Mechanism of the lethal interaction of chlordecone and CCl4 at non-toxic doses

Mechanisms and biomarkers of liver regeneration after drug-induced liver injury

Liver, the major metabolic organ in the body, is known for its remarkable capacity to regenerate. Whereas partial hepatectomy (PHx) is a popular model for the study of liver regeneration, the liver also regenerates after acute injury, but less is known about the mechanisms that drive it. Recent studies have shown that liver regeneration is critical for survival in acute liver failure (ALF), which is usually due to drug-induced liver injury (DILI). It is sometimes assumed that the signaling pathways involved are similar to those that regulate regeneration after PHx, but there are likely to be critical differences. A better understanding of regeneration mechanisms after DILI and hepatotoxicity in general could lead to development of new therapies for ALF patients and new biomarkers to predict patient outcome. Here, we summarize what is known about the mechanisms of liver regeneration and repair after hepatotoxicity. We also review the literature in the emerging field of liver regeneration biomarkers.

DDT and Other Chlorinated Insecticides

The use of organochlorine insecticides such as DDT, lindane and cyclodieneshas declined markedly worldwide over the last decades. Most are now banned or not used. At an acute toxicity level they have been relatively safe in use for humans. However, the greatest concerns are their persistence in people, wildlife and the environment due to their slow metabolism. Although their carcinogenicity for humans has not been supported by strong epidemiological evidence, their potential to be modulators of endocrine and immune function at levels remaining in the environment or associated with residual spraying of DDT continue to be of concern. At present, DDT is still allowed by the United Nations for combating malaria, with continual monitoring and assessment where possible. The toxicological consequences of exposure of animals and people to DDT is discussed as well as some analogues and other insecticides such as lindane, dieldrin and chlordecone that, although little used, continue to persist in surroundings and people. Because of circumstances of world health brought about by climate change or human activities that have yet to develop, there may come a time when the importance of some may re-emerge.

Evaluating pharmacokinetic and pharmacodynamic interactions with computational models in supporting cumulative risk assessment

Simultaneous or sequential exposure to multiple chemicals may cause interactions in the pharmacokinetics (PK) and/or pharmacodynamics (PD) of the individual chemicals. Such interactions can cause modification of the internal or target dose/response of one chemical in the mixture by other chemical(s), resulting in a change in the toxicity from that predicted from the summation of the effects of the single chemicals using dose additivity. In such cases, conducting quantitative cumulative risk assessment for chemicals present as a mixture is difficult. The uncertainties that arise from PK interactions can be addressed by developing physiologically based pharmacokinetic (PBPK) models to describe the disposition of chemical mixtures. Further, PK models can be developed to describe mechanisms of action and tissue responses. In this article, PBPK/PD modeling efforts conducted to investigate chemical interactions at the PK and PD levels are reviewed to demonstrate the use of this predictive modeling framework in assessing health risks associated with exposures to complex chemical mixtures.

Urinary biomarkers trefoil factor 3 and albumin enable early detection of kidney tubular injury

The capacities of urinary trefoil factor 3 (TFF3) and urinary albumin to detect acute renal tubular injury have never been evaluated with sufficient statistical rigor to permit their use in regulated drug development instead of the current preclinical biomarkers serum creatinine (SCr) and blood urea nitrogen (BUN). Working with rats, we found that urinary TFF3 protein levels were markedly reduced, and urinary albumin were markedly increased in response to renal tubular injury. Urinary TFF3 levels did not respond to nonrenal toxicants, and urinary albumin faithfully reflected alterations in renal function. In situ hybridization localized TFF3 expression in tubules of the outer stripe of the outer medulla. Albumin outperformed either SCr or BUN for detecting kidney tubule injury and TFF3 augmented the potential of BUN and SCr to detect kidney damage. Use of urinary TFF3 and albumin will enable more sensitive and robust diagnosis of acute renal tubular injury than traditional biomarkers.

A comparison of the effects of three GM corn varieties on mammalian health

We present for the first time a comparative analysis of blood and organ system data from trials with rats fed three main commercialized genetically modified (GM) maize (NK 603, MON 810, MON 863), which are present in food and feed in the world. NK 603 has been modified to be tolerant to the broad spectrum herbicide Roundup and thus contains residues of this formulation. MON 810 and MON 863 are engineered to synthesize two different Bt toxins used as insecticides. Approximately 60 different biochemical parameters were classified per organ and measured in serum and urine after 5 and 14 weeks of feeding. GM maize-fed rats were compared first to their respective isogenic or parental non-GM equivalent control groups. This was followed by comparison to six reference groups, which had consumed various other non-GM maize varieties. We applied nonparametric methods, including multiple pairwise comparisons with a False Discovery Rate approach. Principal Component Analysis allowed the investigation of scattering of different factors (sex, weeks of feeding, diet, dose and group). Our analysis clearly reveals for the 3 GMOs new side effects linked with GM maize consumption, which were sex- and often dose-dependent. Effects were mostly associated with the kidney and liver, the dietary detoxifying organs, although different between the 3 GMOs. Other effects were also noticed in the heart, adrenal glands, spleen and haematopoietic system. We conclude that these data highlight signs of hepatorenal toxicity, possibly due to the new pesticides specific to each GM corn. In addition, unintended direct or indirect metabolic consequences of the genetic modification cannot be excluded.

Dose-dependent liver tissue repair in chloroform plus thioacetamide acute hepatotoxicity

The objective of this study was to test whether a binary mixture (BM) of chloroform (CHCl(3)) and thioacetamide (TA) causes a dose-dependent liver injury and an opposing tissue repair. Liver injury was assessed by plasma alanine aminotransferase (ALT) and histopathology. Tissue repair was measured by [(3)H-CH(3)]-thymidine ((3)H-T) incorporation into hepatonuclear DNA and PCNA over a time course of 0-72h. Male Sprague-Dawley (S-D) rats received six- and five-fold dose ranges of TA and CHCl(3), respectively. ALT levels and (3)H-T incorporation were in complete agreement with corresponding microscopic observations, and only ALT elevation and (3)H-T incorporation data are presented here. Liver injury observed after exposure to BM was no different than addition of injuries caused by individual compounds. Tissue repair was prompt and adequate, leading to recovery from injury and animal survival. Tissue repair is dose-dependent and plays central role in the hepatotoxic outcome.

Tissue injury and repair as parallel and opposing responses to CCl4 hepatotoxicity: a novel dose-response

Recent studies indicate that the rate and extent of tissue repair, elicited as an endogenous response to toxic insult, are critical determinants in the ultimate outcome of hepatic injury. Therefore, the objective of this study was to develop a dose-response relationship for CCl4 measuring liver injury and tissue repair as two simultaneous but opposing responses. Male Sprague-Dawley rats were injected with a 40-fold dose range of CCl4 (0.1-4 ml/kg i.p.) in corn oil vehicle. Liver injury was assessed by serum enzyme elevations and histopathology, and tissue repair was measured by [3H]thymidine incorporation into hepatonuclear DNA and proliferating cell nuclear antigen immunohistochemistry over a time course of 0 to 96 h. Stimulation of cell division, evident even after a subtoxic dose of CCl4, increased in a dose-dependent manner until a threshold (2 ml/kg) was reached. Doses above this threshold yielded no further increase in tissue repair. Instead, tissue repair response was significantly delayed and diminished. Injury was markedly accelerated above the threshold indicating an unrestrained progression of injury. Although 4 ml CCl4/kg consistently caused 80% lethality by 48 h, tissue repair response in the 20% surviving rats was increased by about 5-fold, aptly demonstrating the critical role of tissue repair in overcoming injury and enabling these animals to survive. This study suggests that, in addition to the extent of tissue repair, the time of onset of tissue repair also determines the extent of hepatic injury and inter-individual differences in the magnitude of tissue repair may contribute significantly to inter-individual differences in susceptibility to toxic chemicals. Thus, while dose-related and prompt stimulation of tissue regeneration leads to recovery, delayed and attenuated repair response, occurring at higher doses, leads to progression of injury and animal mortality. Such dose-response relationships may lead to a better understanding of the underlying cellular mechanisms of injury inflicted by chemical toxicants and aid in fine-tuning risk assessment.

Efficient tissue repair underlies the resiliency of postnatally developing rats to chlordecone + CCl4 hepatotoxicity

It is often assumed that at a younger age populations are at higher risk of toxic effects from exposure to toxic chemicals. Recent studies have demonstrated that neonate and postnatally developing rats are resilient to a wide variety of structurally and mechanistically dissimilar hepatotoxicants such as galactosamine, acetaminophen, allyl alcohol, and CCl4. Most interestingly, young rats survive exposure to the lethal combination of chlordecone (CD) + CCl4 known to cause 100% mortality in adult male and female rats. In a study where postnatally developing (20- and 45-day), and adult (60-day) male Sprague Dawley rats were used, administration of CCl4 (100 microliters/kg, i.p.) alone resulted in transient liver injury regardless of age as indicated by plasma alanine transaminase (ALT), sorbitol dehydrogenase (SDH) levels and histopathological lesions. In CD-pretreated rats, CCl4-induced toxicity progressed with time culminating in 25 and 100% mortality by 72 h after CCl4 in 45- and 60-day rats, respectively, in contrast to regression of CCl4-induced toxicity and 0% mortality in 20-day rats. [3H]Thymidine (3H-T) incorporation and proliferating cell nuclear antigen (PCNA) studies revealed an association between delayed and diminished DNA synthesis, unrestrained progression of liver injury, and animal death. Time-course studies revealed that the loss of resiliency in the two higher age groups might be due to inability to repair the injured liver rather than due to infliction of higher injury. Intervention of cell division in 45-day CD rats by colchicine (CLC, 1 mg/kg, i.p.) 30 h after CCl4 challenge increased mortality from 25 to 85%, confirming the importance of stimulated tissue repair in animal survival. In contrast, efficient and substantial DNA synthesis observed in 20-day rats allows them to limit further progression of liver injury, thereby leading to full recovery of this age group with 0% mortality. Examination of growth factors and proto-oncogene expression revealed a 3- and 3.5-fold increase in transforming growth factor-alpha (TGF-alpha) and H-ras mRNA expressions, respectively, coinciding with maximal hepatocyte DNA synthesis in 20-day normal diet (ND) rats, as opposed to only 2- and 2.5-fold increases observed in 60-day ND rats, respectively. Increased expression of c-fos (10-fold) in 20-day rats occurred 1 h after CCl4 compared to less than a 2-fold increase in 60-day rats. These findings suggest that prompt stimulation of tissue repair permits efficient recovery from injury during early postnatal development of rats.

A review of the role of tissue repair as an adaptive strategy: why low doses are often non-toxic and why high doses can be fatal

The role of tissue repair as an adaptive strategy by species is important to consider in both evolutionary and toxicological perspectives. This paper assesses the distinct and integrative roles of early phase regeneration (EPR) (i.e. arrested G2 hepatocytes chemically activated to proceed through mitosis) and secondary phase regeneration (SPR) (i.e. hepatocytes mobilized principally from G0/G1 to proceed through mitosis) in the repair of carbon tetrachloride (CCl4)-induced liver damage. The role of EPR as a triage system facilitating repair of minor toxic insults as well as providing an essential role in autoprotection as an initial step to augment and sustain SPR is proposed. The function of EPR is then compared with that of SPR in tissue recovery following more massive injury. The interrelationships of these two repair processes with EPR invoking and accelerated SPR following low-to-modest degrees of toxicant-induced hepatotoxicity as well as in auto- or hetero-protection supports the theory that the two responses are co-ordinated in time and functionality. The integration of these two repair processes as shown through experimental manipulation provides a new mechanistic framework to account for the previously reported profound (67-fold) potentiation of acute CCl4 hepatotoxicity by chlordecone (kepone) in adult male Sprague-Dawley rats as well as important interspecies variation in susceptibility to hepatotoxic agents in general and CCl4 in particular. On the basis of the distinct and integrative roles of EPR and SPR in liver responses to toxic injury, a generalized framework is presented that facilitates prediction of both toxic outcome, including shape of dose-response functions and interspecies variation to chemically induced liver damage.

Age-related differences in TGF-alpha and proto-oncogenes expression in rat liver after a low dose of carbon tetrachloride

The resiliency of rats during early post-natal development to CCl4 or to an interactive hepatotoxicity of chlordecone (CD) + CCl4 has been shown to be due to an efficient stimulation of tissue repair. The objective of the current study was to investigate if this is due to efficient expression of transforming growth factor-alpha (TGF-alpha) and proto-oncogenes. Postnatally developing (20 day old) and adult (60 day old) male Sprague-Dawley rats were challenged with a single low dose of CCl4 (100 microL/kg, ip) or corn oil. Liver samples were collected during a time course (0-96 h) after the administration of CCl4 and used to examine TGF-alpha and early (c-fos) and late (H-ras and K-ras) proto-oncogenes mRNA expressions. Significant increases in TGF-alpha, H-ras, and K-ras gene expressions were evident as early as 12 hours after CCl4 and peaked between 24 and 48 hours in an age-dependent manner as detected by slot-blot analysis. Results of the study revealed three- and twofold increases in TGF-alpha gene expression in 20 and 60 day old rats, respectively, after CCl4. There were 3.5- and 2.5-fold increases in H-ras and 4.4- and 3.4-fold increases in K-ras in 20 and 60 day old rats, respectively. In contrast, a 10-fold increase in c-fos mRNA expression was evident in 20 day old rats 1 hour after CCl4 treatment, returning to the baseline value by 3 hours, whereas in 60 day old rats, this increase was less than twofold. The overall findings of this study indicate that TGF-alpha and the early and late proto-oncogene mRNA expressions were enhanced in an age- and time-dependent manner in response to a low dose of CCl4. These results further strengthen the view that the remarkable resiliency of rats to hepatotoxicants during early postnatal development is due to substantial increases in stimulation of hepatocellular regeneration and tissue repair mechanisms, leading to regression of liver injury and recovery.

Modulation of phorbol ester-induced HL-60 differentiation by prostaglandin E2

When treated with phorbol tumor promoters, HL-60 cells undergo terminal differentiation evidenced by a transition from a non-phagocytic suspension culture to an attached fibroblast-like culture with high phagocytic activity. Internalization of fluorescent particles by cells exhibiting the phagocytic positive phenotype (phag+) provides a sensitive indication of promoter-induced differentiation, and the resulting fluorescent cells can be quantitatively analyzed by flow cytometry. The current study was initiated to further test the predictive power of a flow cytometry based HL-60 differentiation assay in the detection of agents associated with tumor promotion. Specifically, experiments were designed to assess the sensitivity of the test system to co-promoters which enhance promoter activity in vivo. Prostaglandin E2 (PGE2) was chosen as a model co-promoter since it has been shown to potentiate phorbol ester (i.e. 12-O-tetradecanoyl phorbol-13-acetate; TPA) induced biological effects in vivo. Results detailed in the current report indicate that PGE2 enhances TPA-induced differentiation of HL-60 cells in a dose-dependent manner. As with in vivo co-promotion experiments, PGE2 exhibited a maximum potentiating effect when administered prior to TPA. These data indicate that HL-60 cells are not only sensitive to phorbol promoters, but also to the co-promoter PGE2. These experiments support the hypothesis that a flow cytometry based HL-60 assay may prove useful for studying chemical agents or intrinsic cellular factors that are involved in the tumor promotion phase of carcinogenesis.

Safety evaluation of the mixture of chemicals at a specific workplace: theoretical considerations and a suggested two-step procedure

Procedures for the selection of compounds with high health hazard potential are reviewed, and major aspects of the assessment of health risks associated with exposure to mixtures of chemicals are discussed. Examples are given of additivity and synergism of effects following exposure to mixtures. Using these data from the literature a two-step procedure for the safety evaluation of the mixture of chemicals occurring at a specific workplace is suggested. The first step consists of estimating the relative health risk associated with each chemical; the estimation is based on the ratio between exposure level and degree of toxicity. Those chemicals representing a high risk are then selected for further consideration. The second step comprises the risk assessment, focusing on prediction of the risk associated with exposure to the mixture of selected chemicals. To allow such prediction the (presumable) mode of action of the selected compounds should be considered. A practical way to find out whether exposure to chemicals at a specific workplace is of serious health concern, could be the conduct of both a 4-week toxicity study in rats and 2 different types of genotoxicity studies with the mixture of selected chemicals, using exposure concentrations related to those occurring in practice.

Toxic interactions among environmental pollutants: corroborating laboratory observations with human experience

Combined exposures to multiple chemicals may result in interactions leading to a significant increase or decrease in the overall toxicity of the mixture compared to the summation of the toxicity of the components. A large number of chemical interactions have been described in animal studies by administering high doses of chemicals by routes and scenarios often different from anticipated human exposures. Though limited, there is some evidence for the occurrence of several supra-additive (the combined effects are greater than the simple summation of the individual effects) and infra-additive (the combined effects are smaller than the simple summation of the individual effects) chemical interactions in humans. For example, toxicokinetic interactions between several solvents have been found to occur in the workplace, whereas those involving pesticides have been reported less frequently, especially during accidental exposures. Toxic interactions involving nutritionally important metals and metalloids appear to occur more frequently, since several of them have an important role in a variety of physiological and biochemical processes. On the contrary, there is not much evidence to confirm the occurrence of toxic interactions among the commonly encountered inorganic gaseous pollutants in humans. Overall, the majority of chemical interactions observed in animal studies have neither been investigated in humans nor been extrapolated to humans based on appropriate mechanistic considerations. Future research efforts in the chemical interactions arena should address these issues by focusing on the development of mechanistically and biologically based models that allow predictions of the extent of interactions likely to be observed in humans.

Amplified interactive toxicity of chemicals at nontoxic levels: mechanistic considerations and implications to public health

It is widely recognized that exposure to combinations or mixtures of chemicals may result in highly exaggerated toxicity even though the individual chemicals might not be toxic. Assessment of risk from exposure to combinations of chemicals requires the knowledge of the underlying mechanism(s). Dietary exposure to a nontoxic dose of chlordecone (CD; 10 ppm, 15 days) results in a 67-fold increase in lethality of an ordinarily inconsequential dose of CCl4 (100 microliters/kg, ip). Toxicity of closely related CHCl3 and BrCCl3 is also enhanced. Phenobarbital (PB, 225 ppm, 15 days) and mirex (10 ppm, 15 days) do not share the propensity of CD in this regard. Exposure to PB + CCl4 results in enhanced liver injury similar to that observed with CD, but the animals recover and survive in contrast to the greatly amplified lethality of CD + CCl4. Investigations have revealed that neither enhanced bioactivation of CCl4 nor increased lipid peroxidation offers a satisfactory explanation of these findings. Additional studies indicate that exposure to a low dose of CCl4 (100 microliters/kg, ip) results in limited injury, which is accompanied by a biphasic response of hepatocellular regeneration (6 and 36 hr) and tissue repair, which enables the animals to recover from injury. Exposure to CD + CCl4 results in suppressed tissue repair owing to an energy deficit in hepatocytes as a consequence of excessive intracellular influx of Ca2+ leading initially to a precipitous decline in glycogen and ultimately to hypoglycemia. Supplementation of cellular energy results in restoration of the tissue repair and complete recovery from the toxicity of CD + CCl4 combination. In contrast, only the early-phase hepatic tissue repair (6 hr) is affected in PB + CCl4 treatment, but this is adequately compensated for by a greater stimulation of tissue repair at 24 and 48 hr resulting in recovery from liver injury and animal survival. A wide variety of additional experimental evidence confirms the central role of stimulated tissue repair as a decisive determinant of the final outcome of liver injury inflicted by CCl4. For instance, a 35-fold greater CCl4 sensitivity of gerbils compared to rats is correlated with the very sluggish tissue repair in gerbils. These findings are consistent with a two-stage model of toxicity, where tissue injury is inflicted by the well described "mechanisms of toxicity," but the outcome of this injury is determined by whether or not sustainable tissue repair response accompanies this injury.(ABSTRACT TRUNCATED AT 400 WORDS)

Adenosine triphosphate protection of chlordecone-amplified CCl4 hepatotoxicity and lethality

Dietary exposure to a nontoxic level of chlordecone (10 ppm for 15 days) followed by a single exposure to a subtoxic dose of CCl4 (100 microliters/kg, ip) is known to result in a 67-fold amplification of CCl4 toxicity. The hypothesis that the underlying mechanism is due to incapacitation of hepatocytes leading to an ablation of the early-phase hormetic response of tissue repair as a consequence of precipitous decline in hepatic glycogen and ATP, received experimental support from Mehendale in 1990. The present study was designed to investigate if direct administration of ATP to rats maintained on the chlordecone diet would result in protection from the hepatotoxic and lethal effects of the chlordecone+CCl4 combination. Male Sprague-Dawley rats (125-150 g) were maintained either on a diet containing no added contaminants (control) or on a diet containing 10 ppm chlordecone for 15 days, and were challenged with CCl4 (100 microliters/kg, ip) on day 16. Without ATP administration all rats died within 72 h, while administration of ATP (100 mg/rat, sc) to chlordecone-pretreated rats at -1, +1, 3, 5, 12, 24 and 36 h of CCl4 injection resulted in 100% survival. Injection of ATP, at -1, +1, 3 and 5 h of CCl4 administration to chlordecone pretreated rats decreased plasma enzyme elevations (alanine and aspartate aminotransferase, sorbitol dehydrogenase) as well as substantially preventing elevation of plasma bilirubin levels at 6, 12 and 24 h. Hepatic ATP levels were also elevated at 6 and 12 h, but not at 24 h.(ABSTRACT TRUNCATED AT 250 WORDS)

Subacute (4-wk) oral toxicity of a combination of four nephrotoxins in rats: comparison with the toxicity of the individual compounds

In a 4-wk study, 10-wk-old Wistar rats were fed the nephrotoxins hexachloro-1,3-butadiene (HCBD), mercuric chloride, d-limonene and lysinoalanine either alone or in combination. These nephrotoxins damage epithelial cells of the proximal tubules, but by different mechanisms. Each chemical was given alone at a Minimum-Nephrotoxic-Effect Level (MNEL), and at a No-Nephrotoxic-Effect Level (NNEL). The combination was given at the MNEL, the NNEL and one-quarter of the NNEL of the individual chemicals. The individual nephrotoxins caused slight growth depression in males at the MNEL, but not at the NNEL, whereas the combination depressed growth slightly at the NNEL and severely at the MNEL. In females at the MNEL, only HCBD retarded growth; in contrast to the effect in males this was not aggravated by combined treatment. Nephrotoxicity was more severe in males fed the combination than in males given the nephrotoxins alone. The former showed decreased renal concentrating ability and moderate histopathological changes in the kidneys at the MNEL, and a dose-dependent increase in kidney weight and number of epithelial cells in the urine at the NNEL and the MNEL. The males treated with a single agent showed slightly increased kidney weights, and/or slight histopathological changes in the kidneys at the MNEL, and (with d-limonene only) epithelial cells in the urine at the NNEL and MNEL. In females, renal changes induced by the combination were not more severe than those observed with individual compounds. No adverse changes attributable to treatment were observed in rats fed the combination at one-quarter of the NNEL. In the present study, combined exposure to four nephrotoxins at their individual NNEL did not constitute an obviously increased hazard, indicating absence of synergistic interaction, whereas at the MNEL clearly enhanced (renal) toxicity occurred in males, although not in females.

Ongoing hepatocellular regeneration and resiliency toward galactosamine hepatotoxicity

In previous studies, we reported that the age-dependent hepatotoxicity of galactosamine (GalN) was evident in hepatocytes maintained in primary cultures. Cellular proliferation and tissue repair are not manifested in response to injury in this in vitro system. Neonatal (5-day) rats have ongoing hepatocellular proliferation in contrast to adult (5-month) rats, and should be therefore resilient to GalN toxicity. Liver injury was assessed by serum transaminases (ALT, AST), 3H-thymidine (3H-T) incorporation into nuclear DNA, and content of hepatocellular nuclear DNA. While the dose of 400 mg/kg did not cause any significant liver injury in the neonates, it did produce significant liver injury in adult rats. At a dose of 800 mg/kg, GalN produced significant injury in the neonates. Because 400 mg/kg causes clearly demonstrable liver injury in the adult and no injury in the neonates, this dose was used for further studies. In addition to the above measures of injury, uracil nucleotides (UTP, UDP, and UMP), glycogen, histopathology, and autoradiographic examination of liver sections were used to assess the liver injury in neonatal and adult rats. In a time-course study, all of the above were measured at 0, 12, 24, 36, 48 and 72 h after GalN administration. Serum enzyme elevations as well as the appearance of necrotic and swollen hepatocytes were maximal at 24 h in the adults rats. In contrast to these observations in the adult rats, none of these measurements indicated significant liver injury in the neonates. 3H-T incorporation into nuclear DNA was much higher in the neonatal liver in comparison to the adults reflecting the difference in regeneration. Hepatocellular nuclear DNA was also higher in the neonate and was significantly decreased due to GalN treatment. In the adult rats, the quiescent normal level of 3H-T incorporation and nuclear DNA content were further decreased at 12 h, increased at 48 h and returned to normal low, quiescent levels at 72 h. In the neonates mitotic activity of hepatocytes was higher than in the adult rats. In the adult rats, mitotic activity was increased at 48 h after GalN administration and returned to normal at 72 h. In the neonates GalN did not alter the mitotic activity significantly. These findings demonstrate that in the presence of hepatocellular regeneration, galactosamine toxicity is minimal while in the absence of it, clear toxicity is manifested. In conclusion, while perturbation in uracil nucleotides and related biochemical events may explain the infliction of liver injury by GalN in an age-dependent fashion, the extent of tissue repair impacts decisively on the final outcome of injury.

Pivotal role of hepatocellular regeneration in the ultimate hepatotoxicity of CCl4 in chlordecone-, mirex-, or phenobarbital-pretreated rats

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 microliters/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.(ABSTRACT TRUNCATED AT 400 WORDS)

Selecting exposure parameters in developmental neurotoxicity assessments

Numerous factors must be considered in selecting exposure parameters for developmental neurotoxicity investigations. Whether employing a single dose during pregnancy, or continuous exposure from prepregnancy through early postnatal developmental periods, the following primary factors should be addressed: 1) Purpose of the study; 2) pharmacokinetics/pharmacodynamics; 3) biotransformation; 4) genotypic variables; 5) limiting factors, including the availability of test compounds for evaluation; and, 6) several general, miscellaneous factors. Whether a single, large dose of an exogenous agent is more toxic to the developing nervous system than a series of smaller doses depends upon the interaction of the physicochemical, pharmacokinetic, and pharmacodynamic properties of the agent with the genotypic features of the test organism.

Potentiation of BrCCl3 hepatotoxicity by chlordecone: biochemical and ultrastructural study

Previous work has established that chlordecone (CD) potentiates the hepatotoxicity of BrCCl3. This interaction occurs at nontoxic levels of CD and BrCCl3. The present research was designed to investigate the mechanism governing the pathogenesis of potentiated hepatic injury and lethality induced by a low dose of BrCCl3 after dietary pretreatment with 10 ppm of CD for 15 days. On Day 16, a single dose of BrCCl3 (30 microliters/kg) was administered ip to rats maintained either on normal diet (ND) or on a diet contaminated with 10 ppm CD. Blood and liver samples were collected at 0, 3, 6, 12, 24, 36, and 48 hr after the halomethane administration for biochemical (ATP, bilirubin, glycogen) and for ultrastructural studies. A continuous increase in serum bilirubin and decrease in hepatic ATP and glycogen were observed in CD + BrCCl3 combination, indicating progressive injury, but not in other treatment groups. In ND + BrCCl3 combination, all biochemical indices were either normal or close to normal after 36 hr, suggesting complete recovery from hepatotoxicity. The most extensive ultrastructural changes characteristic of halomethane hepatotoxicity (necrosis, ballooned cells, and dilation of rough endoplasmic reticulum) were observed after the CD + BrCCl3 combination treatment. The progressive and early depletion of hepatic ATP and glycogen, and the progressive increase in toxicity along with decreased cell division in CD + BrCCl3-treated rats, indicate the association of compromised energy status and suppression of cell division and tissue repair in CD-potentiated BrCCl3 toxicity. These findings suggest that the suppression of stimulated hepatocellular regeneration results in the loss of the essential mechanism of tissue repair leading to continuation of the toxic liver injury associated with the CD + BrCCl3 combination treatment.

Hepatotoxicity and lethality of halomethanes in Mongolian gerbils pretreated with chlordecone, phenobarbital or mirex

The hepatotoxic and lethal effects of CBrCl3, CCl4 and CHCl3 were investigated in gerbils with or without prior exposure to dietary chlordecone (CD), phenobarbital (PB) and mirex (MX) at 10, 225 and 10 ppm, respectively, for 15 days. Gerbils were quite sensitive to these halomethanes (48 h LD50: 20, 80 and 400 microliters/kg, respectively). CD, known to potentiate hepatotoxic and lethal effects of halomethanes in rats, failed to potentiate the toxic effects of any of these three halomethanes in gerbils. PB and MX were also ineffective. Since stimulation of early hepatocellular regeneration has been shown to be responsible for the recovery from the toxicity of a low dose of CCl4, liver cell regeneration and tissue repair were studied in gerbils after CCl4 administration. The objectives of these studies were to investigate the possible reasons for the high sensitivity of gerbils to halomethane toxicity and to investigate the mechanism for their refractoriness to CD-potentiated halomethane toxicity. A low and a high dose of CCl4 (15 and 80 microliters/kg, i.p. respectively) were used to study the time-course of liver injury in gerbils pretreated with or without CD. The low dose of CCl4 stimulated cellular regeneration as indicated by the increase of 3H-thymidine (3H-T) incorporation in hepatic nuclear DNA. The cellular regeneration and tissue repair activities resulted in complete recovery from the limited liver injury in both CD-pretreated and control gerbils. In contrast to rats, however, the process of cell division in gerbils occurred much later, 2 days after CCl4 administration. Evidence from histomorphometric studies was consistent with serum enzyme and 3H-T incorporation data.(ABSTRACT TRUNCATED AT 250 WORDS)

Protection from chlordecone-amplified carbon tetrachloride toxicity by cyanidanol: biochemical and histological studies

Chlordecone (CD) pretreatment is well known to greatly potentiate CCl4 toxicity. Previous work has shown that suppression of hepatocellular regeneration permits an ordinarily limited liver injury to progress in an irreversible manner. Insufficient hepatocellular energy has been proposed as a mechanism for suppressed hepatocellular regeneration. Since cyanidanol reportedly increases cellular ATP, this compound was employed to test the above hypothesis. The present study was designed to investigate the sequential biochemical and histological changes over a time course of 120 hr after CCl4 administration. Male Sprague-Dawley rats (125-150 g) were maintained on 10 ppm CD diet for 15 days and were challenged with either a standard protocol dose (100 microliters/kg) or a low (50 microliters/kg, L) dose of CCl4. Cyanidanol pretreatment at 48, 24, and 2 hr before CCl4 administration to rats maintained on CD diet resulted in 100 or 70% animal survival, for CCl4 (L) or the standard dose of CCl4, respectively. Preliminary studies indicated that neither simultaneous nor subsequent administration of cyanidanol with CCl4 challenge affords such protection. Prior treatment with cyanidanol and a latency period were found necessary for protection. Without cyanidanol, CD + CCl4 combination caused 50 and 100% lethality after CCl4 (L) and the standard dose, respectively, while the same doses of CCl4 alone did not cause lethal effects. Plasma enzymes (alanine aminotransferase, aspartate aminotransferase, sorbitol dehydrogenase) in control rats showed only moderate and transient increases after CCl4 challenge. The combination of CD + standard dose of CCl4 resulted in progressive and marked elevations of all three serum enzymes at all time intervals until the death of animals. Cyanidanol pretreatment resulted in significant decline in the plasma enzyme elevations at later time points. Cyanidanol pretreatment increased hepatic ATP synthesis in control or CD rats. CCl4 administration to control rats did not alter hepatic ATP levels, while in CD-fed rats hepatic ATP levels were significantly decreased. Cyanidanol pretreatment to CD + CCl4 combination-treated rats did not significantly prevent the decline in hepatic ATP and glycogen levels. However, in the surviving rats a recovery in these parameters was observed. Light microscopic examination of livers from animals that received CCl4 alone revealed only marginal cellular injury, at early time points only. However, CCl4 challenge to rats maintained on CD resulted in progressive injury, characterized by the appearance of ballooned cells, necrotic cells, and cells with lipid droplets in the liver. Cyanidanol pretreatment to these rats caused decreased vacuolation and significantly reduced the progression of liver necrosis.(ABSTRACT TRUNCATED AT 400 WORDS)

Protection from chlordecone-amplified carbon tetrachloride toxicity by cyanidanol: regeneration studies

Previous work has shown that chlordecone (CD)-amplified CCl4 hepatotoxicity and lethality can be mitigated by pretreatment with cyanidanol. These studies also revealed that stimulated hepatocellular regeneration might play an important role in the cyanidanol protection of CD-amplified CCl4 toxicity. The present studies conducted over a time course of 0 to 120 hr after CCl4 challenge describe sequential changes in hepatic [3H]thymidine incorporation into hepatocellular nuclear DNA, polyamines and related enzymes, and histomorphometry of liver sections from variously treated rats. Male Sprague-Dawley rats (125-150 g) were maintained on a control diet or on a diet contaminated with CD (10 ppm) for 15 days and/or pretreated with cyanidanol (250 mg/kg, ip) at 48, 24, and 2 hr before a single ip injection of either a standard protocol dose (100 microliters/kg) or a low dose (50 microliters/kg, L) of CCl4 on Day 16 of the dietary protocol. Cyanidanol pretreatment significantly stimulated the hepatic [3H]thymidine incorporation into hepatocellular nuclear DNA of control rats irrespective of CD pretreatment. Similarly, polyamine metabolism was altered favorably for cell division, although mitotic index (metaphase) was not increased. Cyanidanol-stimulated [3H]thymidine incorporation was highly suppressed in rats receiving the CD + CCl4 standard dose combination treatment up to 36 hr, but after this time point a marked increase was observed. Hepatocellular regeneration, quantified histomorphometrically as volume density of cells in metaphase, was progressively increased in rats protected from CD + CCl4 interaction by cyanidanol, starting at 36 hr and lasting until 72 hr. Favorably altered polyamine metabolism was evident from the stimulated ornithine decarboxylase, as well as from the stimulated interconversion of the higher polyamines to maintain increased concentration of putrescine. Challenge by the same dose of CCl4 (100 microliters/kg) to CD-pretreated rats not protected by cyanidanol failed to cause any increase in [3H]thymidine incorporation up to 36 hr and resulted in animal death starting at 36 hr. In the surviving rats, [3H]thymidine incorporation at 48 hr was increased, but was less than 50% of the increase observed in the cyanidanol group. In these rats, attenuation in the stimulation of cell division and insufficiently increased putrescine levels were observed, which are consistent with the inadequate level of hepatocellular regeneration. With rats receiving CD + CCl4(L) combination, the [3H]thymidine incorporation at 48 hr was less than 50% of the increase of cyanidanol-protected rats. Cyanidanol pretreatment to the CD + CCl4 group of rats prevented the decrease in the hepatic DNA levels.(ABSTRACT TRUNCATED AT 400 WORDS)

Potentiation of halomethane hepatotoxicity by chlordecone: a hypothesis for the mechanism

A major toxicological issue today is the possibility of unusual toxicity due to interaction of toxic chemicals upon environmental or occupational exposures to two or more chemicals, at ordinarily harmless levels individually. While some laboratory models exist for such interactions for the simplest case of only two chemicals, progress in this area has suffered for want of a model where the two interactants are individually nontoxic. One such model is available, where prior exposure to nontoxic levels of the pesticide Kepone (chlordecone) results in a 67-fold amplication of CCl4 lethality in rats. Extensive hepatotoxicity observed in this interaction is characterized by histopathological alterations, perturbation of related biochemical parameters and is followed by complete hepatic failure. This propensity for chlordecone to potentiate hepatotoxicity of halomethanes such as CCl4, CHCl3, and BrCCl3 has been a subject of intense study to unravel the underlying mechanism. Mechanisms such as induction of microsomal cytochrome P-450 by chlordecone and greater lipid peroxidation are inadequate to explain the remarkably powerful potentiation of halomethane toxicity. Compelling experimental evidence supports the hypothesis that hepatocellular division during early time points after the administration of CCl4 is an important determinant of the progression (or repair of it) of the liver injury and consequent destruction (or restoration) of the hepatolobular architecture and function. This paper advances a hypothesis for the mechanism of hepatotoxic and lethal effect of CCl4 as being primarily related to the accelerated progression of liver injury due to suppressed hepatocellular regeneration and hepatolobular restoration. This is in contrast to the widely accepted putative mechanism, one which invokes only bioactivation followed by runaway lipid peroxidation as the events determining the course of the progressive phase of liver injury. The concept being advanced in this paper accepts bioactivation (and perhaps lipid peroxidation) as the primary initiating events of cell injury, but maintains that they are not the determinants of the progressive phase of liver injury. The biological issue of whether the cells are incapacitated from regenerating is the determinant of the progression of liver injury, and therefore, the ultimate outcome of hepatotoxicity and lethality.