Covalent protein adducts of hydroquinone in tissues from rats: identification and quantitation of sulfhydryl-bound forms.

The Michael-type addition of sulfhydryl groups to benzoquinone (BQ) or substituted benzoquinones is proposed as the primary mechanism by which these electrophilic intermediates react with either cellular glutathione or protein sulfhydryls. This reaction constitutes a reductive alkylation with a substituted hydroquinone (HQ) derivative resulting from the addition. In the case of HQ, oxidative conversion of the parent material to BQ followed by conjugation with glutathione leads to metabolic activation, producing intermediates which are nephrotoxic as well as having other proposed biological activities. Chemically, BQ may react with more than 1 equiv of glutathione (or other sulfhydryl reagents) to produce HQ derivatives substituted with up to four sulfhydryl groups. Similarly, multiply substituted protein-S adducts of HQ were anticipated to occur in vivo following administration of this material. In the current studies, sulfhydryl-bound HQ protein adducts were detected and quantitated in protein isolated from rats using a modification of the alkaline permethylation procedure of Slaughter and Hanzlik [(1993) Anal. Biochem. 208, 288-295]. In particular, total protein-S adducts to HQ in kidney or blood reached a level of 420 or 80 pmol/mg of protein, respectively, 6 h following a single gavage dose of 100 mg/kg HQ. Measured half-lives of protein-S adducts in kidney and blood were 23.9 and 36.0 h, respectively. The applicability of protein-S adducts as a tissue dosimeter for HQ is discussed.

Covalent protein adducts of hydroquinone in tissues from rats: quantitation of sulfhydryl-bound forms following single gavage or intraperitoneal administration or repetitive gavage administration.

The current studies were conducted to investigate the degree and type of protein binding of hydroquinone (HQ) in the rat following single oral or intraperitoneal (ip) or repeated oral administrations. Male or female F-344 rats or male SD rats received a single dose of HQ at 0, 25, 50, or 100 mg/kg by either gavage or ip injection (SD rats only). In addition, male or female F-344 or male SD rats received HQ by gavage for 6 weeks (5 days/week) at 0, 25, or 50 mg/kg/day. Sulfhydryl-bound HQ was quantitated in protein from blood, kidneys, livers, or spleens 24 h after treatment using an alkaline permethylation procedure. The amount of total protein-S adducts increased with increasing dose in all the tissues that were assayed. Female rats had higher levels of adducts in blood, livers, and kidneys than did male rats when they were treated orally. Male F-344 rats treated orally had elevated levels of adducts in these same tissues compared to SD rats treated orally. For all genders and strains of rats and for all treatment regimens, mono-adducts predominated in livers (>72% of total). In the kidneys, tri- and tetrasubstituted adducts predominated with the summation accounting for >60% of the total. Ip administration of HQ resulted in significantly elevated levels of adducts in all the tissues that were examined, with the greatest increases seen for protein from blood and spleens. Levels of protein-S adducts of HQ in rat kidney following a single gavage administration correlated well with previously published differences in acute HQ nephrotoxicity in rats (female F-344 rat > male F-344 rat > male SD rat). Elevated levels of HQ protein-S adducts following repeated gavage administration did not correlate to measurable clinical signs of nephrotoxicity. Evidence is presented suggesting a possible role for the prostaglandin H synthase complex in the metabolic activation of HQ. In addition, protein arylation alone cannot account for the greater sensitivity of male F-344 rats toward chronic administration of HQ. The sensitivity of male F-344 rats to HQ is likely due to other factors, including the incidence and severity of chronic progressive nephropathy.

Development of a physiologically based pharmacokinetic model for hydroquinone.

Hydroquinone (HQ) produces nephrotoxicity and renal tubular adenomas in male F344 rats following 2 years of oral dosing. Female F344 and SD rats are comparatively resistant to these effects. Nephrotoxicity and tumorigenicity have been associated with a minor glutathione conjugation pathway following the oxidation of HQ to benzoquinone (BQ). The majority of administered doses (90-99%) consists of glucuronide and sulfate conjugates of HQ. An initial physiologically based pharmacokinetic model was developed to characterize the role of kinetics in the strain differences observed in HQ-induced renal toxicity and tumorigenicity. Partition coefficients, protein-binding, and metabolic rate constants were determined directly or estimated from a series of in vivo and in vitro studies. Metabolism was confined to the liver and GI tract. The total flux through the glutathione pathway represented the "internal dose" of HQ for nephrotoxicity. Simulations were compared to a variety of data from male and female F344 rats, male SD rats, and a single male human volunteer. Simulations of intraperitoneal administration resulted in higher amounts of glutathione conjugates than comparable oral doses. This was consistent with protein-binding and toxicity studies and emphasized the importance of first-pass GI tract metabolism. In addition, male F344 rats were predicted to form more total glutathione conjugates than SD rats at equivalent dose levels, which was also consistent with the observed strain differences in renal toxicity. This model represents the first stage in the development of a biologically based dose-response model for improving the scientific basis for human health risk assessments of HQ.

Dermal absorption and pharmacokinetics of isopropanol in the male and female F-344 rat.

Isopropanol (IPA), as a 70% aqueous solution, was applied under occluded conditions to the shaved backs of male and female Fischer F-344 rats for a period of 4 hr. Maximum analyzed blood concentrations of IPA were attained at 4 hr and decreased steadily following removal of the test material. Blood concentrations were below the limit of quantification at 8 hr. Acetone (ACE) blood levels rose steadily during the 4-hr exposures and continued to rise following removal of the test material, reaching peak analyzed levels at 4.5 hr (male) and 5 hr (females). ACE blood concentrations were below the limit of quantification at 24 hr. Basic pharmacokinetic parameters were similar for male and female rats with mean, first-order elimination half-lives for IPA and ACE of 0.8 to 0.9 hr and 2.1 to 2.2 hr, respectively. Following iv administration of [14C]IPA, 50-55% of the dose was eliminated as 14CO2 with lesser amounts recovered as expired volatiles or in urine. Total recoveries following iv administration were 83% for both males and females. Following a 4-hr dermal exposure to [14C]IPA (70% aqueous solution), 84-86% of the dose was recovered from the application site. Dermal absorption rates were calculated by two independent methods. The values obtained were 0.78 +/- 0.03 and 0.85 +/- 0.04 mg/cm2/hr for males and 0.77 +/- 0.13 and 0.78 +/- 0.16 mg/cm2/hr for females. Calculated permeability coefficients of 1.37 to 1.50 x 10(-3) cm/hr for males and 1.35 to 1.37 x 10(-3) cm/hr for females indicate that in the rat, IPA is rapidly absorbed dermally when applied under occluded conditions.