Strain Difference in Sensitivity of Mice to Renal Toxicity of Inorganic Mercury

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Vol. 285, Issue 1, 335-341, April 1998

Strain Difference in Sensitivity of Mice to Renal Toxicity of Inorganic Mercury¹

Toshiko Tanaka-Kagawa, Mieko Suzuki, Akira Naganuma, Nobuaki Yamanaka and Nobumasa Imura

Department of Public Health, School of Pharmaceutical Sciences, Kitasato University, 5-9-1 Shirokane, Minato-ku, Tokyo 108, Japan (T.T.-K., M.S., N.I.), Department of Molecular and Biochemical Toxicology, Faculty of Pharmaceutical Sciences, Tohoku University, Aoba-ku, Sendai 980-77, Japan (A.N.) and Department of Pathology (I), Nippon Medical School, 1-1-5 Sendagi, Bunkyo-ku, Tokyo 113, Japan (N.Y.)

	Abstract

Top Abstract Introduction Methods Results Discussion References

Inorganic mercury has a high affinity for the kidneys and causes acute renal failure. The present investigation was designedto determine the cause of the strain difference in sensitivityof mice to the renal toxicity of inorganic mercury. Renal damagecaused by HgCl₂ was estimated by histopathological and biochemicalassessment, such as increase in blood urea nitrogen and plasmacreatinine levels, and was found to be more remarkable in C3H/Hethan in C57BL/6 mice. Increase in renal lipid peroxidation inC3H/He was greater than that in C57BL/6 mice. However, no straindifference was observed in renal activities of glutathione (GSH)peroxidase, superoxide dismutase and GSH S-transferase in HgCl₂-untreatedmice. The GSH content and activities of catalase and GSSG reductasein kidney of HgCl₂-untreated mice were higher in C3H/He than inC57BL/6. Background level of renal metallothionein content andthe extent of metallothionein induction by HgCl₂ showed no straindifference. On the other hand, renal mercury accumulation washigher and urinary mercury excretion was lower in C3H/He thanin C57BL/6. The activity of renal $gamma$ -glutamyltranspeptidase ( $gamma$ -GTP),which plays a key role in renal mercury accumulation, was higherin C3H/He than in C57BL/6. Furthermore, the increase in bloodurea nitrogen by HgCl₂, renal mercury accumulation and renal $gamma$ -GTPactivity in B6C3F1 mice were intermediate between those of theparent strains. These results suggest that the strain differencein renal toxicity of inorganic mercury seems to be caused by thediscrepancy in renal mercury accumulation, and therefore, renal $gamma$ -GTP may be an important factor determining the susceptibilityof mice to the toxic action of inorganic mercury.

	Introduction

Top Abstract Introduction Methods Results Discussion References

The metabolism of xenobiotics including heavy metals and their effects on living organisms can vary greatly by differencesin species, strain, sex and age. Many of the variations seen inthe metabolism of these compounds are considered to be the resultof genetic differences, but the concrete causes for these differencesare not well understood.

Inorganic mercury accumulates preferentially in kidneys and causes acute renal failure. Several investigators have reportedstrain differences in tissue distribution (Doi et al., 1983),excretion rate (Yasutake and Hirayama, 1986) and susceptibilityto the toxicity (Yasutake and Hirayama, 1988) of methyl mercuryin mice. However, strain difference in the distribution and susceptibilityto the toxicity of inorganic mercury remains to be elucidated.The purpose of the present study, therefore, is to investigatethe strain difference in sensitivity of mice to the toxicity ofinorganic mercury.

Mercury compounds cause oxidative damage in renal proximal tubule cells, which has been characterized by depletion of reducedGSH (Gstraunthaler et al., 1983), increased mitochondrial hydrogenperoxide production, lipid peroxidation (Lund et al., 1993) andthe oxidation of reduced porphyrins (Woods et al., 1990). Therefore,strain difference in the extent of mercury-induced lipid peroxidationas well as in the levels of several cellular antioxidative factors,including SOD, catalase, GST and GSH-Px were investigated in thisstudy.

Metallothionein is a metal-binding protein of low molecular weight thought to play a role in the homeostasis of essentialmetals such as zinc and copper (Bremner and Beattie, 1990). Itmay be involved in the detoxification of heavy metals, and scavengefree radicals. Inorganic mercury induces synthesis of MT and bindsto it (Piotrowski et al., 1974). The renal toxicity of inorganicmercury was prevented significantly by preinduction of MT synthesisin rats (Zalups and Cherian, 1992). Renal MT may bind to Hg(II)and suppress its toxic action in the kidney cells. Therefore,in the present study strain differences in MT levels and its inductionwere also investigated.

Mercury compounds have high affinity to SH groups (Bach and Weibel, 1976). Recent data obtained from both mice (Tanaka etal., 1990) and rats (Zalups and Barfuss, 1995) indicate that exogenousGSH causes an increase in the renal tubular uptake of mercury.Our previous data indicate that when hepatic GSH is depleted specificallywith 1,2-dichloro-4-nitrobenzene before the administration ofinorganic mercury, the renal accumulation and toxicity of inorganicmercury are diminished significantly (Tanaka et al., 1990). Theseresults suggest that hepatic GSH, as a source of plasma GSH, playsan important role in the renal uptake of mercury. In several recentstudies, inhibition of renal $gamma$ -GTP by pretreatment with acivicinhas caused a decrease in the renal uptake and/or accumulationof mercury and an increase in the urinary excretion of mercuryin mice administered inorganic mercury (Tanaka et al., 1990; Tanaka-Kagawaet al., 1993) or methyl mercury (Naganuma et al., 1988; Tanakaet al., 1992a; Tanaka-Kagawa et al., 1993) and rats administeredinorganic mercury (Zalups, 1995). These results suggest that mercurialsin the lumen of proximal tubules which are filtered through theglomeruli or translocated from tubular cells exist as a mercury-GSHcomplex. This mercury-GSH complex may also serve as a substratefor $gamma$ -GTP and the final product, mercury-cysteine, may be takenup by renal cells after degradation of the GSH moiety in the samemanner as in the metabolism of GSH itself. We have also reportedthat age-, sex- and strain-related differences were observed inrenal mercury content of mice treated with methyl mercury whichwas correlated significantly with the renal $gamma$ -GTP activity (Tanakaet al., 1991, 1992b). These findings suggest the possibility thatsimilar strain differences as described above should also be observedin the sensitivity of mice to inorganic mercury.

	Methods

Top Abstract Introduction Methods Results Discussion References

Chemicals. Glutathione was obtained from Boehringer Mannheim GmbH (Indianapolis, IN). Other chemicals were obtained from Wako Pure ChemicalIndustries Ltd. (Osaka, Japan).

Animals. Male mice of two inbred strains, C57BL/6 and C3H/He and their F1, B6C3F1 (C57BL/6 female × C3H/He male), were used in theexperiments 4 weeks after birth. They were supplied through CharlesRiver, Japan Inc., Tokyo, and kept in metabolism cages (one mouseper cage) in a room equipped with a 12-hr light cycle. They receivedlaboratory chow (CE-2, CLEA Japan) and water ad libitum.

Survival study. C3H/He and C57BL/6 mice were injected with HgCl₂ (35 µmol/kg s.c.) and the survival rate for 5 days was examined.

Renal toxicity studies. C3H/He and C57BL/6 mice were treated with HgCl₂ (20 µmol/kg s.c.) and blood samples were collected from animals under etheranesthesia at 12, 24, 48 and 72 hr after the injection. Bloodwas collected from the femoral vein into heparinized containers.Blood samples were separated into plasma and red blood cells bycentrifugation (800 × g, 5 min). BUN and plasma creatinine valuesas indicators of renal damage were determined by the NADH-coupledenzymatic method using urease (Hallett and Cook, 1971) and colorimetricdetermination based on the Jaffe reaction (Jaffe, 1886) usinga commercially available assay kit (Wako Pure Chemicals Ind.,Osaka, Japan), respectively.

Lipid peroxidation in the kidneys was determined by quantitating the TBA-RS by the method of Ohkawa et al. (1979)

In separate experiments, C3H/He, C57BL/6 and B6C3F1 mice were treated with HgCl₂ (20 and 25 µmol/kg s.c.) and blood samplesfor BUN determination were collected from animals under etheranesthesia at 48 hr after the injection.

Histopathological examination. Four mice each in C3H/He and C57BL/6 strains were sacrificed on days 1 (24 hr), 2, 3, 5, 10 after the dorsal subcutaneousinjection of HgCl₂ (20 µmol/kg). Four normal aged-matched, unmanipulatedmice in each group were studied as controls. After removal ofthe kidney, tissue blocks were fixed in 20% formalin and embeddedin paraffin, and sectioned at 2~3 µm. Hematoxylin-eosin and periodicacid-Schiff stains were performed for light microscopic studies.

Determination of tissue distribution and urinary excretion of mercury. C3H/He and C57BL/6 mice were injected with HgCl₂ (20 µmol/kg s.c.). Urine was collected in metabolism cages (one mouse/cage)and also by bladder puncture. Kidney, liver, brain, heart, lungand spleen were removed 1, 4, 8, 12, 24, 48 and 72 hr after HgCl₂injection. In a separate experiment, C3H/He, C57BL/6 and B6C3F1mice were injected with HgCl₂ (20 µmol/kg s.c.). Urine was collectedin metabolism cages (one mouse/cage) and also by bladder puncture.Kidney, liver, brain, heart, lung and spleen were removed at 2,4, 8 and 16 hr after HgCl₂ injection. Mercury contents in tissues,blood and urine were determined by the reductive vapor-atomicabsorption method using a mercury analyzer (RA-2, Nippon InstrumentsCo., Tokyo, Japan) after wet digestion with nitric acid.

Determination of renal GSH concentration. Renal GSH concentration was measured by high-performance liquid chromatography with SBD-F as a fluorogenic reagent (Toyo'okaand Imai, 1983) as described previously (Tanaka-Kagawa et al.,1993).

Measurement of enzyme activity. Activities of catalase, GSH-Px, GST, GSSG-reductase and SOD in kidney of HgCl₂-untreated mice were measured. For measurementof the activity of GSH-Px, GST and GSSG-reductase, kidneys werehomogenized in 9 volumes of 0.25 M sucrose solution, and the homogenateswere centrifuged at 105,000 × g for 1 hr at 4°C. GSH-Px activityin the supernatant was determined by the method of Lawrence andBurk (1976) with H₂O₂, tert-butyl hydroperoxide or cumene hydroperoxideas a substrate. GST activity in the cytosol was determined bythe method of Habig et al. (1974) by using 1-chloro-2,4-dinitrobenzeneas a substrate. GSSG-reductase in the cytosol was determined bythe method of Carlberg and Mannervik (1985). For assay of theactivity of catalase and SOD, kidneys were homogenized by sonicationin 24 volumes of 20 mM potassium phosphate buffer (pH 8.0) containing14 mM sodium borate and 0.2 mM ethylenediaminetetraacetic acid,disodium salt. Catalase activity was assayed by the method ofJohansson and Borg (1988). SOD activity was determined by themethod of Ohyanagui (1984). Because Cu,Zn-SOD is blocked by cyanide,the activity measured in the presence of 25 mM potassium cyanidecorresponds to Mn-SOD activity and that measured in the absenceof cyanide corresponds to the sum of Mn-SOD and Cu,Zn-SOD activities. $gamma$ -GTP activity in the 800 × g supernatant was determined by themethod of Tate and Meister (1974) with $gamma$ -glutamyl-p-nitroanilideas substrate.

Protein was determined colorimetrically using Coomassie blue binding (Bio-Rad Protein Assay, Bio-Rad Laboratories, Richmond,CA), with $gamma$ -globulin as a standard.

Determination of MT. MT content was determined by the ²⁰³Hg-binding assay (Kotsonis and Klaassen, 1977) as modified by Naganuma et al. (1987) as describedpreviously (Tanaka-Kagawa et al., 1993).

Statistics. Data are expressed as means ± S.D. from four to eight mice. Data were statistically analyzed by one- or two-way analysis ofvariance. When F-values obtained with the analysis of variancewere found to be statistically significant (P < .05), the Scheffe'smultiple comparison post hoc test was used. Student's t test wasused to determine the significance of the difference in activitiesof antioxidative enzymes in mouse kidney between C3H/He and C57BL/6mice.

	Results

Top Abstract Introduction Methods Results Discussion References

Strain difference in susceptibility to mercury toxicity. Figure 1 shows the strain difference in lethal toxicity of HgCl₂. Five days after administration of HgCl₂ (35 µmol/kg s.c.)all mice of the C57BL/6 strain survived, whereas 40% of C3H/Hestrain mice died.

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Fig. 1. Strain difference in lethal toxicity of HgCl_2. Mice (n = 8) were treated subcutaneously with 35 µmol/kg of HgCl₂.

Both BUN and plasma creatinine levels measured as biological indicators of renal damage dramatically increased in C3H/He micetreated with HgCl₂ (fig. 2). In contrast, BUN levels increasedslightly, and no significant increase was observed in plasma creatininelevels of C57BL/6 mice after HgCl₂ injection (fig. 2).

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Fig. 2. Time courses of BUN and plasma creatinine levels of mice treated with HgCl₂ (20 µmol/kg s.c.). Each point represents mean ± S.D. of four to six mice. *, ***Significantly different from the untreated group (*P < .05, ***P < .001).

Figure 3 shows morphological changes in the renal tissue after HgCl₂ administration. The proximal tubule cells mainly in portionsof the S2 and S3 segments were injured in C3H/He mice (fig. 3D).The changes, including swelling, degeneration, necrosis and sloughingof tubular epithelial cells, were observed in C3H/He mice 24 hrafter the injection of HgCl₂ (fig. 3, D and E). These changesprogressed at day 2 to day 3 after the injection of HgCl₂ andno rupture of the tubular basement membrane was detected in theperiodic acid-Schiff-stained specimens (data not shown). Then,regeneration of tubular cells were observed at day 5 (data notshown). However, the changes in renal tissue were less evidentin C57BL/6 mice (fig. 3F, at 24 hr) throughout the whole experimentalperiod. No obvious change was detected in glomeruli of both C3H/Heand C57BL/6 mice. These results indicate that the renal toxicitiescaused by HgCl₂ were more severe in C3H/He mice than in C57BL/6mice.

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Fig. 3. Light microscopic assessment of the strain difference in nephrotoxicity 24 hr after the administration of HgCl₂ (20 µmol/kg s.c.). (A, B) Renal cortex of a C3H/He mouse untreated with HgCl₂. (C) Renal cortex of a C57BL/6 mouse untreated with HgCl₂. (D) Renal cortex of a C3H/He mouse treated with HgCl₂. Proximal tubular cells are injured mainly in the S2 and S3 segments, as shown by decreased staining areas. (E) Renal cortex of a C3H/He mouse treated with HgCl₂. Prominent injuries of proximal tubular cells, including swelling, degeneration, necrosis and sloughing. (F) Renal change of a C57BL/6 mouse treated with HgCl₂. Tubular damages are less evident than in C3H/He mice. (hematoxylin-eosin stain, A and D original magnification, ×12; B, C, E and F, ×40)

Numerous studies have suggested that oxidative tissue damage is a principal underlying action of mercury-induced nephrotoxicity(Woods et al., 1990

; Lund et al., 1993

). TBA-RS levels of thekidney, an indicator of lipid peroxidation, in C3H/He mice increasedto 2.5-fold at 1 hr and 4 hr after HgCl₂ injection (fig. 4). However,no remarkable increase in renal TBA-RS level was observed in C57BL/6mice treated with HgCl₂, although 1.6-fold increase was seen at1 hr after treatment (fig. 4).

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Fig. 4. Time course of TBA-RS level in kidneys of mice treated with HgCl₂ (20 µmol/kg s.c.). Each point represents mean ± S.D. of four to six mice. *, **Significantly different from untreated group (*P < .05, **P < .01).

To investigate the possible mechanism underlying the strain difference in renal damage after mercury treatment, backgroundlevels of free radical scavenging factors were measured in bothstrains of mice untreated with HgCl₂. As shown in table 1, nosignificant strain difference was observed in renal activity ofGSH-Px, SOD and GST. Moreover, activities of catalase and GSSGreductase were higher in C3H/He than in C57BL/6, which is moreresistant to HgCl₂ than C3H/He.

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TABLE 1
Enzyme activities in kidney of mice untreated with HgCl₂

It has been suggested that cellular GSH and MT are major determinants of HgCl₂ toxicity. Renal GSH concentration of HgCl₂-untreatedmice was lower in C57BL/6, which is more resistant to HgCl₂ thanC3H/He. Strain difference accounting for the higher sensitivityof C3H/He mice to renal toxicity of inorganic mercury was notobserved in GSH concentration of HgCl₂-treated mouse kidney (table2). No strain difference in renal MT content was observed inHgCl₂-untreated mice, and renal MT content in both strains ofmice was similarly increased for 24 hr after HgCl₂ treatment (table3). At 48 and 72 hr after HgCl₂ treatment, renal MT content inC57BL/6 mice was lower than that in C3H/He mice (table 3). Thus,resistance of C57BL/6 mice to lethal and renal toxicity of HgCl₂can not be ascribed to these biological factors.

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TABLE 2
Renal GSH concentration (µmol/g tissue)^a

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TABLE 3
Renal MT concentration (Hg bound nmol/g tissue)^a

Mercury distribution and excretion. The percentage of injected mercury found in kidneys and urine at various times after injection is shown in figure 5. Renalmercury level was highest at 4 hr after HgCl₂ administration inboth C3H/He and C57BL/6 mice, but distribution of mercury to thekidneys was dramatically lower and urinary mercury excretion wasmarkedly higher in C57BL/6 mice than in C3H/He mice (fig. 5).No apparent difference in mercury content in liver, heart, lung,spleen, testis, brain, plasma and red blood cells was observedbetween C3H/He and C57BL/6 mice at 4 hr after HgCl₂ injection(data not shown). These results suggest that the relative insensitivityof the C57BL/6 mice to HgCl₂ toxicity simply may be related tothe lower mercury accumulation in the kidneys than that in C3H/Hemice.

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Fig. 5. Time courses of renal mercury content and cumulative mercury excretion in urine. Mice were treated subcutaneously with 20 µmol/kg of HgCl₂. Each point represents mean ± S.D. of four to six mice. *, **, ***Significantly different from C3H/He (*P < .05, **P < .01, ***P < .001).

We have reported previously that hepatic and plasma GSH and renal $gamma$ -GTP can be determinants of renal mercury uptake in micetreated with methyl mercury. To investigate the strain differencein factors regulating renal mercury accumulation, background levelsof tissue GSH concentration and renal $gamma$ -GTP activity were determined.No significant strain difference was observed in plasma and hepaticGSH concentration (data not shown), whereas renal $gamma$ -GTP activityin C57BL/6 mice was lower than in C3H/He mice (fig. 6).

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Fig. 6. Strain difference in renal $gamma$ -GTP activity. Values represent mean ± S.D. of six mice. ***Significantly different from the specified group (P < .001).

To investigate whether the sensitivity of mice to renal toxicity of inorganic mercury is controlled genetically, renal damagecaused by HgCl₂ was estimated in C3H/He, C57BL/6 and their hybridF1 generation, B6C3F1 mice. Level of increase in BUN (fig. 7)in B6C3F1 mice was intermediate between C3H/He and C57BL/6. Furthermore,renal mercury accumulation and urinary mercury excretion of B6C3F1mice injected with HgCl₂ tended to be intermediate between thoseof the parent strains except for the renal mercury content at2 hr after HgCl₂ treatment (fig. 8). Renal $gamma$ -GTP activity of B6C3F1also showed the intermediate value (fig. 6).

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Fig. 7. BUN level in mice 48 hr after administration of HgCl₂ (20 or 25 µmol/kg s.c.). Values represent mean ± S.D. of five to eight mice. **, ***Significantly different from the untreated group (**P < .01, ***P < .001). ,Significantly different from specified group (P < .05,P < .001)

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Fig. 8. Time courses of renal mercury content and cumulative mercury excretion in urine. Mice were treated subcutaneously with 20 µmol/kg of HgCl₂. Each point represents mean ± S.D. of five to eight mice. ^{a, b, c}Values with different letters are significantly different from each other at each time point (P < .05).

	Discussion

Top Abstract Introduction Methods Results Discussion References

Although organ distribution and toxicity of inorganic mercury have been studied by numerous investigators, strain differencesin susceptibility to the toxicity of inorganic mercury have notbeen reported previously. The data presented in this paper demonstratethat C57BL/6 mice are considerably more insensitive to HgCl₂-inducedlethal and renal toxicity than C3H/He mice, and the relative insensitivityof the C57BL/6 mice may simply be related to the lower mercuryaccumulation in the kidneys than that in C3H/He mice. Strain differencesin renal mercury accumulation may result from different activityof renal $gamma$ -GTP, which plays an important role in renal mercuryaccumulation.

Levels of BUN and plasma creatinine which indicate renal failure dramatically increased 2 days after HgCl₂ injection in C3H/Hemice. Changes in renal morphology after HgCl₂ injection were alsomore evident in C3H/He mice than in C57BL/6 mice. Morphologicalchanges caused by HgCl₂ were observed in tubular cells but notin glomeruli in both C3H/He and C57BL/6 mice by light microscopicstudies in the present investigation. Autoradiographic studies(Berlin and Ulberg, 1963) previously showed that Hg(II), administeredas HgCl₂ to mice, rapidly accumulated in the renal cortex, andthat the highest concentration was detected in the S3 segmentof the proximal tubules. It is well known that a sublethal doseof HgCl₂ causes necrosis of pars recta in the kidneys of ratsand mice within 24 hr. In the present investigation treatmentof mice with HgCl₂ produced severe injury in proximal tubularcells as reported previously. We have demonstrated that a straindifference was observed in the extent of renal failure but notin the locus of the damaged regions in the kidneys.

Measurement of BUN and plasma creatinine levels is the most commonly used procedure for assessment of glomerular function.In the present study levels of BUN and plasma creatinine increasedin C3H/He mice by HgCl₂ treatment, although no morphological changeswere observed in glomeruli by light microscopy. The elevationof BUN and plasma creatinine levels may result from glomerulardamage that cannot be detected by light microscopic observationin the present study or from reduction of the glomerular filtrationrate caused by tubuloglomerular feedback. The tubuloglomerularfeedback hypothesis (Thurau and Boylan, 1978) proposes that proximaltubular damage results in failure of the normal reabsorption ofthe filtered sodium chloride, and the concentration of this substance,therefore, rises in the distal tubules. The elevated sodium chlorideis sensed by the macula densa which responds by inducing the releaseof renin leading to local generation of angiotensin II. The angiotensinII causes arteriolar constriction, decreased filtration pressureand a reduction in the glomerular filtration rate (Thurau andBoylan, 1978).

Glutathione is the major cytosolic low molecular weight sulfhydryl compound which acts as a cellular reducing reagent andis protective against numerous toxic substances including heavymetals. Treatment of animals with an inhibitor of GSH synthesisor GSH depletors markedly sensitized mice to Hg (II) toxicity(Berndt et al., 1985; Naganuma et al., 1990), which suggests thatcellular GSH is a major determinant of Hg (II) toxicity. In thepresent study, renal TBA-RS level as an indicator of oxidativedamage was increased by HgCl₂ treatment. Glutathione may playan important role in the prevention of mercury-induced oxidativedamage as a direct scavenger or by scavenging as a collaboratingfactor with GSH-Px. Thus GSH may be one cause of the strain differencein renal damage induced by HgCl₂. However, we observed no differencein renal GSH concentration between the two strains of mouse whichwould account for the higher sensitivity of C3H/He mice to renaltoxicity of inorganic mercury.

The kidney damage caused by inorganic mercury was prevented by preinduction of renal MT because intracellular mercury in thekidney is firmly trapped by the MT (Zalups and Cherian, 1992).Furthermore, the sensitivity to the renal toxicity of HgCl₂ wasenhanced markedly in the transgenic mice that are deficient inthe MT-I and MT-II genes (MT-null mice) (Satoh et al., 1997).These findings suggest that MT is an important protective factoragainst the renal toxicity caused by inorganic mercury. In thepresent study, no strain difference was observed in renal MT contentof HgCl₂-untreated mice. Furthermore, the extent of MT inductionwas similar in the C3H/He and C57BL/6 strains. These results suggestthat the strain difference in sensitivity to HgCl₂ was not causedby renal MT levels in these strains of mice.

Several recent studies suggested that the renal $gamma$ -GTP plays an important role not only in renal uptake but also in renal storageof mercurials (Tanaka-Kagawa et al., 1993: Zalups, 1995). As reportedpreviously (Tanaka et al., 1991), renal $gamma$ -GTP activity in C57BL/6mice was lower than that in C3H/He mice. The present study revealedthat renal $gamma$ -GTP activity in B6C3F1 mice was intermediate betweenthe activities in the parent strains. Furthermore, this studyobserved that renal mercury accumulation and renal damage in B6C3F1mice treated with HgCl₂ were also intermediate. These facts indicatethat the strain difference in sensitivity to HgCl₂-induced toxicitymay be explained by the discrepancy in renal mercury accumulation.Furthermore, renal $gamma$ -GTP, as a determinant of renal mercury accumulation,may be an important factor in determining the susceptibility ofmice to mercury toxicity.

	Footnotes

Accepted for publication December 29, 1997.

Received for publication September 2, 1997.

¹ This work was supported in part by Kitasato University of Research Grant for Young Researchers. This work was presented atthe 114th Annual Meeting of The Pharmaceutical Society of Japanin April 1994.

Send reprint requests to: Nobumasa Imura, Department of Public Health, School of Pharmaceutical Sciences, Kitasato University, 9-1 Shirokane 5-chome, Minato-ku, Tokyo 108, Japan.

	Abbreviations

BUN, blood urea nitrogen; GSH, glutathione; $gamma$ -GTP, $gamma$ -glutamyltranspeptidase; MT, metallothionein; SBD-F, ammonium 7-fluorobenzo-2-oxa-1,3-diazole-4-sulfonate; TBA-RS, thiobarbiturate-reactive substances; GSH-Px, glutathione peroxidase; GST, glutathione S-transferase; GSSG, oxidized glutathione; SOD, superoxide dismutase.

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Strain Difference in Sensitivity of Mice to Renal Toxicity of Inorganic Mercury1

Strain Difference in Sensitivity of Mice to Renal Toxicity of Inorganic Mercury¹