Activation and detoxication of promutagens by toadfish (Opsanus tau) hepatic postmitochondrial fractions in the Salmonella assay

Three groups of experiments were conducted to characterize the hepatic postmitochondrial fraction (S9) from the oyster toadfish (Opsanus tau) as an activation system for promutagens in the Salmonella assay and to provide an initial evaluation of the extent to which data from standard in vitro assays with mammalian activation systems are predictive of possible genotoxic effects in this marine fish. In the first group of experiments the effects of increasing the concentration of S9 from untreated and 3-methylcholanthrene (MC)- or Aroclor 1254 (AC)-pretreated toadfish and Sprague-Dawley rats on the mutagenicities of different concentrations of 2-aminoanthracene (2AA) and benzo[a]pyrene (BAP) were examined in Salmonella (TA98) plate assays. The maximum levels of 2AA mutagenicity attained by S9 from untreated (UI S9) toadfish and rats were comparable, but UI S9 from toadfish was moreeffective than UI S9 from rats in mediating BAP mutagenicity. MC pretreatment decreased maximum levels of 2AA mutagenicity and increased maximum levels of BAP mutagenicity mediated by S9 from both species. MC pretreatment also altered the pattern of dependence of 2AA mutagenicity on the concentration of S9 protein for S9 from both species. A similar alteration in the pattern of dependence of BAP mutagenicity on the concentration of S9 protein was also observed with S9 from MC-pretreated toadfish. Although AC pretreatment of rats effected changes in the mutagenicities of both test chemicals similar to those effected by MC pretreatment, AC pretreatment of toadfish effected little or no change in the mutagenicities of either test chemical. The changes in the pattern of dependence of 2AA and BAP mutagenicities on the concentration of S9 protein effected by MC pretreatment of toadfish were confirmed in a separate group of experiments. A third group of experiments was designed to examine the effects of α-naphthoflavone (ANF) on the mutagenicities of 2AA and BAP mediated by UI and MC S9 from toadfish. Although ANF did not affect the 2AA mutagenicity mediated by UI S9, a significant decrease in 2AA mutagenicity and a significant increase in BAP mutagenicity mediated by MC S9 and a significant decrease in BAP mutagenicity mediated by UI S9 were observed. These results indicate that 2AA and BAP are effectively activated by toadfish S9 and that, as in rats, these two test chemicals are activated and/or detoxicated by different cytochrome P-450-dependent pathways. These results also support the contention that cytochrome P-450-dependent detoxication pathways can be an important determinant of the mutagenic potency of some promutagens in vitro.     

Ligand binding and detoxication

In an organism the binding of a toxic chemical to a binding site can act as a detoxication mechanism when toxicity is a property of the unbound ligand. This qualitative statement has been evaluated in quantitative terms. To this end parameters have been defined for which numerical values are required, equations are derived and a procedure is outlined that allows assessment of when and to what extent binding is of value in detoxication. In the process two new quantities are introduced, i.e. the binding capacity and the binding activity, which make for easier handling and comparison of binding data. It is concluded that to be important in detoxication the numerical value of the binding activity must be greater than unity and the total ligand concentration should not exceed the binding capacity. These general conclusions can be further refined depending on the accuracy with which the values of the parameters involved are known. Due to its generality the results of the analysis are useful in all situations where it is desirable to know the magnitude of the free fraction of a bound chemical.     

Oxidative detoxication of thallium in the yeast mitochondria

When yeast cells are grown in thallium-containing broth, the thallium ion is oxidized in the mitochondria to Tl₂O₃. This oxide is subsequently discharged from the mitochondria and finally excreted from the protoplast.     

Genetic variability in the cytochrome P450-paraoxonase 1 (PON1) pathway for detoxication of organophosphorus compounds

Detoxication of organophosphorus (OP) compounds is affected by genetic and environmental modulation of a number of enzymes involved in the process. For organophosphorothioate insecticides, different P450 isozymes and variants carry out two reactions that have quite different consequences; (1) they bioactivate their parent compounds to highly toxic oxon forms that are many times more toxic than the parent compounds, and (2) concurrently, they dearylate the parent OP compounds, generating much less toxic metabolites. The ratios at which these different P450s carry out bioactivation versus dearylation differ among the P450 isozymes. The detoxication of the oxon forms of diazinon and chlorpyrifos is achieved by hydrolysis to the respective aromatic alcohols and diethyl phosphates primarily by paraoxonase 1 (PON1), a plasma enzyme tightly associated with high-density lipoprotein particles and also found in liver. Stoichiometric binding to other targets also contributes to the detoxication of these oxons. PON1 is polymorphically distributed in human populations with an amino acid substitution (Gln/Arg) at position 192 of this 354-amino acid protein (the initiator Met residue is cleaved on maturation) that determines the catalytic efficiency of hydrolysis of some substrates. In addition to the variable catalytic efficiency determined by the position 192 amino acid, protein levels of PON1 vary by as much as 15-fold among individuals with the same PON1(192) genotype (Q/Q; Q/R; R/R). The generation of PON1 null mice and transgenic mice, expressing each of the human PON1(192) alloforms in place of mouse PON1, has allowed for the examination of the physiological function of the PON1(192) alloforms in OP detoxication. Sensitivity to diazoxon exposure is primarily determined by the plasma level of PON1, whereas for chlorpyrifos oxon exposure, both the plasma PON1 level and the position 192 amino acid are important--PON1(R192) is more efficient in inactivating chlorpyrifos oxon than is PON1(Q192). The availability of PON1 null mice provides an opportunity to examine the contribution of other enzymes in the OP detoxication pathways without PON1 interference.     

Role of enhanced detoxication in a deltamethrin-resistant population of Triatoma infestans (Hemiptera, Reduviidae) from Argentina

Deltamethrin and other pyrethroids have been extensively used in Argentina since 1980, for the chemical control of Triatoma infestans Klug (Hemiptera: Reduviidae). Recently, resistance to deltamethrin was detected in field populations by the survival of bugs exposed by topical application to the diagnostic dose estimated on the CIPEIN susceptible strain. Results of the current study showed low resistant ratios (RRs) to deltamethrin for the resistant populations (RR ranged from 2.0 for San Luis colony to 7.9 for Salta colony). Biochemical studies were made on the most resistant colony (Salta) and the susceptible strain (CIPEIN), in order to establish the importance of degradative mechanisms as a cause of the detected resistance. Esterase activity was measured on 3 days old first instars through phenylthioacetate and a-naphtyl acetate activities. The results showed a significant difference in no cholinesterase esterase activity from susceptible (7.6 +/- 0,7 micro M S./i.min.) and Salta resistant colony (9.5 +/- 0.8 microM S./i.min.). Cytochrome p450 mono-oxygenase (p450) activity was measured on individual insects through ethoxycoumarine deethylase (ECOD) activity using a fluorescence microplate reader. The dependence of ECOD activity on age and body region of the nymphs, and pH and time of incubation were studied in order to optimize the measurement. As a result, comparative studies were performed on abdomens of 2 days old first instars at pH 7.2 and 4 h incubation time. ECOD activity of first nymphs was significantly lower in the susceptible colony (61.3 +/- 9.08 pg ECOD/ insect) than in the resistant one (108.1+/- 5.7 pg ECOD/ insect). These results suggest that degradative esterases (no-cholinesterase) and mono-oxygenases cytochrome p450, play an important role in the resistance to deltamethrin in Salta colony from Argentina.     

Enzyme systems of insecticide detoxication in the Colorado beetle

The activity of three enzymatic systems of xenobiotic metabolism (cytochrome P-450-dependent monooxygenases, non-specific esterases and glutathione S-transferases) was studied at different stages of development of the Colorado potato beetle (Leptinotarsa decemlineata). Significant sex and ontogenetic differences in the content of cytochrome P-450, position of maxima of CO-difference spectra of the cytochrome P-450 reduced form and substrate specificity of cytochrome P-450 were revealed. The activity of non-specific esterases was shown to increase depending on the age of larvae. The insecticide 1-naphtholenol methylcarbamate which is metabolized by the system of cytochrome P-450-dependent monooxygenases is more toxic in the larvae than at the imago stage, which is correlated with the activity of this system at different stages of ontogenesis. The microsomal monooxygenase inhibitor, piperonylbutoxide, increases the insecticide toxicity in the Colorado beetle imago more than 2-fold. The experimental results testify to different contribution of the detoxication systems to the sensitivity of the Colorado beetle to insecticides at various metamorphosis stages.