Michael J. Olson

A comparison of male rat and human urinary proteins: implications for human resistance to hyaline droplet nephropathy.

alpha 2u-Globulin (alpha G), the major urinary protein of sexually mature male rats, is a key determinant of susceptibility to hyaline droplet nephropathy (HDN) induced by a variety of hydrocarbons in male rats. Arguments against extrapolating renal toxicity and carcinogenicity data for HDN-inducing toxicants from male rats to risk assessment for humans rely on the observation that humans do not express alpha G. Yet, human serum and urine are known to contain proteins coded for by the same gene family that also controls alpha G synthesis in the rat. Therefore, to understand some of the quantitative and qualitative differences between proteins of human and male rat urine which confer apparent resistance to HDN in humans, urinary proteins of male F344 rats (ca. 3 months old) and normal human males were compared by cation exchange, gel filtration, SDS-PAGE, and partially identified by Western blotting. We observed that (1) the protein content of human urine is only 1% that of male rat urine; (2) human urinary proteins, recovered by (NH4)2SO4 precipitation followed by dialysis, are primarily of high (greater than or equal to 75 kDa) molecular weight (MW) with minor components of 12-66 kDa; (3) male rat urine has little high-MW protein, but is rich in alpha G (18.5 kDa); (4) at pH 5, the most cationic fraction of human urinary protein constituted only about 4% of the total while the analogous fraction of rat urine, containing alpha G, contained 26% of total urinary protein; and (5) cationic (at pH 5.0) human urinary proteins included small amounts of proteins, e.g., alpha 1-acid glycoprotein, and alpha 1-microglobulin, which are products of the gene family coding for alpha G in rat. Thus, although humans excrete trace amounts of proteins similar to alpha G, the very low protein content of human urine, the relatively small proportion of cationic to total proteins, and the high MW of the most abundant human urinary proteins form a biological basis for suggesting that humans are not at risk for the type of fuel and solvent hydrocarbon-induced nephropathy, and the sequelae of such nephropathy, observed in male rats.

Accumulation of α2u-globulin in the renal proximal tubules of male rats exposed to unleaded gasoline

Saturated branched-chain aliphatic hydrocarbons, found in motor fuels, induce nephrotoxicity in male rats. Treatment of male rats with unleaded gasoline (0.04-2.0 ml/kg body wt, po) for 9 days increased markedly the number and size of hyaline (protein resorption) droplets in epithelial cells of the renal proximal convoluted tubules (PCT) and enhanced cellular exfoliation at high dose levels. No other treatment-related pathological effects were observed in the glomeruli, distal tubules, or medulla. The renal content of alpha 2u-globulin, a major urinary protein of male rats, was increased maximally by about 4.4-fold after gasoline administration (1.0 ml/kg, po, 9 days); no further increase was observed at higher doses. Immunoperoxidase staining of kidney tissue sections for alpha 2u-globulin revealed large accumulations of antigen localized in many of the PCT epithelial cells which contained hyaline droplets. The hepatic content of alpha 2u-globulin and its mRNA were not altered by gasoline administration. These data show, for the first time, that alpha 2u-globulin is accumulated in the kidneys of gasoline-intoxicated male rats and sequestered specifically in some of the hyaline droplets characteristic of gasoline-induced nephropathy. A hydrocarbon-induced defect in the renal lysosomal degradation of low-molecular-weight urinary proteins, rather than increased synthesis of these proteins, appears to cause hyaline droplet accumulation.

DNA strand breaks induced by hydrogen peroxide in isolated rat hepatocytes.

It has been proposed that increased rates of hepatic hydrogen peroxide (H2O2) production may initiate or promote the liver tumors that appear following chronic exposure of rodents to chemicals that cause peroxisome proliferation. However, the effect of H2O2 on the structural integrity of DNA in parenchymal hepatocytes, the target cells of peroxisome proliferator-induced carcinogenesis, is largely uncharacterized. Furthermore, oxidant-induced cellular damage has been invoked as causal of a number of hepatotoxic effects associated with exposure to chemicals other than peroxisome proliferators. For these reasons, alkaline elution analysis was used to study the action of H2O2, added exogenously, on DNA of intact, isolated rat hepatocytes. Addition of a bolus of H2O2 (0.01-1.0 mM) to monolayer cultures of hepatocytes caused concentration-dependent increases in single-strand DNA breaks (SSDB), which were maximal within 30 min of exposure. Cytotoxicity, as measured by lactate dehydrogenase (LDH) release, was minimal during a 1-h exposure to H2O2 concentrations less than 1 mM, but the efflux of oxidized glutathione was increased. Formation of SSDB was nearly linear with respect to H2O2 concentration in the range 0.1-1.0 mM. No double-strand DNA breaks or DNA-protein crosslinks were identified at H2O2 concentrations of 1 mM or less. Repair of SSDB in H2O2-free medium occurred in a rapid, linear manner only for the first 15 min, resulting in disappearance of 65% of the SSDB. A second, slower phase of SSDB rejoining occurred between 20 and 60 min of incubation in H2O2-free media; at 60 min rejoining was maximal (80% repair). These results define a specific type of DNA damage associated with H2O2 exposure of hepatocytes and suggest that primary cultures of rat hepatocytes are a suitable model for characterizing the potential genotoxic effects of oxidants, particularly excess H2O2 that may occur in the livers of animals exposed chronically to peroxisome proliferators.

Hydrocarbon-induced hyaline droplet nephropathy in male rats during senescence

Male rats administered unleaded gasoline rapidly develop nephropathy characterized by accumulation of hyaline droplets in cells of the proximal convoluted tubules (PCT). This acute response is implicated in development of renal carcinoma in male rats exposed chronically to wholly volatilized gasoline. A major constituent of hyaline droplets is alpha 2 mu-globulin, a protein of hepatic origin for which the rate of synthesis declines during aging. Little information, however, is presently available on possible age-dependent susceptibility of male rats to hydrocarbon-induced nephropathy. In kidneys of untreated male Fischer 344 rats the number of constitutive hyaline droplets declined progressively with increasing age. Electrophoresis of renal cortical homogenates revealed a protein with Mr about 18 X 10(3), probably alpha 2 mu-globulin, in young (3.5 months old) male rats and total absence of this protein in aged (26 months old) males. RIA confirmed that constitutive levels of renal and hepatic alpha 2 mu-globulin in old rats were less than 1.5% of those in young adults. Unleaded gasoline (0.4 ml/kg/day, po, 5 days) caused accumulation of hyaline droplets in renal PCT of 3.5-month-old males accompanied by a marked increase (about twofold) in the renal content of alpha 2 mu-globulin, whereas the same treatment was without effect in 26-month-old rats. Finally, in the renal cortex of young rats the activities of the lysosomal proteases cathepsin B and D were increased following gasoline administration, presumably in response to protein accumulation. However, in 26-month-old rats cathepsin B activity was unaffected, while cathepsin D was increased by gasoline administration. Thus, we conclude that animal age is an important determinant in the development of hydrocarbon-induced nephropathy and only rats which produce large amounts of alpha 2 mu-globulin are susceptible to development of this pathology.

Leupeptin-mediated alteration of renal phagolysosomes: similarity to hyaline droplet nephropathy of male rats exposed to unleaded gasoline

alpha 2u-Globulin, a protein of hepatic origin found in the urine of male rats, is accumulated in the kidney cortex during exposure to unleaded gasoline and has been implicated in the development of fuel hydrocarbon-induced nephropathy and renal neoplasia. The principal morphological feature of gasoline-induced nephropathy is accumulation of hyaline droplets (enlarged secondary lysosomes or phagolysosomes) in epithelial cells of the proximal convoluted tubule S1 and S2 segments. Inhibition of cathepsin B (a major lysosomal peptidase) by treatment of male rats with leupeptin causes rapid accumulation of phagolysosomes and alpha 2u-globulin in the kidney very similar to gasoline exposure. Further, the renal cortical subcellular distribution of alpha 2u-globulin, determined with an electron microscopic immunochemical method, is almost totally confined to phagolysosomes following administration of either gasoline or leupeptin. These results, taken together, indicate that the mechanism of nephrotoxicity of gasoline involves inhibition of renal phagolysosomal proteolysis.

Rapid Post-Exposure Decay of a_2u -Globulin and Hyaline Droplets in the Kidneys of Gasoline-Treated Male Rats

Unleaded gasoline induces nephropathy, characterized by rapid accumulation of hyaline (protein resorption) droplets in epithelial cells of the renal proximal convoluted tubules, only in male rats. The hepatic synthesis of the male rat-specific protein alpha 2u-globulin, a constituent of renal hyaline droplets, is unaltered by gasoline treatment (Olson et al., 1987). Renal alpha 2u-globulin content increased to 210% of control within 18 h of a single oral dose of gasoline (2.0 ml/kg); maximal levels (320% of control) were attained following gasoline administration for 3 d. Increases in renal alpha 2u-globulin caused by gasoline were accompanied by concurrent proliferation of hyaline droplets. However, within 3 d of terminating gasoline administration renal alpha 2u-globulin content decreased to the same level as that in unexposed rats, although renal hyaline droplet number returned to pretreatment levels somewhat more slowly. The conjoint effect of postexposure recovery and estradiol (an inhibitor of hepatic alpha 2u-globulin synthesis) administration was also determined in male rats. On postexposure d 3, 6, and 9, estradiol treatment (1 mg/kg, sc, 4 d, starting on d 9 of gasoline treatment) decreased renal alpha 2u-globulin content to 75%, 59%, and 48%, respectively, of that in rats allowed to recover from gasoline with no hormone treatment. Hepatic alpha 2u-globulin content in estradiol-treated rats was decreased by 74%, 97%, and 96% at the same intervals. Estradiol treatment during recovery from gasoline also appeared to increase the removal of accumulated hyaline droplets from the renal cortex. Thus, accumulation of alpha 2u-globulin-containing hyaline droplets after subacute exposure of male rats to gasoline is rapidly reversible, dependent on continuous exposure to gasoline and maintenance of the normal rate of hepatic alpha 2u-globulin synthesis. These results emphasize the dynamic state of renal cortical hyaline droplets and suggest strongly that gasoline hydrocarbons cause hyaline droplet accumulation by prolonging the half-time of degradation of alpha 2u-globulin.

Defluormation of the CFC-substitute 1,1,1,2-tetrafluoroethane: comparison in human, rat and rabbit hepatic microsomes

1,1,1,2-Tetrafluoroethane (HFC-134a), which lacks ozone-depleting potential, has been selected as a replacement refrigerant for dichlorodifluoromethane (CFC-12) in air-conditioning and chiller applications, and as a propellant for pharmaceutical aerosols. A variety of paradigms using rats and rabbits have shown that HFC-134a has very little toxic potential. To strengthen the prediction of human hazard associated with HFC-134a exposure, we evaluated the rate of metabolism of this halocarbon by human hepatic microsomes relative to similar tissue preparations derived from rats and rabbits. Human microsomes defluorinated HFC-134a in a cytochrome-P-450-catalyzed reaction, common also to rat and rabbit. In absolute terms, the maximal rate of HFC-134a metabolism by human microsomes was very low, showed little interindividual variation among the samples evaluated (1.3 +/- 0.3 nmol F-/mg protein/15 min, mean +/- SD, n = 10), and did not exceed that in rat or rabbit liver microsomes. These findings support the argument that for characterization of HFC-134a toxicity, especially that which may be mediated by products of halocarbon metabolism, laboratory animals are an adequate surrogate for humans.

Interaction of fluoroethane chlorofluorocarbon (CFC) substitutes with microsomal cytochrome P450: Stimulation of P450 activity and chlorodifluoroethene metabolism

The abilities of halothane and the fluoroethane chlorofluorocarbon (CFC) substitutes, FC-123, FC-133a, FC-124, FC-134a and FC-125, to stimulate cytochrome P450 activities and 2-chloro-1,1-difluoroethene (CDE) defluorination in hepatic microsomes from phenobarbital-treated rabbits were compared. At 1% (v/v) each, halothane and FC-123 similarly increased the consumption of NADPH and O2 by 300 and 100%, respectively, over that in microsomes without substrate. FC-133a and FC-124 were less effective, increasing NADPH and O2 consumption by 150-200 and 70%. FC-134a and FC-125 were the least effective, increasing NADPH and O2 consumption by only 70 and 50%, respectively. No metabolism of any fluoroethane could be detected under the incubation conditions used. Halothane and FC-123 were most effective in stimulating CDE metabolism with increases of CDE defluorination ranging from 1.5- to 2-fold. FC-133a and FC-124 enhanced CDE oxidation 89 and 74%, respectively, and FC-134a and FC-125 had no effect. While CDE metabolism was enhanced in the presence of the fluoroethanes, no additional NADPH or O2 was consumed when halothane or FC-124 was incubated with CDE compared with incubations containing only halothane or FC-124. Log-log plots of NADPH consumption and CDE metabolism with the olive oil/gas partition coefficients of each fluoroethane showed linear relationships. These data demonstrate that the activity of the fluoroethanes in stimulating P450 activity and CDE metabolism is a function of their lipid solubility, and fluoroethane-enhanced CDE metabolism is related to the ability of these compounds to increase uncoupled P450 activity.

Phagolysosomal alterations induced by unleaded gasoline in epithelial cells of the proximal convoluted tubules of male rats: effect of dose and treatment duration.

Short-term oral administration of unleaded gasoline to male rats reproduces the accumulation of phagolysosomes (hyaline droplets) in epithelial cells of the renal proximal convoluted tubules (PCT) observed following long-term inhalation of wholly volatilized gasoline. Phagolysosomes are partially composed of alpha 2u-globulin, a low-molecular-weight protein, unique to male rats. In this study, dose-dependent and chronologic alterations of phagolysosomes caused by gasoline were observed by transmission electron microscopy. Exposure to commercially available unleaded gasoline (0.4-2.0 ml/kg, po, once daily, 9 d) increased the number and size of phagolysosomes in epithelial cells of the PCT in male rat kidney. However, administration of 0.04 ml gasoline/kg or less was ineffective in inducing phagolysosomal accumulation. Subcellular analysis revealed that many of the phagolysosomes observed in treated rats (doses greater than 0.4 ml/kg) were angular and had cross-sectional diameters varying from 0.5 to 9 microns; in controls the majority of phagolysosomes were round and their diameter varied from 0.5 to 2.5 microns. Treatment of male rats with gasoline (2.0 ml/kg body weight, po, 1-9 d) caused a progressive increase in the number and size of phagolysosomes in PCT epithelial cells dependent on treatment duration. Alterations in phagolysosomal morphology and quantity occurred within 20 h following a single dose of gasoline, emphasizing that the process of phagolysosome accumulation is a dynamic phenomenon. Many of the enlarged phagolysosomes contained a condensed, crystalline core of greater electron density than the surrounding matrix. Furthermore, the rapid increase in abnormal, condensed contents in the phagolysosomes may indicate that a derangement of renal protein catabolism is the primary mechanism by which fuel hydrocarbons cause hyaline droplet nephropathy in male rats.

Defluorination of 1,1,1,2-tetrafluoroethane (R-134a) by rat hepatocytes.

As part of its toxicological evaluation we assessed the in vitro metabolism of 1,1,1,2-tetrafluoroethane (R-134a), a non-ozone-depleting chemical likely to replace dichlorodifluoromethane (R-12) as an air-conditioning refrigerant. Hepatocyte suspensions in sealed flasks produced increasing quantities of F- (detected in the liquid media) as the headspace concentration of R-134a increased from 1% to 50% (balance of atmosphere 95% O2-5% CO2); the kinetics of defluorination suggested substrate-saturation. Little F- was detected in cultures without R-134a or in cell suspensions heated prior to addition of R-134a. Halothane (1,1,1-trichloro-2-bromo-2-chloro-ethane), although not defluorinated by hepatocytes maintained with 95% O2, inhibited defluorination of R-134a. Hepatocytes from phenobarbital-treated rats dehalogenated high (greater than or equal to 25%) concentrations of R-134a at greater rates than cells from untreated rats. These findings are consistent with the hypothesis that oxidative metabolism of R-134a by cytochrome P-450 can occur in vivo.