Effect of chlorophenols on porphyrin metabolism in rats and chick embryo

Comparative biotransformation of hexachlorobenzene and hexafluorobenzene in relation to the induction of porphyria

The porphyrinogenic action of hexafluorobenzene was investigated and compared to that of hexachlorobenzene. Metabolite patterns in the urine of exposed rats were determined to quantify the extent of metabolism through cytochrome P450 catalysed oxidation and glutathione conjugation. Results obtained demonstrate an almost similar extent of formation of phenolic metabolites. However, in the urine of hexachlorobenzene exposed rats significantly higher levels of the N-acetyl-S-(pentahalophenyl)cysteine were observed than in the urine of hexafluorobenzene exposed rats. Hexafluorobenzene exposure did not result in induction of porphyria, whereas exposure to hexachlorobenzene did result in significantly elevated levels of urinary as well as liver porphyrins. Together these results indicate that if the reactive intermediate is indeed formed in the cytochrome P450 catalysed initial oxidative dehalogenation, the extent of its formation as well as its subsequent reactivity and reaction pathways vary with the type of the halogen substituents. Furthermore, the results seem to indicate that the extent of metabolism of hexahalogenated benzenes into urinary metabolites resulting from glutathione conjugation is a better indication of their porphyrinogenic action than their extent of metabolism to phenolic metabolites. Two explanations for this observation are presented.

Possible reactive intermediates in the oxidative biotransformation of hexachlorobenzene

In this review the biotransformation of hexachlorobenzene is discussed, with special reference to the possible generation of reactive metabolites or intermediates during this process. Evidence is presented for the direct involvement of certain cytochrome P-450 isoenzymes in the major toxic effect of hexachlorobenzene, hepatic porphyria. The in vivo biotransformation is discussed and compared with in vitro experiments (microsomal and cell culture studies). The possible reactive metabolites and intermediates and their mechanisms of formation are presented. Special attention is directed to a very reactive metabolite, tetrachloro-1,4-benzoquinone, which has a high capacity to efficiently react with protein, thus possibly linking the oxidative biotransformation of hexachlorobenzene and the molecular mechanism of enzyme inactivation leading to hepatic porphyria.

The microsomal metabolism of hexachlorobenzene. Origin of the covalent binding to protein

The microsomal metabolism of hexachlorobenzene is studied, with special attention to the covalent binding to protein. The metabolites formed are pentachlorophenol and tetrachlorohydroquinone. In addition, a considerable amount of covalent binding to protein is detected (250 pmoles pentachlorophenol, 17 pmoles tetrachlorohydroquinone and 11 pmoles covalent binding in an incubation containing 50 mumoles of hexachlorobenzene). In order to establish the potential role of reductive dechlorination in the covalent binding, the anaerobic metabolism of hexachlorobenzene was investigated. At low oxygen concentrations no pentachlorobenzene was detected, and only very small amounts of pentachlorophenol as well as covalent binding, indicating a relationship between covalent binding and the microsomal oxidation of hexachlorobenzene. Incubations with 14C-pentachlorophenol at low concentrations showed that a conversion-dependent covalent binding occurs to the extent of 75 pmole binding per nmole pentachlorophenol. This is almost enough to account for the amount of label bound to protein observed in hexachlorobenzene incubations. This indicates that less than 10% of the covalent binding occurs during conversion of hexachlorobenzene to pentachlorophenol, and the remainder is produced during conversion of hexachlorobenzene to pentachlorophenol, and the remainder is produced during conversion of pentachlorophenol. The major product of microsomal oxidation of pentachlorophenol is tetrachlorohydroquinone, which is in redox-equilibrium with the corresponding semiquinone and quinone (chloranil). The covalent binding is inhibited by addition of ascorbic acid or glutathione to the hexachlorobenzene incubations. Ascorbic acid decreases the covalent binding with a simultaneous increase in formation of tetrachlorohydroquinone, probably due to a shift in the redox-equilibrium to the reduced side. Glutathione does not act as a reducing agent, since the inhibition of covalent binding is not accompanied by an increase in tetrachlorohydroquinone formation. Instead, glutathione reacts with chloranil, producing at least three stable products, probably in a Michael-type reaction. These results strongly indicate the involvement of chloranil or the semiquinone radical in the covalent binding during microsomal hexachlorobenzene metabolism.

The effect of tetrachlorohydroquinone on hexachlorobenzene-induced porphyria in Japanese quail

Female Japanese quail received either hexachlorobenzene (HCB, 100 mg/kg . d) or tetrachlorohydroquinone (TCHQ, 175 mg/kg . d) for 10 d as a primary treatment. Following this, a secondary treatment of HCB (100 mg/kg . d) or TCHQ (175 mg/kg . d), alone or in combination, was administered for 1, 5, 10 or 15 d. The primary HCB treatment caused elevated delta-aminolevulinic acid synthetase (ALA-S) activities and small increases in porphyrin concentrations. Subsequent treatment of these birds with lactose resulted in no further increases in porphyrins or ALA-S. TCHQ treatment caused increases in porphyrins similar to those seen with continued HCB treatment. Apparently, despite the fact that TCHQ alone had no affect on ALA-S or porphyrin levels, this compound is able, in the presence of elevated ALA levels to cause porphyria. A combination of HCB and TCHQ administered to HCB-pretreated animals caused a more severe porphyria than did follow-up treatment with either HCB or TCHQ alone.

Mechanism of hexachlorobenzene-induced porphyria in rats. Effect of phenobarbitone pretreatment

The effect of a pretreatment with phenobarbitone (PB) on the porphyrinogenic action exerted by hexachlorobenzene (HCB) was examined in female rats. Kinetic studies of enzyme function after HCB poisoning showed that porphyrinogen carboxy-lyase was the only enzyme of haem biosynthesis that markedly lowered its activity. Both stages of uroporphyrinogen (UPG) III decarboxylation were decreased. This enzyme, together with UPG I synthase (increased levels) were the first enzymes altered. Subsequently, an increase in delta-aminolaevulinate (AmLev) synthase and ferrochelatase was detected; AmLev dehydratase was the last to increase. On long-term exposure, PB alone did not modify the basal values of haem intermediates; only the content of cytochrome P-450 increased. All the enzyme activities studied showed no significant changes, except ferrochelatase, which increased. With both drugs the metabolic impairment promoted by HCB was accelerated and enhanced by prior PB treatment leading to the onset of an earlier and stronger porphyria. A more noticeable accumulation and excretion of higher carboxylated porphyrins and precursors was more promptly observed as a consequence of the early porphyrinogen carboxy-lyase blockade and the concomitant induction of AmLev synthase. Although the enzymic activities of both AmLev dehydratase and ferrochelatase were enhanced, this response differed in time. For UPG I synthase this pretreatment elicited lower values than those found in the HCB group. Cytochrome P-450 contents were immediately and slightly enhanced by all the drugs, but the values for the combined treatment were the lowest. Of the several hypotheses that could explain the action of HCB on the haem pathway, our results would suggest that the porphyrinogenic action of HCB is mediated by some of its metabolic products.

Effect of parathion, malathion, endosulfan and chlordane on porphyrin accumulation and ALA-synthetase in chick embryo liver

In the present study we investigated the porphyrinogenic ability of 4 pesticides: chlordane, endosulfan, parathion and malathion, all of which are widely used in agriculture. In order to determine whether they affect the heme biosynthetic pathway we studied, in 17-day old chick embryo liver "in ovo", their effects on the amount of porphyrins and on the activity of delta-ALA synthetase (ALA-S), the first and rate limiting enzyme of this pathway. All of them induced hepatic porphyrin accumulation to a different extent compared with dimethylsulfoxide (DMSO) controls. Parathion as well as endosulfan promoted remarkable increases, chlordane raised porphyrin level in a lower degree and malathion slightly modified it. However, the accumulation observed with malathion was markedly enhanced if the period of incubation was extended to 48 h and, even more, if a second dose was injected during these 48 h. When ALA-S activity was analyzed in the chick embryos treated with parathion or endosulfan no alteration could be found in spite of producing noticeable accumulation of porphyrins. In contrast, chlordane promoted a statistically significant elevation of ALA-S as well as malathion which produced the highest induction observed. These results show that not only organochlorinated but also organophosphorous pesticides affect heme metabolism and that induction of ALA-S and porphyrin accumulation are not parallel.