Brassinolide and [26, 28-2H6]brassinolide are differently demethylated by loss of C-26 and C-28, respectively, in Marchantia polymorpha

Metabolism of brassinolide in Marchantia polymorpha was investigated by use of in vivo suspension cultured cells. GC-MS analysis of metabolites derived from non-labelled brassinolide and [26, 28-2H6] brassinolide revealed that brassinolide was converted to 26-norbrassinolide while [26, 28-2H6]brassinolide to [26-2H3]28-norbrassinolide. It seems that Marchantia cells recognized [26, 28-2H6]brassinolide as a xenobiotic rather than brassinolide and deteriums attached to C-28 significantly affect demethylation reaction due to isotopic effect. Thus, demethylation of brassinolide in planta seems to proceed by loss of C-26 rather than C-28. The present finding is the first evidence for demethylation metabolism of brassinosteroids. The biological activity of 26-norbrassinolide was 10-fold reduced as shown by the rice lamina inclination test. However, because of its high biological activity, it remains difficult to conclude whether or not C-26 demethylation serves as an important deactivation process of brassinolide.     

Mechanistic studies of lanosterol C-32 demethylation. Conditions which promote oxysterol intermediate accumulation during the demethylation process

Conditions have been established which promote the accumulation of the dihydrolanosterol C-32 demethylation intermediates lanost-8-en-3 beta,32-diol and 3 beta-hydroxylanost-8-en-32-aldehyde with intact hepatic microsomes. Accumulation of dihydrolanosterol-derived oxysterols occurs with a variety of assay manipulations which include short incubation times, limiting enzyme amounts, high pH, and increasing substrate concentration. In addition, competitive inhibition of dihydrolanosterol demethylation by lanosterol, or the reciprocal inhibition of lanosterol demethylation by dihydrolanosterol, leads to oxysterol accumulation at the expense of demethylated end product. Similarly, the nonsteroidal demethylase inhibitors miconazole and ketoconazole promote oxysterol accumulation in a concentration-dependent manner. Finally, cholesterol loading of isolated microsomes results in changes in the measured kinetic constants, Km and Vmax, and results in enhanced oxysterol accumulation above that seen in control microsomal preparations. The major oxysterol intermediate accumulated under all the conditions described above is the C-32 aldehyde in an approximate 3:1 ratio to the C-32 alcohol. These data support the conclusion that a single enzyme species is responsible for all three oxidations of the C-32 demethylation sequence. In addition, intermediates which do not routinely accumulate during demethylation are freely diffusible from the enzyme when appropriate conditions are established to prevent their further metabolism.     

Cytochrome P-450-dependent oxidation of lanosterol in cholesterol biosynthesis. Microsomal electron transport and C-32 demethylation

Electron transfer to rat liver microsomal cytochrome P-450 of 14 alpha-methyl group demethylation of 24,25-dihydrolanosterol (C30-sterol) has been studied with a new radio-high-performance liquid chromatography assay. The monooxygenase is dependent upon NADPH plus oxygen, insensitive to CN-, and sensitive to CO. Microsomal oxidation is also sensitive to trypsin digestion, and reactivation is dependent upon the addition of purified, detergent-solubilized cytochrome P-450 reductase. Electron transport of C-32 sterol demethylation can be fully supported by very low concentrations of NADPH (approximately 10 microM) only in the presence of saturating concentrations of NADH (approximately 200 microM) suggesting involvement of cytochrome b5-dependent electron transfer in addition to the NADPH-supported pathway. The cytochrome P-450 of 14 alpha-demethylation has been solubilized with detergents, resolved chromatographically from cytochrome P-450 reductase and cytochrome b5, and fully active C-32 demethylase reconstituted. Incubation of intact microsomes with NADH and very low concentrations of NADPH described above leads to interruption of demethylation without 14 alpha-methyl group elimination. Under these conditions, C-32 oxidation products of the C30-sterol substrate accumulate at the expense of formation of demethylated, C29-sterol products. This enzymic interruption of C-32 demethylation, accumulation of oxygenated C30-sterols, along with subsequent demethylation of the isolated C30-oxysterols under similar oxidative conditions supports the suggestion that 14 alpha-hydroxymethyl and aldehydic sterols are metabolic intermediates of sterol 14 alpha-demethylation. Only very modest inductions of the constitutive cytochrome P-450 isozyme of 14 alpha-methyl sterol oxidase can be obtained with just 2 out of 12 known, potent inducers of mammalian hepatic cytochrome P-450s. Alternatively, administration of complete adjuvant in mineral oil drastically reduces amounts of total microsomal cytochrome P-450 while activity of 14 alpha-methyl sterol oxidase is not affected dramatically. Thus, as much as 2.5-fold enhancement of C-32 oxidase specific activity is obtained when expressed per unit of cytochrome P-450.     

Regioselective bioconversion of colchicine and thiocolchicine into their corresponding 3-demethyl derivatives

A variety of plant cell cultures and microbial soil isolates were screened for their ability to specifically demethylate colchicine at the C-3 position. Among all plant cell cultures tested, the newly established Colchicum variegatum culture was the only one able to demethylate colchicine, however unspecifically, yielding a mixture of 3-demethylcolchicine and 2-demethylcolchicine. In contrast, two bacterial strains were found among more than 500 isolates tested which expressed higgly regio-specific demethylation activity exclusively at C-3 of colchicine. The bioconversion product of the microorganisms, 3-demethylcolchicine, was completely excreted into the medium. The specific C-3 bioconversion of colchicine as well as of thiocolchicine by one of these strains, Bacillus IND-B 375, was characterized in function of substrate concentration and incubation time.     

Ergosterol biosynthesis in novel melanized fungi from hypersaline environments

Halotolerant and halophilic melanized fungi were recently described in hypersaline waters. A close study of the sterol composition of such fungi, namely Hortaea werneckii, Alternaria alternata, Cladosporium sphaerospermum, Cladosporium sp., and Aureobasidium pullulans revealed the dominance of ergosterol and the presence of 29 intermediates of its biosynthesis pathway. The presence or absence of intermediates from distinct synthesis routes gave insight into the operative synthetic pathways from 4,4,14-trimethylcholesta-8,24-dien-3 beta-ol (lanosterol) to ergosterol in melanized fungi and in Saccharomyces cerevisiae, a reference yeast cultured in parallel. In all studied melanized fungi, initial methylation at C-24 took place before C-14 and C-4 demethylation, involving a different reaction sequence from that observed in S. cerevisiae. Further transformation was observed to occur through various routes. In A. alternata, isomerization at C-7 takes place prior to desaturation at C-5 and C-22, and methylene reduction at C-24. In addition to these pathways in Cladosporium spp., H. werneckii, and A. pullulans, ergosterol may also be synthesized through reduction of the C-24 methylene group before desaturation at C-5 and C-22 or vice versa. Moreover, in all studied melanized fungi except A. alternata, ergosterol biosynthesis may also proceed through C-24 methylene reduction prior to C-4 demethylation. -- Méjanelle, L., J. F. Lòpez, N. Gunde-Cimerman, and J. O. Grimalt. Ergosterol biosynthesis in novel melanized fungi from hypersaline environments. J. Lipid Res. 2001. 42: 352--358.     

Dissecting the sterol C-4 demethylation process in higher plants. From structures and genes to catalytic mechanism

Sterols become functional only after removal of the two methyl groups at C-4. This review focuses on the sterol C-4 demethylation process in higher plants. An intriguing aspect in the removal of the two C-4 methyl groups of sterol precursors in plants is that it does not occur consecutively as it does in yeast and animals, but is interrupted by several enzymatic steps. Each C-4 demethylation step involves the sequential participation of three individual enzymatic reactions including a sterol methyl oxidase (SMO), a 3β-hydroxysteroid-dehydrogenase/C4-decarboxylase (3βHSD/D) and a 3-ketosteroid reductase (SR). The distant location of the two C-4 demethylations in the sterol pathway requires distinct SMOs with respective substrate specificity. Combination of genetic and molecular enzymological approaches allowed a thorough identification and functional characterization of two distinct families of SMOs genes and two 3βHSD/D genes. For the latter, these studies provided the first molecularly and functionally characterized HSDs from a short chain dehydrogenase/reductase family in plants, and the first data on 3-D molecular interactions of an enzyme of the postoxidosqualene cyclase sterol biosynthetic pathway with its substrate in animals, yeast and higher plants. Characterization of these three new components involved in C-4 demethylation participates to the completion of the molecular inventory of sterol synthesis in higher plants.     

Ergosterol depletion and 4-methyl sterols accumulation in the yeast Saccharomyces cerevisiae treated with an antifungal, 6-amino-2-n-pentylthiobenzothiazole.

In Saccharomyces cerevisiae treated with an antifungal agent, 6-amino-2-n-pentylthiobenzothiazole, levels of ergosterol and other 4-desmethylsterols were found to be significantly reduced. Major sterols in treated yeast were lanosterol, 4,4-dimethylzymosterol, 4-methylzymosterol and 4-methylfecosterol. A hypothesis is stated that the antifungal agent inhibits sterol demethylation at C-4 and forces the biosynthesis to a blind pathway ending by 4-methylfecosterol.     

Biotransformation of mestanolone and 17-methyl-1-testosterone by Rhizopus stolonifer

Abstract

Microbial transformation of mestanolone (1) using the plant pathogenic fungus, Rhizopus stolonifer, resulted in the production of two known metabolites, identified as 11α-hydroxymestanolone (3) and 6α-hydroxymestanolone (4). Transformation of 17-methyl-1-testosterone (2) by R. stolonifer yielded two known metabolites, methandrostenolone (5) and 11α,17β- dihydroxy-androsta-1,4-diene-3-one (6). These transformations included α-hydroxylations at C-11 and C-6, dehydrogenation at C-4, androsta and a demethylation at C-17 positions. Structures of transformed products were determined using spectroscopic techniques.     

Oxidative C4-demethylation of 24-methylene cycloartanol by a cyanide-sensitive enzymatic system from higher plant microsomes

Microsomes isolated from corn embryos (Zea mays) were shown to catalyse the C-4 monodemethylation of 28-[3H],24-methylene cycloartanol 1, leading to the corresponding 4 alpha-methyl sterol, cycloeucalenol 5. An enzymatic assay has been developed for the 4,4-dimethyl sterol 4-demethylase in higher plants. The demethylation process was shown to involve a 4-methyl, 4-hydroxymethyl derivative 2 which can be considered as the immediate metabolite of 1 by the 4-methyl oxidase. Compound 2 is further metabolized into 5 through a 4-methyl-4-carboxylic acid 3 and a 3-keto-4 alpha-methyl intermediate 4 which were identified. The conversion of 1 into 5 requires NADPH and molecular oxygen. The initial oxidative step was strictly dependent upon molecular oxygen, NADPH or NADH, and strongly inhibited by cyanide, whereas the overall process was completely insensitive to CO and to specific inhibitors of cytochrome P-450. It is concluded that in Zea mays microsomes, the C-4 demethylation of 1 results from a multistep process involving a terminal oxygenation system sensitive to cyanide which is distinct from cytochrome P-450 and in particular from that involved in the 14 alpha-demethylation of obtusifoliol.     

Thyroid hormone-, carbohydrate, and age-dependent regulation of a methylation site in the hepatic S14 gene

The rat hepatic S14 gene has served as a model of thyroid hormone regulation of gene expression. Earlier studies of the S14-containing chromatin region demonstrated that a cytosine residue at position 625 (C-625) in the 3' untranslated exon was hypermethylated in hepatic DNA derived from hypothyroid animals. This observation was consistent with the markedly reduced level of expression of the S14 gene in these rats. The current studies have extended these observations to groups of rats in various thyroidal states. By using the restriction enzyme Hhal, the percent demethylation of this site was quantitated (hypothyroid, 9.3%; euthyroid, 19.2%; hyperthyroid, 66.6%). Moreover, the level of methylation was shown to be reversible as the thyroidal state was altered. Our data also indicate that these changes are probably independent of de novo DNA synthesis. Kinetic studies of the demethylation of this cytosine residue after T3 administration showed no change for at least 1 day and maximal change after about 4 days. This contrasts with the significant rise in S14 mRNA evident within 30 min and suggests that demethylation plays no role in the acute induction of this gene by T3. Carbohydrate feeding, another stimulus of S14 expression, similarly caused the demethylation of this cytosine residue. Earlier studies had demonstrated that mRNA S14 expression was not detectable in rat pups before about 20 days of age and continued to rise through the first year of life. Consistent with those findings, S-14 C-625 was fully methylated up to 15 days of age. Progressive demethylation then occurred up to 12 months of age. These results indicate that increased demethylation of a specific site in the 3' untranslated region of the S14 gene, possibly resulting from augmented excision repair processes, is correlated with increased expression of the gene.     

Effect of allylamine antimycotic agents on fungal sterol biosynthesis measured by sterol side-chain methylation

Sterol side-chain (C-24) methylation was assayed by incorporation of radioactivity from [Me-14C]methionine into the ergosterol fraction in cells of the pathogenic fungi Candida albicans, Candida parapsilosis and Trichophyton mentagrophytes. Methylation at C-24 occurred after nuclear demethylation in all cases. The method was used to measure ergosterol biosynthesis inhibition by the allylamine antimycotics naftifine and SF 86-327, which are known to block squalene epoxidation. In C. albicans cells treated with SF 86-327 (1 mg l-1) to fully inhibit squalene epoxidation, C-24 methylation continued for several hours at about 40% of the control rate. This residual biosynthesis was probably due to methylation of endogenous sterol precursors. The degree of residual biosynthesis in the three fungi correlated well with their susceptibility to SF 86-327. The highly susceptible dermatophyte T. mentagrophytes had negligible residual sterol biosynthesis. These differences were not due to inhibition of methionine uptake. For naftifine (100 mg l-1) there was evidence of a second inhibitory action in C. albicans. A cell-free assay indicated that this was due to direct inhibition of the C-24 methyltransferase.     

Plant growth regulator activities of stereochemical isomers of triadimenol

Etiolated seedlings of wheat ( Triticum aestivum L. cv. Jubilar) were treated with individual isomers of triadimenol in order to determine the biochemical basis for plant growth retardation. The Is, 2R isomer showed the highest activity as a plant growth retardant, followed by the 1R, 2s form. The inhibition of growth was not relieved by exogenous gibberellic acid suggesting a mode of action different from inhibition of gibberelln synthesis. Labelling of sterols with radioactive acetate and methionine demonstrated a strong inhibition of sterol synthesis, most likely at the step of C-14 demethylation of obtusifoliol. The extent of growth inhibition was accompanied with the potency of individual isomers to inhibit sterol synthesis. The inhibition of gibberellin synthesis appears of less importance for growth retardation.     

Mechanistic studies of lanosterol 14 alpha-methyl demethylase: substrate requirements for the component reactions catalyzed by a single cytochrome P-450 isozyme

Lanosterol 14 alpha-methyl demethylation is a cytochrome P-450-dependent process that proceeds through the oxidative sequence of alcohol, aldehyde followed by decarbonylation with formic acid release. Microsomal metabolism studies shown here indicate that only lanostenols and 32-oxy-lanostenols with unsaturation at either the delta 7 or delta 8 position in the sterol can be demethylated. The 14 alpha-methyl group of either lanostan-3 beta-ol or delta 6 lanostenol is not oxidized to the anticipated C-32 alcohol or aldehyde by the enzyme, nor are the corresponding 32-oxy-lanostanols demethylated when incubated with microsomal preparations. Despite the lack of metabolism, the saturated and delta 6 sterol analogues are effective competitive inhibitors of demethylase activity. Utilizing preferred substrates, comparison of the component reactions of the demethylation sequence shows that both the oxidative function and lyase function are sensitive to common inhibitors and that both activities require NADPH. These findings strongly support the premise that a P-450 isozyme does catalyze each phase of the lanosterol 14 alpha-methyl demethylation sequence. Collectively these results demonstrate the double-bond requirement for both components of the demethylation sequence and suggest that the olefinic electrons at delta 7 or delta 8 but not delta 6 may participate directly during demethylation. This participation may involve stabilizing a transition state intermediate or directing activated oxygen insertion as part of the P-450 monoxygenase mechanism.     

Stereochemistry of C-4 demethylation during conversion of obtusifoliol into poriferasterol by Ochromonas malhamensis

Obtusifoliol-[2,2,4-³H₃] was synthesised and incubated with the chrysophyte alga Ochromonas malhamensis which converted it into poriferasterol. A reaction sequence applied to poriferasterol showed that the tritium retained at C-4 occupied the 4α-position. This demonstrates that biological C-4 demethylation of a 4α-methylsterol precursor by O. malhamensis results in the axial 4β-hydrogen being inverted into the equatorial 4α-position of the 4-desmethyl sterol product.     

Fatty acid patterns of different stages of Oesophagostomum dentatum and Oesophagostomum quadrispinulatum as revealed by gas chromatography

Total methylated fatty acid patterns of various developmental stages (third-stage larvae (L3), L3 and fourth-stage larvae (L4) cultured in vitro, L4 and female and male adults derived from intestinal contents) of the porcine nodular worms Oesophagostomum dentatum and Oesophagostomum quadrispinulatum and their cultivation medium were analysed by gas chromatography using Microbial Identification computer software. Fatty acids ranging from C-12 to C-20 could be separated. For each stage and species, characteristic patterns were found. The most prevalent fatty acids were C-18. The freshly exsheathed larvae contained the greatest variety of fatty acids (including short-chain fatty acids C-12 to C-15) with approximately equal amounts of fatty acids with odd and even chain lengths, whereas more advanced stages consisted of a lower number of fatty acids with mostly even chain lengths >/=C-16. Intestinal stages contained less odd-numbered fatty acids and less branched fatty acids than others. In contrast to intestinal L4, cultivated L4 had high amounts of C-15:0 and C-17:0. Sheathed L3 contained more C-18 than freshly exsheathed ones, and medium incubated for 7 days in the presence of parasites contained C-13 to C-15 and monounsaturated C-16, but less C-18 and C-20:4 than fresh medium or medium incubated without worms. Based on the evaluation of stage- and species-specific fatty acid patterns random samples could be assigned to the correct stage and species. In a dendrogram based on fatty acid patterns the same stages of the two species formed the closest relationships, and the intestinal stages formed a clade distinct from the cultivated larvae and L3. All stages contained considerable relative amounts of arachidonic acid, the main precursor of eicosanoids. The fixed differences between species and stages indicate genetic regulation of fatty acid patterns, while environmental influences are mirrored by differences between cultivated and intestinal stages. Regulation of fatty acid patterns probably plays a role in worm physiology and host-parasite interaction.     

Effects of triazoles on fungi. III. Composition of a plasma membrane-enriched fraction of Taphrina deformans

Comparative chemical analyses were conducted with plasma membrane-enriched fractions of Taphrina deformans cells grown in a medium with or without the C-14 demethylation inhibitor propiconazole at a concentration that gives 50% growth inhibition. The membrane fractions were prepared using differential and discontinuous sucrose density gradient centrifugation, and characterized by cytochemical, enzymatic and chemical analyses. Membranes of nontreated cells were similar to those from other fungi with a protein/lipid ratio of 1.2, 13% phospholipid content in the membrane lipid (122 μg/mg protein), and a relatively high sterol/phospholipid molar ratio of 0.69. The corresponding membrane fraction from propiconazole-treated cells had 24% less lipid, 27% less phospholipid, 5-times more triacylglycerol relative to other neutral acyl lipids, and over a 2-fold higher sterol/phospholipid ratio. The greater sterol/phospholipid ratio was due to a higher C-14 methyl sterol content rather than less functional sterol (brassicasterol). Membranes from treated cells contained slightly less protein than those from nontreated cells, but there was little difference in the electrophoretic separation patterns of solubilized membrane polypeptides.     

Identification of 24-methylene-24,25-dihydrolanosterol as a precursor of ergosterol in the yeasts Schizosaccharomyces pombe and Schizosaccharomyces octosporus

Abstract Study of the plasma membrane sterol composition in the yeasts Schizosaccharomyces pombe and Schizosaccharomyces octosporus revealed the presence of ergosterol, lanosterol, dehydroergosterol, fecosterol, episterol and 24-methylene-24,25-dihydrolanosterol (eburicol), a C-31 derivative. The growth of both yeasts in the presence of ketoconazole led to a decrease by 85% of the ergosterol content while the levels of lanosterol and eburicol increased. This suggests that in the biosynthetic pathway of ergosterol in Schizosaccharomyces species, the transmethylation process on the C-24 may occur directly on lanosterol and not only on zymosterol. On the other hand, it cannot be excluded that in the genus Schizosaccharomyces two routes exist from lanosterol to ergosterol: the classical one via a direct C-14, C-4 demethylation of lanosterol and the second one via the formation of a C-31 derivative followed by demethylations.     

Synthesis of [1,2-3H2]cholecalciferol and metabolism of [4-14C,1,2-3H2]- and [4-14C,1-3H]-cholecalciferol in rachitic rats and chicks

[1,2-(3)H(2)]Cholecalciferol has been synthesized with a specific radioactivity of 508mCi/mmol by using tristriphenylphosphinerhodium chloride, the homogeneous hydrogen catalyst. With doses of 125ng (5i.u.) of [4-(14)C,1-(3)H(2)]cholecalciferol the tissue distribution in rachitic rats of cholecalciferol and its metabolites (25-hydroxycholecalciferol and peak P material) was similar to that found in chicken with 500ng doses of the double-labelled vitamin. The only exceptions were rat kidney, with a very high concentration of vitamin D, and rat blood, with a higher proportion of peak P material, containing a substance formed from vitamin D with the loss of hydrogen from C-1. Substance P formed from [4-(14)C,1,2-(3)H(2)]cholecalciferol retained 36% of (3)H, the amount expected from its distribution between C-1 and C-2, the (3)H at C-1 being lost. 25-Hydroxycholecalciferol does not seem to have any specific intracellular localization within the intestine of rachitic chicks. The (3)H-deficient substance P was present in the intestine and bone 1h after a dose of vitamin D and 30min after 25-hydroxycholecalciferol. There was very little 25-hydroxycholecalciferol in intestine at any time-interval, but bone and blood continued to take it up over the 8h experimental period. It is suggested that the intestinal (3)H-deficient substance P originates from outside this tissue. The polar metabolite found in blood and which has retained its (3)H at C-1 is not a precursor of the intestinal (3)H-deficient substance P.     

The ERG28-encoded protein, Erg28p, interacts with both the sterol C-4 demethylation enzyme complex as well as the late biosynthetic protein, the C-24 sterol methyltransferase (Erg6p)

In Saccharomyces cerevisiae, the C-24 sterol methyltransferase (Erg6p) converts zymosterol to fecosterol, an enzymatic step following C-4 demethylation of 4,4-dimethylzymosterol. Our previous study showed that an endoplasmic reticulum (ER) transmembrane protein, Erg28p, functions as a scaffold to tether the C-4 demethylation enzymatic complex (Erg25p-Erg26p-Erg27p) to the ER. To determine whether Erg28p also interacts with other ergosterol biosynthetic proteins, we compared protein levels of Erg3p, Erg6p, Erg7p, Erg11p and Erg25p in three pairs of erg28 and ERG28 strains. In erg28 strains, the Erg6p level in the ER fraction was decreased by about 50% relative to the wild-type strain, while ER protein levels of the four other ergosterol proteins showed no significant differences. Co-immunoprecipitation experiments, using an erg28 strain transformed with the epitope-tagged plasmid pERG28-HA and proteins detected with anti-HA and anti-Erg6p antibodies, indicated that Erg6p and Erg28p reciprocally co-immunoprecipitate. Further, the split ubiquitin yeast membrane two-hybrid system designed to detect protein interactions between membrane bound proteins also indicated an Erg28p-Erg6p interaction when pERG6-Cub was used as the bait and pERG28-NubG was used as the prey. We conclude that Erg28p may not only anchor the C-4 demethylation enzyme complex to the ER but also acts as a protein bridge to the Erg6p enzyme required for the next ergosterol biosynthetic step.     

Structure-Activity Relationship of Synthetic 2-Phenylnaphthalenes with Hydroxyl Groups that Inhibit Proliferation and Induce Apoptosis of MCF-7 Cancer Cells

In this study, six 2-phenylnaphthalenes with hydroxyl groups were synthesized in high yields by the demethylation of the corresponding methoxy-2-phenylnaphthalenes, and one 2-phenylnaphthalene with an amino group was obtained by hydrogenation. All of the 2-phenylnaphthalene derivatives were evaluated for cytotoxicity, and the structure-activity relationship (SAR) against human breast cancer (MCF-7) cells was also determined. The SAR results revealed that cytotoxicity was markedly promoted by the hydroxyl group at the C-7 position of the naphthalene ring. The introduction of hydroxyl groups at the C-6 position of the naphthalene ring and the C-4'' position of the phenyl ring fairly enhanced cytotoxicity, but the introduction of a hydroxyl group at the C-3'' position of the phenyl ring slightly decreased cytotoxicity. Overall, 6,7-dihydroxy-2-(4''-hydroxyphenyl)naphthalene (PNAP-6h) exhibited the best cytotoxicity, with an IC₅₀ value of 4.8 μM against the MCF-7 cell line, and showed low toxicity toward normal human mammary epithelial cells (MCF-10A). PNAP-6h led to cell arrest at the S phase, most likely due to increasing levels of p21 and p27 and decreasing levels of cyclin D1, CDK4, cyclin E, and CDK2. In addition, PNAP-6h decreased CDK1 and cyclin B1 expression, most likely leading to G₂/M arrest, and induced morphological changes, such as nuclear shrinkage, nuclear fragmentation, and nuclear hypercondensation, as observed by Hoechst 33342 staining. PNAP-6h induced apoptosis, most likely by the promotion of Fas expression, increased PARP activity, caspase-7, caspase-8, and caspase-9 expression, the Bax/Bcl-2 ratio, and the phosphorylation of p38, and decreased the phosphorylation of ERK. This study provides the first demonstration of the cytotoxicity of PNAPs against MCF-7 cells and elucidates the mechanism underlying PNAP-induced cytotoxicity.