadecanoyloxy-14α-ethyl-5α-cholest-7-en-15α-ol, 3β-hexadecanoyloxy-14α-ethyl-5α-cholest-7-en-15β-ol, bis-3β,15α-hexadecanoyloxy-14α-ethyl-5α-cholest-7-ene, 3β-hexadecanoyloxy-14α-ethyl-5α-cholest-7-en-15-one, 3α-benzoyloxy-14α-ethyl-5α-cholest-7-en-15-one, 14α-ethyl-5α-cholest-7-en-3α-ol-15-one, 14α-ethyl-5α-cholest-7-en-15-on-3β-yl pyridinium sulfate, 14α-ethyl-5α-cholest-7-en-15-on-3β-yl potassium sulfate (monohydrate), 14α-ethyl-5α-cholest-7-en-15-on-3α-yl pyridinium sulfate, 14α-ethyl-5α-cholest-7-en-15-on-3α-yl potassium sulfate (monohydrate), 3β-ethoxy-14α-ethyl-5α-cholest-7-en-15-one, 3β-acetoxy-14α-n-propyl-5α-cholest-7-en-15-one, 14α-n-propyl-5α-cholest-7-en-3β-ol-15-one, bis-3β, 15α-acetoxy-14α-n-propyl-5α-cholest-7-ene, 3β-acetoxy-14α-n-propyl-5α-cholest-7-en-15β-ol, 14α-n-propyl-5α-cholest-7-en-3β, 15α-diol, 14α-n-propyl-5α-cholest-7-en-3β, 15β-diol, 14α-n-butyl-5α-cholest-7-en-3β-ol-15-one, 3β-acetoxy-14-α-n-butyl-5α-cholest-7-en-15-one, bis-3β,15α-acetoxy-14α-n-butyl-5α-cholest-7-ene, 3β-acetoxy-14α-n-butyl-5α-cholest-7-en-15β-ol, 14α-n-butyl-5β-cholest-7-en-3β, 15β-diol, and 14α-n-butyl-5α-cholest-7-en-3β, 15α-diol.     

Biotransformation of 5-en-3β-ol steroids by Mucor circinelloides lusitanicus

In this work, we report the mode of biotransformation of 5-en-3β-ol steroids using Mucor circinelloides lusitanicus for the first time. Here, we selected seven 5-en-3β-ol steroids as substrates. The main characteristic of the fungus was to introduce a 7α-hydroxyl group into substrates 1--5. With substrate 2, 3β, 7α, 11α-trihydroxypregna-5-en-20-one (2b) was obtained as the final product in good yield (46.4%). All the metabolites were determined by infrared spectra, high-resolution mass spectrometry, proton nuclear magnetic resonance, and carbon-13 nuclear magnetic resonance.     

STEROL DISTRIBUTION IN THE GENUS HETEROCAPSA (PYRRHOPHYTA)1

The sterol composition of seven strains of marine peridinioid dinoflagellates comprising the four known species of Heterocapsa Stein was examined by gas chromatography-mass spectrometry to determine the utility of these compounds in systematics. Cholest-5-en-3β-ol (cholesterol), 24-methyl-cholest-5-en-3β-ol (24-methylcholesterol), 4α,24(S)-dimethyl-5α-cholestan-3β-ol (4,24-dimethylcholestanol), 4α,23,24(R)-trimethyl-5α-cholest-22-en-3β-ol (dinosterol), 4α,23ξ,24ξ-trimethyl-5α-cholestan-3β-ol (dihydrodinosterol), and an unknown sterol were detected. Sterol composition does not vary significantly from species to species within the genus Heterocapsa and thus cannot be used for species differentiation. Sterols may, however, have value in defining the properties of dinoflagellate taxa above the family level. Over the course of the growth curve for Heterocapsa niei (Loeblich) Morrill & Loeblich 4,24-dimethylcholestanol and dinosterol covaried, suggesting that 4,24-dimethylcholestanol is converted into dinosterol by a previously proposed bioalkylation scheme.     

Sterol profiles of red algae

Twelve species of red algae belonging to the Orders Gelidiales, Cryptonemiales and Gigartinales were examined for sterols. Four species contained cholestan-3β-ol as the major sterol, accompanied by C₂₆, C₂₈ and C₂₉ stanols. Sterols not previously reported in algae were 24-dimethyl-5α-chol-22-en-3β-ol, cholest-22-en-3β-ol, cholest-7-en-3β-ol, 24ξ-methylcholest-22-en-3β-ol, 24-methylenecholestan-3β-ol, 24ξ-ethylcholestan-3β-ol and isofucostanol.     

Structural requirement of sterol nucleus for the silkworm growth and development

Several cholesterol analogs structurally modified in nuclear substitutions were tested for sustaining the growth of the silkworm $\text{Bombyx mori}$. 5α-Cholest-7-en-3β-ol, 5,7-cholestadien-3β-ol and cholesteryl acetate can replace cholesterol as sterol source for $\text{B. mori.}$ Considerably good growth was also obained with 5α-cholest-14-en-3β-ol and 5α-cholesta-6,8(14)-dien-3β-ol. Other sterols tested were either partially effective or ineffective as nutrients.     

Dinoflagellate sterols IV: Isolation and structure of 4α,23ξ,24ξ-trimethylcholestanol from the dinoflagellate Glenodiniumhallii

The dinoflagellate $\text{Glenodinium}$$\text{hallii}$ was investigated for its sterol composition. Five of the six sterols were isolated and identified as cholest-5-en-3β-ol, (24ξ)-24-methylcholest-5-en-3β-ol, stigmasta-5,22-dien-3β-ol, (22E,24R)-4α,23,24-trimethyl-5α-cholest-22-en-3β-ol, and 4α,23ξ,24ξ-trimethyl-5α-cholestan-3β-ol.     

Effect of ay-9944 on sterol biosynthesis in Chlorella sorokiniana

When Chlorella sorokiniana was grown in the presence of 4 ppm AY-9944 total sterol production was unaltered in comparison to control cultures. However, inhibition of sterol biosynthesis was shown by the accumulation of a number of sterols which were considered to be intermediates in sterol biosynthesis. The sterols which were found in treated cultures were identified as cyclolaudenol, 4α,14α-dimethyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 4α,14α-dimethyl -5α-ergosta-8,25-dien-3β-ol, 14α-methyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 24-methylpollinastanol, 14α-methyl-5α-ergost-8-en-3β-ol, 5α-ergost -8(14)-enol, 5α-ergost-8-enol, 5α-ergosta-8(14),22-dienol, 5α-ergosta-8,22-dienol, 5α-ergosta-8,14-dienol, and 5α-ergosta-7,22-dienol, in addition to the normally occurring sterols which are ergosterol, 5α-ergost-7-enol, and ergosta-5,7-dienol.The occurrence of these sterols in the treated culture indicates that AY-9944 is an effective inhibitor of the Δ⁸ → Δ⁷ isomerase and Δ¹⁴-reductase, and also inhibits introduction of the Δ²²-double bond. The occurrence of 14α-dimethyl-5α-ergosta-8,25-dien-3β-ol and 14α-methyl-9β,19-cyclo-5α-ergost -25-en-3β-ol is reported for the first time in living organisms. The presence of 25-methylene sterols suggests that they, and not 24-methylene derivatives, are intermediates in the biosynthesis of sterols in C. sorokiniana.     

Inhibition of sterol biosynthesis by 14α-hydroxymethyl sterols

14α-Hydroxymethyl-5α-cholest-7-en-3β-ol (I) and 14α-hydroxymethyl-5α-cholest-6-en-3β-ol (II) have been prepared by chemical synthesis from 3β-acetoxy-7α,32-epoxy-14α-methyl-5α-cholestane. Compound I, previously shown to be efficiently convertible to cholesterol upon incubation with rat liver homogenate preparations, has been found to be a potent inhibitor of sterol synthesis in animal cells in culture. Compound I caused a 50% reduction of the levels of HMG-CoA reductase activity in cultures of L cells and fetal liver cells at concentrations of 3 × 10^?6 M and 8 × 10^?6 M, respectively. Compound II, the Δ⁶-analogue of I, caused a 50% suppression of the enzyme activity in the two cell types at even lower concentrations, 5 × 10^?7 M and 2 × 10^?6 M, respectively. Concentrations of I and II required to specifically inhibit sterol synthesis from acetate were similar to those required to suppress the levels of HMG-CoA reductase activity.     

Selenium deficiency potentiates paraquat-induced lipid peroxidation in isolated perfused rat lung

Glutathione peroxidase (GSHPx), a seleno-enzyme, reduces lipid hydroperoxides while producing oxidized glutathione (GSSG), which can efflux from cells. To study the role of GSHPx in antioxidant defense, isolated lungs from selenium-deficient rats were perfused for 2 h with or without 1 mM paraquat. Perfusate GSSG was measured as an index of GSHPx activity, and malondialdehyde (MDA) as an index of lipid peroxidation. Selenium deficiency decreased lung GSHPx activity 75-80%. During perfusion control lungs showed GSSG efflux of 8.5 +/- 4.5 nmol/h and with paraquat 49.1 +/- 12.1 nmol/h. Selenium-deficient lungs with or without paraquat showed GSSG efflux of 16.4 +/- 5.3 and 13.7 +/- 8.9 nmol/h, respectively. MDA efflux occurred only in paraquat-perfused selenium-deficient lungs (7.8 +/- 2.7 nmol/h). Lung homogenates from this group had lower GSH + GSSG than the other three groups. These results indicate an inverse correlation between GSSG efflux and MDA accumulation from paraquat-perfused lungs and suggest that increased turnover of the GSHPx reaction protects paraquat-perfused lungs from lipid peroxidation.     

Chemical syntheses of 5α-cholesta-6,8(14)-dien-3β-ol-15-one and related 15-oxygenated sterols

Hydroboration of 5α-cholesta-8,14-dien-3β-ol (I) gave 5α-cholest-8-en-3β,15α-diol (IV) in 89% yield. 5α-Cholest-7-en-3β,15α-diol (V) was prepared in 91% yield by hydroboration of 5α-cholesta-7,14-dien-3β-ol (II). Hydroboration of 27:63 mixture of I and II gave IV and V in 18% and 70% yields, respectively. 5α-Cholest-8-en-15α-ol-3-one and 5α-cholest-7-en-15α-ol-3-one were prepared in high yields from IV and V, respectively, by either selective oxidation with silver carbonate-celite or by enzymatic oxidation using cholesterol oxidase. 7α,8α-Epoxy-5α-cholestan-3β,15α-diol (VIII) was prepared in 93% yield by treatment of V with m-chloroperbenzoic acid. 5α-Cholest-8(14)-en-7α-ol-3,15-dione (IX) was prepared in 56% yield by oxidation of VIII with pyridinium chlorochromate followed by treatment of the crude product with acid. Compound IX was also obtained in 72% yield by selective chemical oxidation of 5α-cholest-8(14)-en-3β,7α,15α-triol. 5α-Cholesta-6,8(14)-dien-3,15-dione (X) was prepared in 89% yield by treatment of IX with p-toluenesulfonic acid under controlled conditions. Reduction of X with lithium tri-tert-butoxyaluminum hydride under controlled conditions gave 5α-cholesta-6,8(14)-dien-3β-ol-15-one in 84% yield.     

The sterols of Argania spinosa seed oil

The sterol fraction of Argan seed oil (Argania spinosa) contains two main compounds, 5α-stigmast-7-en-3β-ol (schottenol) and 5α-stigmast-7,22(E)-dien-3β-ol (spinasterol).     

The fatty acid and sterol composition of two marine dinoflagellates

The fatty acid, sterol and chlorophyll pigment compositions of the marine dinoflagellates Gymnodinium wilczeki and Prorocentrum cordatum are reported. The fatty acids of both algae show a typical dinoflagellate distribution pattern with a predominance of C₁₈, C₂₀ and C₂₂ unsaturated components. The acid 18:5ω3 is present at high concentration in these two dinoflagellates. G. wilczeki contains a high proportion (93.4%) of 4-methyl-5α-stanols including 4,23,24-trimethyl-5α-cholest-22E-en-3β-ol (dinosterol), dinostanol and 4,23,24-trimethyl-5α-cholest-7-en-3β-ol reported for the first time in dinoflagellates. The role of this sterol in the biosynthesis of 5α-stanols in dinoflagellates is discussed. P. cordatum contains high concentrations of a number of δ ²⁴⁽²⁸⁾-sterols with dinosterol, 24-methylcholesta-5,24(28)-dien-3β-ol, 23,24-dimethylcholesta-5,22E-dien-3β-ol, 4,24-dimethyl-5α-cholest-24(28)-en-3β-ol and a sterol identified as either 4,23,24-trimethyl- or 4-methyl-24-ethyl-5α-cholest-24(28)-en-3β-ol present as the five major components. The role of marine dinoflagellates in the input of both 4-methyl- and 4-desmethyl-5α-stanols to marine sediments is discussed.     

Configuration at C-24 of sterols from the liverwort Palavicinnia lyellii

The 4-desmethylsterol fraction of the liverwort Palavicinnia lyellii is composed of 36% 24β-methylcholest-5-en-3β-ol (dihydrobrassicasterol), 16% 24α-methylcholest-5-en-3β-ol (campesterol), 33% 24α-ethylcholest-5-en-3β-ol (sitosterol) and 15% 24ξ-ethylcholesta-5,22-dien-3β-ol.     

Macrophage mitochondrial damage from StAR transport of 7-hydroperoxycholesterol: Implications for oxidative stress-impaired reverse cholesterol transport

StAR family proteins in vascular macrophages participate in reverse cholesterol transport (RCT). We hypothesize that under pathophysiological oxidative stress, StARs will transport not only cholesterol to macrophage mitochondria, but also pro-oxidant cholesterol hydroperoxides (7-OOHs), thereby impairing early-stage RCT. Upon stimulation with dibutyryl-cAMP, RAW264.7 macrophages exhibited a strong time-dependent induction of mitochondrial StarD1 and plasma membrane ABCA1, which exports cholesterol. 7α-OOH uptake by stimulated RAW cell mitochondria (like cholesterol uptake) was strongly reduced by StarD1 knockdown, consistent with StarD1 involvement. Upon uptake by mitochondria, 7α-OOH (but not redox-inactive 7α-OH) triggered lipid peroxidation and membrane depolarization while reducing ABCA1 upregulation. These findings provide strong initial support for our hypothesis.