Effects of the flaxseed lignans secoisolariciresinol diglucoside and its aglycone on serum and hepatic lipids in hyperlipidaemic rats.

The present study involved a comparative analysis of the effects of purified flaxseed lignans, secoisolariciresinol diglucoside (SDG) and its aglycone metabolite (SECO), in hyperlipidaemic rats. For hypercholesterolaemia, female Wistars (six rats per group) were fed a standard or 1 % cholesterol diet and orally administered 0, 3 or 6 mg SDG/kg or 0, 1.6 or 3.2 mg SECO/kg body weight once daily for 4 weeks. Hypertriacylglycerolaemia was induced in male Sprague-Dawley rats (ten rats per group) by supplementing tap water with 10 % fructose. These rats were orally administered 0, 3 or 6 mg SDG/kg body weight once daily for 2 weeks. Fasting blood samples (12 h) were collected predose and at the end of the dosing period for serum lipid analyses. Rats were killed and livers rapidly excised and sectioned for lipid, mRNA and histological analyses. Chronic administration of equimolar amounts of SDG and SECO caused similar dose-dependent reductions in rate of body-weight gain and in serum total and LDL-cholesterol levels and hepatic lipid accumulation. SDG and SECO failed to alter hepatic gene expression of commonly reported regulatory targets of lipid homeostasis. SDG had no effect on serum TAG, NEFA, phospholipids and rate of weight gain in 10 % fructose-supplemented rats. In conclusion, our data suggest that the lignan component of flaxseed contributes to the hypocholesterolaemic effects of flaxseed consumption observed in humans. Future studies plan to identify the biochemical mechanism(s) through which flaxseed lignans exert their beneficial effects and the lignan form(s) responsible.

Oxidation of 4-alkylphenols and catechols by tyrosinase: ortho-substituents alter the mechanism of quinoid formation.

Numerous phenols and catechols are known to be substrates for tyrosinase. While the catalytic mechanism of phenol oxidation by tyrosinase has been well studied, little work has been done to determine the influence of substituents on the reaction. In the present investigation, we explored the effects of changing substituents at the 2 and 6 position on the mechanism of tyrosinase-catalyzed oxidation of 4-allyl and 4-propylphenols and catechols. We have previously demonstrated that tyrosinase initially oxidizes hydroxychavicol (4-allyl-catechol) to an o-quinone (3,5-cyclohexadien-1,2-dione) which because of the relatively acidic protons in the benzyl position, readily isomerizes to the tautomeric p-quinone methide (4-allylidene-2,5-cyclohexadien-1-one, QM) (Bolton et al., 1994). We have confirmed through GSH trapping studies that oxidation of 4-allylphenol by tyrosinase yields the same o-quinone GSH conjugates as hydroxychavicol. In contrast, the presence of additional ortho substituents dramatically alters the mechanism of tyrosinase-catalyzed oxidation of 4-alkylphenols. For example, eugenol (4-allyl-2-methoxyphenol), which possesses 1 ortho-methoxy substituents, is not oxidized to a o-quinone or a QM. However, when both ortho o-quinones or QMs which may be selectively toxic to the malignant melanocyte. Although mammalian tyrosinase is much more substrate specific compared to the mushroom tyrosinase used in this study [42], it should be possible to identify compounds which are substrates for the mammalian form but are otherwise oxidatively stable. In order to develop such target compounds an improved understanding of substituent effects on tyrosinase-catalyzed oxidation of catechols and phenols is necessary. This should for the development of strategies for therapeutic compounds that are selectively toxic toward melanoma.

The reactivity of o-quinones which do not isomerize to quinone methides correlates with alkylcatechol-induced toxicity in human melanoma cells.

Catechols are widespread in the environment, especially as constituents of edible plants. A number of these catechols may undergo oxidative metabolism to electrophilic o-quinones (3,5-cyclohexadien-1,2-dione) by oxidative enzymes such as cytochrome P450 and peroxidases. Alkylation of cellular nucleophiles by these intermediates and the formation of reactive oxygen species, especially through redox cycling of o-quinones, could contribute to the cytotoxic properties of the parent catechols. In contrast, isomerization of the o-quinones to electrophilic quinone methides (4-methylene-2,5-cyclohexadien-1-one, QM) could cause cellular damage primarily through alkylation. In this investigation, we treated human melanoma cells with two groups of catechols. These cells have high levels of tyrosinase required to oxidize catechols to quinoids. For catechols which are oxidized to o-quinones that cannot isomerize to quinone methides or form unstable quinone methides, plots of the cytotoxicity data (ED50) versus the reactivity of the o-quinones gave an excellent linear correlation; decreasing o-quinone reactivity led to a decrease in the cytotoxic potency of the catechol. In contrast, catechols which are metabolized by the o-quinone/p-quinone methide bioactivation pathway were equally cytotoxic but showed no correlation between the reactivity of the o-quinones and the cytotoxic potency of the catechols. The most likely explanation for this effect is a change in cytotoxic mechanism from o-quinone-mediated inhibition of cell growth to a bioactivation pathway based on both o-quinone and p-QM formation. These results substantiate the conclusion that the involvement of the o-quinone/ QM pathway in catechol toxicity depends on a combination between the rate of enzymatic formation of the o-quinone, the rate of isomerization to the more electrophilic QM, and the chemical reactivity of the quinoids.

Mechanisms of dimer and trimer formation from ultraviolet-irradiated alpha-tocopherol.

Alpha-Tocopherol (alpha-TH) undergoes ultraviolet (UV)-induced photooxidation on the surface of mouse skin to produce a dihydroxydimer, a spirodimer, and trimers as the major products. To study the photochemistry involved, we UV-irradiated alpha-TH in a thin film on a glass petri dish. Photooxidation yielded a mixture of dihydroxydimer, spirodimer, and trimers. In the time-course studies, the dihydroxydimer accumulated and then was further oxidized, whereas the spirodimer and trimers accumulated more gradually. Reaction of two tocopheroxyl radicals forms the dihydroxydimer, whereas the spirodimer may be formed either by photooxidation of alpha-TH to an orthoquinone methide (o-QM) followed by a Diels-Alder reaction or by photooxidation of alpha-TH to the dihydroxydimer, followed by two-electron oxidation. Irradiation of a mixture of d10-labeled and unlabeled (d0) dihydroxydimer produced a mixture of labeled and unlabeled spirodimers as detected by positive atmospheric pressure chemical ionization-mass spectrometry. The absence of mixed label spirodimers among products indicated that direct oxidation of the dihydroxydimer is a facile route to the spirodimer and is probably the major spirodimer-forming reaction in alpha-TH photooxidations. Trimer formation from the dihydroxydimer and the spirodimer was observed, however, and requires an o-QM intermediate. Photooxidation of dl0-labeled and unlabeled (d0) dihydroxydimers yielded mixed isotopomers of the trimer products, thus demonstrating that the dihydroxydimer and spirodimers underwent conversion to o-QM intermediates. Photochemical conversion of alpha-TH to UV-absorbing dimer and trimer products may contribute to photoprotection by topically applied alpha-TH.

[Stable maintenance of dicentric mini-chromosomes in CHL4 mutants in yeast]. / Stabil'noe podderzhanie ditsentricheskikh mini-khromosom u mutanta drozhzhei po genu chl4.

Earlier we have identified the chl4-1 mutation in a screen for yeast mutants with increased loss of chromosome III and circular artificial minichromosome in mitosis. Mutation in the CHL4 gene leads to a 50-100-fold promotion in the rate of chromosome loss per cell division compared to the isogenic wild type strain. Detailed analysis of behaviour of the circular minichromosome marked by the CUP1 gene has shown that minichromosome nondisjunction (2:0 segregation) leading to an increase in the copy number of minichromosome in part of a cell population is the main reason of minichromosome instability in the mutant. The unique peculiarity of chl4-1 mutation is the ability of the strains carrying this mutation to stably maintain circular dicentric minichromosomes without any rearrangement during many generations. (In the wild type strains dicentric minichromosomes are extremely unstable. As a consequence of that there is a strong selection for cells harboring monocentric derivatives in a population of cells derived from a cell containing a dicentric plasmid). Introduction of the second centromere into one of the natural chromosomes (chromosomes II or III) in the chl4-1 mutant leads to the same dramatic consequences as that in the wild type strain (mitotic lag of cells harboring dicentric chromosomes and, as a result of that, selective pressure for cells harboring monocentric derivatives of dicentric chromosome). A genomic clone of CHL4 was isolated by complementation of the chl4-1 mutation. Nucleotide sequence analysis of CHL4 revealed a 1.4-kb open reading frame with a predicted 53-kDa protein sequence. Analyzing the sequence of the CHL4 protein we have found a region meeting the necessary requirements for the helix-turn-helix (HTH) structure. This region of the CHL4 protein has about 40% homology with the repressor of tryptophane operon (TrpR) of E. coli. A strain containing a null allele of CHL4 was viable under standard growth conditions, but had temperature-sensitive phenotype (conditional lethality at 34 degrees C). We suggest that the CHL4 gene product is one of the components of the segregation cell machinery.

[CHL15--a new gene controlling the replication of chromosomes in saccharomycetes yeast: cloning, physical mapping, sequencing, and sequence analysis]. / CHL15--novyi gen, kontroliruiushchii replikatsiiu khromosom u drozhzhei--sakharomitsetov: klonirovanie, fizicheskoe kartirovanie, sekvenirovanie i funktsional'nyi analiz.

We have analyzed the CHL15 gene, earlier identified in a screen for yeast mutants with increased loss of chromosome III and artificial circular and linear chromosomes in mitosis. Mutations in the CHL15 gene lead to a 100-fold increase in the rate of chromosome III loss per cell division and a 200-fold increase in the rate of marker homozygosis on this chromosome by mitotic recombination. Analysis of segregation of artificial circular minichromosome and artificially generated nonessential marker chromosome fragment indicated that sister chromatid loss (1:0 segregation) is a main reason of chromosome destabilization in the chl15-1 mutant. A genomic clone of CHL15 was isolated and used to map its physical position on chromosome XVI. Nucleotide sequence analysis of CHL15 revealed a 2.8-kb open reading frame with a 105-kD predicted protein sequence. At the N-terminal region of the protein sequences potentially able to form DNA-binding domains defined as zinc-fingers were found. The C-terminal region of the predicted protein displayed a similarity to sequence of regulatory proteins known as the helix-loop-helix (HLH) proteins. Data on partial deletion analysis suggest that the HLH domain is essential for the function of the CHL15 gene product. Analysis of the upstream untranslated region of CHL15 revealed the presence of the hexamer element, ACGCGT (an MluI restriction site) controlling both the periodic expression and coordinate regulation of the DNA synthesis genes in budding yeast. Deletion in the RAD52 gene, the product of which is involved in double-strand break/recombination repair and replication, leads to a considerable decrease in the growth rate of the chl15 mutant. We suggest that CHL15 is a new DNA synthesis gene in the yeast Saccharomyces cerevisiae.

Photoprotective actions of natural and synthetic melanins.

Melanins are thought to be important modulators of photochemistry in skin. Eumelanin, a black-brown pigment, is believed to protect against UV-induced photodamage, whereas pheomelanin, a red-yellow pigment, is believed to possess photosensitizing properties. To investigate the hypothesized dichotomy of melanins as both photoprotectants and photosensitizers, we examined the effects of melanins on UV-induced liposomal lipid peroxidation. Sepia melanin, a representative eumelanin, and both red hair pheomelanin and synthetic pheomelanin were employed in these studies. Both eumelanin and pheomelanin inhibited UVA/B- and UVA-induced liposomal lipid peroxidation in a concentration-dependent manner as measured by inhibition of conjugated diene formation. No change in protective properties of the melanins was observed in the presence of saturating levels of O2 during UVA irradiation. Pheomelanin irradiated with UVA/B or UVA induced superoxide-catalyzed reduction of nitroblue tetrazolium, whereas eumelanin did not. Melanins are known to bind various metals, and we examined the effect of iron on the photoproperties of melanins. Eumelanin complexed with Fe(III) did not inhibit UVA/B-induced lipid peroxidation, whereas pheomelanin complexed with Fe(III) stimulated UVA/B-induced lipid peroxidation. Thus, complexation with iron reversed the antioxidant effect of eumelanin and converted pheomelanin into a prooxidant. Analysis of lipid peroxidation products indicated that the oxidation was mediated by free radicals rather than by singlet oxygen. These data indicate that both eumelanin and pheomelanin exert antioxidant effects against UV-induced lipid peroxidation but that the prooxidant activities of pheomelanin result from pheomelanin-metal complexation.

UV-B-Induced photooxidation of vitamin E in mouse skin.

Topically applied alpha-tocopherol (alpha-TH, vitamin E) inhibits UV-B (290-320 nm) photocarcinogenesis, yet alpha-TH undergoes rapid photooxidation by UV-B in vitro. To examine the effect of UV-B on alpha-TH in vivo, we studied the fate of alpha-TH in UV-B-irradiated mouse skin. [14C]-alpha-TH was applied to mouse skin at various times prior to UV-B irradiation. UV-B irradiation for 1 h at a dose rate of 2.6-2.9 J m-2 s-1 resulted in consumption of 40-60% of the applied dose and formation of oxidation products. The major product fraction formed in UV-B-irradiated mice treated topically with alpha-TH contained an alpha-TH dihydroxy dimer and its two-electron oxidation product, a spirodimer. Products previously identified as being derived from photochemical or peroxyl radical scavenging reactions of alpha-TH were also observed, including alpha-tocopherolquinone (alpha-TQ), alpha-tocopherolquinone 2, 3-epoxide (alpha-TQE 1), alpha-tocopherolquinone 5,6-epoxide (alpha-TQE 2), and 8a-(hydroperoxy)epoxytocopherones. These results indicate that topically applied alpha-TH is extensively oxidized in skin and suggest that alpha-TH photoproducts may be involved in the observed effects of topically applied vitamin E in UV-B-irradiated skin.

Photoprotective actions of topically applied vitamin E.

Topical application of vitamin E has been shown to decrease the incidence of ultraviolet (UV)-induced skin cancer in mice. Vitamin E provides protection against UV-induced skin photodamage through a combination of antioxidant and UV absorptive properties. Topical application of alpha-tocopherol on mouse skin inhibits the formation of cyclobutane pyrimidine photoproducts. However, topically applied alpha-tocopherol is rapidly depleted by UVB radiation in a dose-dependent manner. The photooxidative fate of the alpha-tocopherol depends on the local environment of the vitamin E. alpha-Tocopherol quinone and alpha-tocopherol quinone epoxides are principal photoproducts of vitamin E that has penetrated into the epidermal layer of the skin, whereas tocopherol dimers and trimers are formed from alpha-tocopherol in a bulk phase at the skin surface. Dimer and trimer products may participate in prevention of UV-induced photodamage.

o-Methoxy-4-alkylphenols that form quinone methides of intermediate reactivity are the most toxic in rat liver slices.

The effects of p-alkyl substituents on the relative cytotoxicity of 4-alkyl-2-methoxyphenols were investigated in isolated rat liver slices. The derivatives of 4-alkyl-2-methoxyphenol studied were 4-methyl- (creosol), 4-ethyl-, 4-propyl-, 4-isopropyl-, 4-allyl-2-methoxyphenol (eugenol), as well as 4-allyl-2,6-dimethoxyphenol. The data were correlated with previous microsomal experiments which showed that all of the 4-alkyl-2-methoxyphenols were converted to quinone methides (QMs; 4-methylene-2,5-cyclohexadien-1-ones) via a cytochrome P450-catalyzed process [Bolton, J. L. Comeau, E., and Vukomanovic, V. (1995) Chem.-Biol. Interact., in press]. The present investigation showed little correlation between the rate of QM formation in microsomes and the relative toxicities of the alkylphenols, unless the QMs formed were of similar reactivity. In contrast, a plot of alkylphenol toxicity versus the relative hydrolysis rates of QMs derived from these phenols fit a parabolic equation with a minimum at the data for 4-isopropyl-2-methoxyphenol. These data suggest that in vivo oxidation of phenols to QMs which have lifetimes in the 10 s-10 min range results in cytotoxicity. QMs with reactivities outside this window are less toxic since the electrophile is either too stable for reaction with cellular nucleophiles or too reactive for nucleophilic cellular macromolecules to compete with solvent. These data suggest that a reactivity window exists for QMs which is a primary determinant of the extent of cytotoxic injury caused by these reactive electrophiles.

Reactions of beta-carotene with cigarette smoke oxidants. Identification of carotenoid oxidation products and evaluation of the prooxidant/antioxidant effect.

Recent intervention trials reported that smokers given dietary beta-carotene supplementation exhibited an increased risk of lung cancer and overall mortality. beta-Carotene has been hypothesized to promote lung carcinogenesis by acting as a prooxidant in the smoke-exposed lung. We have examined the interactions of cigarette smoke with beta-carotene in model systems. Both whole smoke and gas-phase smoke oxidized beta-carotene in toluene to several products, including carbonyl-containing polyene chain cleavage products and beta-carotene epoxides. A major product of the reaction was identified as 4-nitro-beta-carotene, which was formed by nitrogen oxides in smoke. Both cis and all-trans isomers of 4-nitro-beta-carotene were detected. The hypothesis that smoke-driven beta-carotene autoxidation exerts prooxidant effects was tested in a liposome system. Lipid peroxidation in dilinoleoylphosphatidylcholine liposomes exposed to gas-phase smoke was modestly inhibited by the incorporation of 0.1 mol % beta-carotene. Both the lipid soluble antioxidant alpha-tocopherol and the water soluble antioxidant ascorbate were oxidized more slowly by gas-phase smoke exposure in liposomes containing beta-carotene. These data indicate that beta-carotene exerts weak antioxidant effects against smoke-induced oxidative damage in vitro. It is unlikely that a prooxidant effect of beta-carotene occurs under biologically relevant conditions or is responsible for an increased incidence of lung cancer observed in smokers who consume beta-carotene supplements.