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Abstract

Our earlier histomorphometric and biochemical studies suggested that the progressive phase of the interactive toxicity of chlordecone (CD) + CCl₄ involves suppression of hepatocellular regeneration. The objective of the present work was to correlate hepatocellular regeneration with CCl₄ (100 μl/kg)-induced hepatotoxicity in rats maintained for 15 days on a normal (N) diet, relative to the regenerative response in rats maintained on a diet containing either 10 ppm CD, 225 ppm phenobarbital (PB), or 10 ppm mirex (M). Hepatocellular regeneration was assessed by measuring DNA and ³H-thymidine (³H-T) incorporation, followed by autoradiographic analysis of liver sections. Hepatotoxicity was assessed by measuring plasma transaminases (aspartate and alanine) followed by histopathological observations of liver sections for necrotic, swollen, and lipid-laden cells. Lethality studies were also carried out to assess the consequence of hepatotoxicity on animal survival. Dietary 10 ppm CD potentiated the hepatotoxicity of CCl₄ to a greater extent than PB or M, as evidenced by elevations in plasma enzymes. Although the serum enzymes were significantly elevated in PB rats in contrast to the slight elevations in N and M rats, they returned to normal levels by 96 hr. However, serum enzyme elevations in CD rats were progressive with time until death of the animals. Actual liver injury by CCl₄ was greater in PB- than in CD-pretreated rats, as evidenced by histopathological observations. A 100% mortality occurred in CD-pretreated rats at 60 hr after CCl₄ administration, whereas no mortality occurred in either N-, M-, or PB-pretreated rats, indicating recovery from liver injury. Hepatocellular nuclear DNA levels were significantly decreased starting at 6 hr after CCl₄ administration to CD-pretreated rats, but not in M- or PB-pretreated rats. ³H-T incorporation into nuclear DNA as well as percentage of labeled cells showed a biphasic increase in N rats: 1 at 1-2 hr, and the other at 36-48 hr after CCl₄ administration. However, only 1 peak of ³H-T incorporation at 36-48 hr was observed in the CD + CCl₄ combination, which was also significantly lower when compared to that observed after the M or PB + CCl₄ combination treatments. These findings suggest that there is recovery in N-, PB-, or M-pretreated rats from CCl₄-induced injury by virtue of the stimulated hepatocellular regeneration and tissue repair. In CD-pretreated rats, CCl₄ toxicity is progressive because of mitigated hepatocellular regeneration (at 2-6 hr), supporting the concept that hepatocellular regeneration plays a critical role in determining whether hepatotoxicity becomes permissively progressive or actively regressive, owing to tissue repair mechanisms. In the absence of hepatocellular regeneration and tissue repair, progressive liver injury leads to sustained hepatic failure (24 hr), culminating in animal death. These findings underscore the importance of assessing additional parameters of hepatobiology indicative of the ultimate outcome of toxicity rather than relying solely on indices of liver injury, particularly during the inflictive phase of chemically-induced liver injury.

Keywords

Mirex carbon tetrachloride potentiation

References

Agarwal AK and Mehendale HM (1983). Potentiation of CCl4 hepatotoxicity and lethality by chlordecone in female rats. Toxicology 26: 231-242.

Azmendariz-borunda J. , Seyer JM , Kang AH , and Raghow R. (1990). Regulation ofTGFβ gene expression in rat liver intoxicated with carbon tetrachloride. FASEB J. 4: 215-221.

Bell AN , Young RA , Lockard VG , and Mehendale HM (1988). Protection of chlordecone potentiated CCl4 hepatotoxicity and lethality by partial hepatectomy. Arch. Toxicol. 61: 392-405.

Burton K. (1956). A study of the conditions and mechanism of the diphenylamine reaction for the colorimetric estimation of DNA. Biochem. J. 62: 315-323.

Butler TC (1961). Reduction of carbon tetrachloride in vivo and reduction of carbon tetrachloride and chloroform in vitro by tissues and tissue constituents. J. Pharmacol. Exp. Ther. 134: 311-319.

Carlson GP (1975). Potentiation of carbon tetrachloride hepatotoxicity in rats by pretreatment with polychlorinated biphenyls. Toxicology 5: 69-77.

Carlsson R. , Engvall E. , Freeman A. , and Ruoslahti E. (1981). Laminen and fibronectin in cell adhesion: Enhanced adhesion of cells from regenerating liver to laminin. Proc. Natl. Acad. Sci. USA 78: 2403-2406.

Chang LO and Looney WB (1965). A biochemical and autoradiographic study of the in vivo utilization of tritiated thymidine in regenerating rat liver. Cancer Res. 25: 1817-1822.

Chang LW , Pereira MA , and Klaunig JE (1985). Cytotoxicity of halogenated alkanes in primary cultures of rat hepatocytes from normal, partial hepatectomized and preneoplastic/neoplastic liver. Toxicol. Appl. Pharmacol. 80: 274-283.

10.

Chauveau J. , Moule Y. , and Rouiller CH (1956). Isolation of pure and unaltered liver nuclei morphology and biochemical composition . Exp. Cell Res. 11: 317-321.

11.

Cheeseman KH , Albano EF , Tomasi A. , and Slater TF (1985). Biochemical studies on the metabolic activation of halogenated alkanes. Environ. Health Persp. 64: 85-101.

12.

Columbano, A. , Ledda-Columbano GM , Ennas MG , Curto M. , Chelo A. , and Pani P. (1990). Cell prolif eration and promotion of rat liver carcinogenesis: Different effect of hepatic regeneration and nitrogen induced hyperplasia on the development of enzyme altered foli carcinogenesis. 11: 771-776.

13.

Connor HD , Thurman RG , Galiz MD , and Mason RP (1986). The formation of a novel free radical metabolite from CCl4 in the perfused rat liver and in vivo. J. Biol. Chem. 261: 4542-4548.

14.

Curtis LR and Mehendale HM (1979). The effect of kepone pretreatment on biliary excretion of xenobiotics in the male rat. Toxicol. Appl. Pharmacol. 47: 295-303.

15.

Curtis LR and Mehendale HM (1980). Specificity of chlordecone-induced potentiation of carbon tetrachloride hepatotoxicity. Drug Metab. Dispos . 8: 23-27.

16.

Curtis LR , Williams WL , and Mehendale HM (1979). Potentiation of hepatotoxicity of CCl4 following preexposure to chlordecone (Kepone®) in the male rat. Toxicol. Appl. Pharmacol. 51: 283-293.

17.

Davis ME and Mehendale HM (1980). Functional and biochemical correlation of chlordecone enhancement of CCl4 hepatotoxicity. Toxicology 15: 91-103.

18.

Frank H. , Haussman HJ , and Remmer H. (1982). Metabolic activation of carbon tetrachloride: Induction of cytochrome P-450 with phenobarbital or 3-methylcholanthrene and its effects on covalent binding. Chem. Biol. Interact. 40: 193-208.

19.

Gad S. and Weil CS (1986). Statistics and Experimental Design for Toxicologists . Telford Press, West Caldwell, New Jersey.

20.

Garner RC and McLean AEM (1969). Increased susceptibility to CCl4 poisoning in the rat after pretreatment with oral phenobarbitone. Biochem. Pharmacol. 18: 645-650.

21.

Gomez-Lechon J. and Castell JV (1987). Evidence for arrested cell subpopulation in rat liver inducible to mitosis. Cell Tissue Kinet. 20: 583-590.

22.

Goyette M. , Petropoulos CJ , Shank PR , and Fausto N. (1983). Regulated transcription of C-Ki-ras and C-myc during compensatory growth of rat liver. Science 219: 510-512.

23.

Gude WD (1968). Autoradiographic Techniques. Printice-Hall, Englewood Cliffs, New Jersey.

24.

Hewitt WR , Miyajima H. , Cote MG , and Plaa GL (1980). Modification of haloalkane-induced hepatotoxicity by exogenous ketones and metabolic ketosis. Fed. Proc. 39: 3118-3123.

25.

Higgins GM and Anderson RM (1931). Experimental pathology of the liver. 1. Restoration of the liver of the white rat following partial surgical removal. Arch. Pathol. 12: 186-202.

26.

Klingensmith JS and Mehendale HM (1982). Potentiation of CCl4 lethality by chlordecone. Toxicol. Lett. 11: 149-154.

27.

Klingensmith JS , Lockard VG , and Mehendale HM (1983). Acute hepatotoxicity and lethality of CCl4 in chlordecone pretreated rats . Exp. Mol. Pathol. 39: 1-10.

28.

Klingensmith JS and Mehendale HM (1983). Hepatic microsomal metabolism of CCl4 after pretreatment with chlordecone, mirex or phenobarbital in male rats. Drug Metab. Dispos. 11: 329-334.

29.

Kodavanti PRS , Joshi UM , Lockard VG , and Mehendale HM (1989). Chlordecone (Kepone®)-potentiated carbon tetrachloride hepatotoxicity in partially hepatectomized rats-A histomorphometric study. J. Appl. Toxicol . 9: 367-375.

30.

Kodavanti PRS , Joshi UM , Young RA , Bell AN , and Mehendale HM (1989). Role of hepatocellular regeneration in chlordecone potentiated hepatotoxicity of carbon tetrachloride . Arch. Toxicol. 63: 367-375.

31.

Kodavanti PRS , Joshi UM , Young RA , Meydrech EF , and Mehendale HM (1989). Protection of hepatotoxic and lethal effects of CCl4 by partial hepatectomy . Toxicol. Pathol. 17: 494-506.

32.

Kodavanti PRS , Kodavanti UP , and Mehendale HM (1990). Altered hepatic energy status in chlordecone (Kepone®)-potentiated CCl4 hepatotoxicity . Biochem. Pharmacol. 40: 859-866.

33.

Kodavanti PRS , Kodavanti UP , and Mehendale HM (1991). Carbon tetrachloride-induced alterations of hepatic calmodulin and free calcium levels in rats pretreated with chlordecone. Hepatology 13: 230-238.

34.

Ledda-Columbano GM , Columbano A. , Curto M. , Ennas MG , Coni P. , Sharma DSR , and Pani P. (1989). Further evidence that mitogen-induced cell proliferation does not support the formation of enzyme altered island in rat liver by carcinogenesis. Carcinogenesis 10: 847-850.

35.

Leevey CM , Hollister RM , Schmid R. , McDonald RA , and Davidson CS (1959). Liver regeneration in experimental CCl4 intoxication . Proc. Soc. Exp. Biol. Med. 102: 672-675.

36.

Lockard VG , Mehendale HM , and O'Neal RM (1983). Chlordecone-induced potentiation of carbon tetrachloride hepatotoxicity: A light and electron microscopic study. Exp. Mol. Pathol. 39: 230-245.

37.

Lockard VG , Mehendale HM , and O'Neal RM (1983). Chlordecone-induced potentiation of carbon tetrachloride hepatotoxicity: A morphometric and biochemical study. Exp. Mol. Pathol. 39: 246-256.

38.

McLean AEM and McLean EK (1966). The effect of diet and 1,1,1-trichloro-2,2-bis(p-chlorophenyl)-ethane (DDT) on microsomal hydroxylating enzymes and on sensitivity of rats to carbon tetrachloride poisoning . Biochem. J. 100: 564-571.

39.

Mead JE and Fausto N. (1989). Transforming growth factor-α may be a physiological regulator of liver regeneration by means of an autocrine mechanism. Proc. Natl. Acad. Sci. USA 86: 1558-1562.

40.

Mehendale HM (1984). Potentiation of halomethane hepatotoxicity: Chlordecone and carbon tetrachloride. Fund. Appl. Toxicol. 4: 295-308.

41.

Mehendale HM (1989). Amplification of hepatotoxicity and lethality of CCl4 and CHCl3 by chlordecone. Rev. Biochem. Toxicol. 10: 91-138.

42.

Mehendale HM (1989). Mechanism of the lethal interaction of chlordecone and CCl4 at nontoxic doses. Toxicol. Lett. 49: 215-241.

43.

Mehendale HM (1990). Potentiation of halomethane hepatotoxicity by chlordecone: A hypothesis for the mechanism. Med. Hypoth. 33: 289-299.

44.

Mehendale HM and Klingensmith JS (1988). In vivo metabolism of CCl4 by rats pretreated with chlordecone, mirex or phenobarbital . Toxicol. Appl. Pharmacol. 93: 247-256.

45.

Mitchell AD and Mirsalis JC (1984). Unscheduled DNA synthesis as an indicator of genotoxic exposure. In: Single Cell Mutation Monitoring System: Methodologies and Applications, AA Ansari and F De-Serres (eds). Plenum Press, New York, pp. 165-216.

46.

Nakata R. , Tsukamoto I. , Miyoshi M. , and Kojo S. (1985). Liver regeneration after CCl4 intoxication in the rat. Biochem. Pharmacol. 34: 586-588.

47.

Noguchi T. , Fong KL , Lai EK , Alexander SS , King MM , Olson L. , Poyer JL , and McCay PB (1982). Specificity of a phenobarbital-induced cytochrome P-450 for metabolism of carbon tetrachloride to the trichloromethyl radical . Biochem. Pharmacol. 31: 615-624.

48.

Petropoulos CJ , Andrews G. , Tamaoki T. , and Fausto N. (1983). a-Fetoprotein and albumin mRNA levels in liver regeneration and carcinogenesis . J. Biol. Chem. 258: 4901-4906.

49.

Reitman S. and Frankel S. (1957). A colorimetric method for the determination of serum glutamic oxaloacetic and glutamic pyruvic transaminases. Am. J. Clin. Pathol. 28: 56-63.

50.

Roberts E. , Ahluwalia MB , Lee G. , Chan C. , Sharma DSR , and Farber E. (1983). Resistance to hepatotoxins acquired by hepatocytes during liver regeneration. Cancer Res. 43: 28-34.

51.

Ruch RJ , Klaunig JE , and Pereira MA (1985). Selective resistance to cytotoxic agents in hepatocytes isolated from partially hepatectomized and neoplastic mouse liver. Cancer Lett. 26: 295-301.

52.

Sipes IG , El-Sisi AE , Sim WW , Mobley SA , and Earnest DL (1991). The reactive oxygen species in the progression of CCl4-induced liver injury. Adv. Exp. Med. Biol. 283: 489-497.

53.

Sipes IG , Krishna G. , and Gillette JR (1977). Bioactivation of carbon tetrachloride, chloroform, and bromotrichloromethane: Role of cytochrome P-450. Life Sci. 20: 1541-1548.

54.

Soni MG and Mehendale HM (1991). Protection from chlordecone-amplified carbon tetrachloride toxicity by cyanidanol: Biochemical studies. Toxicol. Appl. Pharmacol. 108: 46-57.

55.

Soni MG and Mehendale HM (1991). Protection from chlordecone-amplified carbon tetrachloride toxicity by cyanidanol: Regeneration studies. Toxicol. Appl. Pharmacol. 108: 58-66.

56.

Wiebel ER , Staubli W. , Guagi HR , and Hess FA (1969). Correlated morphometric and biochemical studies on the liver cell. J. Cell Biol. 42: 68-91.

57.

Wolf CR , Harrelson NG Jr , Nastainczyk WM , Philpot RM , Kalyanaraman B. , and Mason RP (1980). Metabolism of CCl4 in hepatic microsomes and reconstituted monooxygenase systems and its relationship to lipid peroxidation. Mol. Pharmacol. 18: 553-558.

Pivotal Role of Hepatocellular Regeneration in the Ultimate Hepatotoxicity of CCl 4 in Chlordecone-,Mirex-,or Phenobarbital-Pretreated Rats

Abstract

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