Cytochrome P-450 content and aldrin epoxidation to dieldrin in isolated rat hepatocytes

A rat hepatocyte suspension effectively epoxidized aldrin to dieldrin with a V_max of 7.19 mol/mol P-450/min and a K_m of 9.27 μM. Viability and metabolic activity were stable for 6 hr after isolation when cells were maintained at room temperature (20°C) with the gentle introduction of $\text{O}{}_2\text{CO}{}_2$ onto the surface of the suspension. The cytochrome P-450 content of the suspension was 303 pmol/10⁶ cells. Primary maintenance culture of the cells also epoxidized aldrin. During culture for 3 days, metabolic activity decreased slowly day by day. Metabolic activity of microsomal fraction from rat liver was also examined. Microsomes epoxidized aldrin with a V_max of 5.11 mol/mol P-450/min and a K_m of 1.64 μM. Significant loss of some subspecies of cytochrome P-450 during fractionation of liver homogenate was indicated.     

Hepatic disposition of parathion: Uptake by isolated hepatocytes and chromatographic translobular migration

Isolated rat hepatocytes suspended in Waymouth's medium absorbed parathion rapidly and reversibly until the intracellular parathion concentration reached more than 300 times the ambient concentration. The distribution quotient q, defined as the ratio of intra- and extracellular concentrations at equilibrium, decreased when horse serum was added to the medium. The high hepatocyte affinity and rapid uptake of parathion suggested that this compound might be almost completely absorbed by periportal hepatocytes in the perfused liver and migrate downstream chromatographically through the lobule. Parathion infusion experiments verified this prediction and showed that the migration rate is dependent on the q value. The chromatographic feature may be useful as a basis for nonhistological investigation of intralobular hepatocyte heterogeneity. The lobule may function as a reverse-phase chromatograph also for many other unionized xenobiotics. Implications of the findings in the hepatic disposition of xenobiotics in vivo are discussed.     

The effects of DDT and dieldrin on rat peritoneal macrophages

The effects of DDT and dieldrin on cell population, viability, and phagocytic activity on the rat peritoneal macrophages were studied. It was observed that both pesticides, at low levels of concentration, exhibited a marked effect on this cell type. At the lowest concentrations tested both pesticides produced an increase in the macrophage population which appeared to be the result of a foreign-body response. At higher concentrations of pesticide this foreign-body response appears to be inhibited. The phagocytic activity of the cells steadily decreased as the concentration of the pesticide administered increased, and a decrease in cell viability with increased pesticide exposure was also noted.     

The mechanism of resistance to lindane and hexadeuterated lindane in the Third Yumenoshima strain of house fly

The factors which cause lindane resistance in the Third Yumenoshima strain, a strain of house flies highly resistant to insecticides, were studied using hexadeuterated lindane. Hexadeuterated lindane has the same physicochemical properties as lindane, but the former is much less biodegradable than the latter. The LD₅₀ ratio of lindane to hexadeuterated lindane in this strain, deuterium isotope effect on LD₅₀ values, was larger than that in S_NAIDM, a susceptible (nonresistant) strain. The penetration rates of labeled and nonlabeled lindane through the insect cuticle were about the same for both strains. Thus, penetration rate does not cause resistance. The metabolic degradation of lindane in the resistant strain in vivo occurred much faster than in the susceptible strain. This was also the case for lindane degradation processes in vitro such as microsomal oxidation and glutathione conjugation. In both strains, significant isotope effects were observed in the degradation rates in vitro of labeled and nonlabeled lindane. Therefore, principal biodegradation and detoxication pathways should include reactions which cleave the CH bonds. When the much less biodegradable d₆ counterpart of lindane was applied to both strains, the susceptible strain became much more highly intoxicated than the other within 20 to 30 min. This indicates that a combination of both greater degradability and probably lower sensitivity at the action site are the main factors underlying resistance in the Third Yumenoshima strain.     

Paraoxon-induced release of β-glucuronidase from rat hepatocytes in vitro

A suspension culture of isolated rat hepatocytes was used to reproduce in vitro the paraoxon-induced release of hepatic β-glucuronidase observed in vivo. After a short latent period, exposure of hepatocytes to paraoxon at 10^?7 to 10^?4M resulted in a typical dose-dependent response, with highest release occurring at 10^?4M paraoxon. With 10^?3M paraoxon, however, response was anomalous with a much-decreased enzyme release. As expected from earlier results in vivo, SV₁-oxon exhibited less effect than paraoxon.     

Differential inhibition responses caused by DDT on oligomycin-sensitive Mg2+-ATPase activity: Nature of the requirements for DDT sensitivity

Earlier communications from this laboratory have shown that DDT inhibited oligomycin-sensitive Mg²⁺-ATPase (EC 3.6.1.3) but that its active component, F₁, was not affected. In the present investigation evidence has been obtained to determine the nature of the requirements for DDT sensitivity. The results showed that DDT sensitivity was conferred to F₁ from pig heart mitochondrial preparations when it was bound to F₀ from the same preparation. The F₁ from house fly (Musca domestica L) thorax was able to bind to F₀ from pig heart. This combination showed similar sensitivity to that of the original F₁-F₀ combination from pig heart mitochondria. However, when F₁ from pig heart mitochondria was incorporated into F₀ depleted in oligomycin sensitivity-conferring protein (OSCP) from the same source, the resulting ATPase activity was insensitive to DDT. Addition of crude (50–200 μg) or purified (5–20 μg) OSCP in the above preparation restored DDT sensitivity. Presence of dioleyl or dipalmitoyl phosphatidyl choline or Triton X-100 in the reaction medium antagonized the DDT inhibitions. Depletion of phospholipids from submitochondrial membrane preparations (SMP) decreased ATPase activity. Addition of dioleyl or soybean phosphatidyl choline to this lipid-depleted preparation restored DDT sensitivity. Evidence presented suggests that DDT acted on F₁ in association with one or more membrane components and that OSCP and phospholipid were essential for DDT sensitivity.     

Influence of pyrethroid ester,oxime ether,and other central linkages on insecticidal activity,hydrolytic detoxification,and physicochemical parameters

The relative potency to target and nontarget insects of ester pyrethroids and the analogous oxime ethers, and the degree of synergism of the esters with tributyl phosphorotrithioate, provide a useful guide to the importance of esterase detoxification in species specificity. These criteria indicate that esterase detoxification is a more important component of pyrethroid tolerance in Chrysopa carnea and Cryptolaemus montrouzieri larvae than in Exochomus flavipis larvae and Musca domestica adults. Studies with 3-phenoxybenzyl 2-(4-chlorophenyl)-2-cyclopropylacetate and the corresponding 2,3,4,5,6-pentafluorobenzyl ester, their oxime ether analogs, and permethrin and its thiol ester and amide analogs provide evidence that the high insecticidal activity of some ester and E-oxime ether pyrethroids, relative to that of the corresponding thiol ester and amide, is more closely associated with the dipole moment and polarizability of the central linkage and its resistance to esterase detoxification than with bond lengths or lipophilicities conferred by a specific linkage. Pentafluorobenzyl tetramethylcyclopropanecarboxylate is very effective in the vapor state for house fly control.     

Antagonism of chlorobenzene-induced hepatotoxicity by lindane

In two complete replicates of a 2 × 2-fractorial-designed experiment involving chlorobenzene and γ-hexachlorocyclohexane (lindane), the hepatotoxicity induced by a challenge dose of chlorobenzene was altered by the pretreatments due to selective changes in various metabolis pathways. Pretreatment with either toxicant, alone or in combination, elevated the relative metabolism of 1.12 g chlorobenzene/kg to conjugated and polar metabolites. The relative importance of these pathways was increased most by pretreatment with chlorobenzene + lindane and least with chlorobenzene. The incidence and severity of chlorobenzene-induced hepatocellular necrosis was dependent on how much the pretreatments increased excretion of these metabolites relative to that of p-chlorophenol, since the conjugates and polar metabolites represent an inactivation of the toxic chlorobenzene-3,4-epoxide whereas p-chlorophenol reflects its formation. Thus these changes in the metabolic pathways resulted in either (i) a marginally significant decrease in hepatotoxicity (chlorobenzene pretreatment); (ii) significant reduction in both the incidence and severity of the lesions (lindane pretreatment); or (iii) absence of centrilobular hepatocellular necrosis in all but 1 of 12 rats where a minimal degree of necrosis was present (chlorobenzene + lindane pretreatment). In this study, the effect of pretreatment with xenobiotics on chlorobenzene-induced hepatotoxicity was dependent on how much the pretreatments altered the inactivation of chlorobenzene-3,4-epoxide relative to its formation.     

Effects of DDT on electrical properties of lecithin-decane bilayer membranes

Lecithin-decane bilayer membranes were treated with DDT and valinomycin, either by adding the compounds to the electrolyte around the membrane or by adding them directly to the lecithin-decane. Membrane capacitance was calculated using the dc transient technique. Specific capacitance was determined from capacitance versus area regressions and was not significantly altered by DDT. Specific K⁺ conductance was decreased by DDT, but only when DDT and the K⁺ carrier, valinomycin, were administered to the electrolyte where they may have interacted hydrophobically. It is concluded that the valinomycin-induced conductance of artificial membranes is inappropriate as a model for investigating the effects of DDT on the electrical properties of excitable membranes.     

Pyrethroid insecticides: Potent,stereospecific enhancers of mouse brain sodium channel activation

Deltamethrin and NRDC 157, pyrethroid insecticides that produce different poisoning syndromes in mammals, enhanced veratridine-dependent, sodium channel-mediated ²²Na⁺ uptake in mouse brain synaptosomes. Concentrations producing half-maximal enhancement were 2.5 × 10^?8M (deltamethrin) and 2.2 × 10^?7M (NRDC 157). This effect was stereospecific: The nontoxic 1S enantiomers had no significant effect on veratridine-dependent activation. At high deltamethrin concentrations, enhancement was maximal at 5 × 10^?5?1 × 10^?4M veratridine. Pyrethroid enhancement was completely blocked by 5 × 10^?6M tetrodotoxin, and neither pyrethroid affected ²²Na⁺ uptake in the absence of veratridine at concentrations up to 1 × 10^?5M. The relative potencies of deltamethrin and NRDC 157 in the synaptosomal sodium channel assay agree well with their relative acute toxicities to mice when administered by intracerebral injection. These findings demonstrate that pyrethroids exemplifying both characteristic poisoning syndromes are potent, stereospecific modifiers of sodium channel function in mammalian brain.     

Induced hydrogen ion transport in lipid membranes as origin of toxic effect of pentachlorophenol in an alga

Pentachlorophenol (PCP) decreases the rate of carbon assimilation in the alga Selenastrum capricornutum. In parallel with the reduction of carbon assimilation in this alga there is a decrease of electrical resistance of lipid membranes and development of negative membrane surface charge. The experimental results suggest that PCP toxicity to algae is due to adsorption of negatively charged PCP ions at the membrane surface that act as carriers of hydrogen ion across the membrane. This protonophoretic action of PCP causes the decrease of membrane electrical resistance and the dissipation of hydrogen ion electrochemical potential gradients across cellular and subcellular membranes, which reduces the ability of algae to assimilate carbon.     

In vitro activity and binding characteristics of the hydroxybenzonitriles in chloroplasts isolated from Matricaria inodora and Viola arvensis

The electron transport inhibition, uncoupling, and binding of ioxynil and bromoxynil salts is compared in chloroplast fragments isolated from two weed species with contrasting responses to the hydroxybenzonitriles. Ioxynil Na was three to four times more inhibitory than bromoxynil K towards DCPIP and SiMo reduction in both Matricaria inodora and Viola arvensis. Ioxynil Na was also a more potent uncoupler of PSI-dependent electron transport from ascorbate/DCPIP to methyl viologen. Uncoupling occurred at concentrations higher than those that inhibited electron transport. Binding studies with [¹⁴C]bromoxynil K and [¹⁴C]ioxynil Na salts revealed slightly biphasic curves with no significant difference in the amounts of the two herbicides bound at a given concentration. The ratios of inhibition constant (K_i) and binding constant (K_b) were approximately one for ioxynil Na and three for bromoxynil K. Radiolabelled herbicide displacement studies revealed that ioxynil Na could partially displace bound [¹⁴C]bromoxynil K, but bromoxynil K could not displace bound ioxynil Na at biochemically active concentrations. Ioxynil Na may be a more effective inhibitor than bromoxynil K because it binds more strongly to the thylakoid membrane.     

Dichloroacetamide herbicide antidotes enhance sulfate metabolism in corn roots

The herbicide antidotes N,N-diallyl-2,2-dichloroacetamide (R25788) and 3-dichloroacetyl-2,2,5-trimethyloxazolidine (R29148) at ppm levels slightly enhance the uptake of [³⁵S]sulfate in corn roots and greatly increase its metabolism to “bound sulfide”, cysteine, and glutathione (GSH). The decrease in free sulfate content of the roots with R25788 is closely associated with an increase in GSH level. The sulfate content is decreased with an 8-hr exposure to R25788 and R29148 at 3 ppm and its decline continues through 48 hr to about 5% of the control level. Effects on sulfate content are evident at 24 hr even with 0.3–1 ppm of these antidotes. Several other mono- or dichloroacetamide antidotes at 30 ppm also decrease the free sulfate content of corn roots to about 34–60% of control levels within 24 hr. R25788 at 30 ppm has little or no effect at 24 hr on sulfate levels in corn leaves whether the plants are grown in the light or in the dark. R25788 and R29148 decrease sulfate levels in the leaves of milo and in whole pigweed plants, but not in barley, lambsquarters, water grass, wheat, or wild mustard. In increasing GSH biosynthesis, the antidote acts in corn prior to the reduction step to form bound sulfide; in fact, R25788 increases the specific activity of ATP sulfurylase, the first enzyme involved in sulfate assimilation. Thus, dichloroacetamides such as R25788 and R29148 provide a means to experimentally, and perhaps even practically, manipulate sulfate utilization in corn and some other plants.     

Rates of sulfide oxidation in cotton,carrot, and tobacco cultured plant cells measured with a model aromatic alkyl-sulfide

p-Chlorophenylmethylsulfide (PCPMS) was enzymatically sulfoxidized to p-chlorophenylmethylsulfoxide (PCPMSO) in aerobic cotton, carrot, and tobacco cell suspension cultures. Neither boiled nor freeze-killed cell cultures were competent to sulfoxidize PCPMS to PCPMSO. The sulfone, p-chlorophenylmethylsulfone (PCPMSO₂), was not produced in any of the three species. The rates of PCPMS sulfoxidation, were cotton > carrot > tobacco. The apparent K_m for carrot cells was 88 μM PCPMS (14 μg/ml), while the apparent V_max was 7 nmol PCPMSO/mg whole cell protein/hr. These rates of sulfide oxidation are higher than previously reported in intact plants.     

Pyrethroid-hydrolyzing esterases in southern armyworm larvae: Tissue distribution,kinetic properties,and selective inhibition

Esterase activity hydrolyzing both [1RS,trans]- and [1RS,cis]-permethrin was detected in crude homogenates of the following southern armyworm (Spodoptera eridania Cramer) larval tissues: cuticle, gut, fat body, head capsule, Malpighian tubules, and silk gland. Neither substrate was detectably hydrolyzed by hemolymph. The highest esterase activities per insect equivalent of tissue were found in cuticle, gut, and fat body for the trans isomer and in cuticle and gut for the cis isomer. Each preparation hydrolyzed the trans isomer more rapidly, but the degree of specificity varied greatly between tissues. Differences in apparent K_m and V_max values between the three most active tissues were threefold or less for trans isomer hydrolysis, but differences between tissues of up to 100-fold were found for K_m and V_max values for cis isomer hydrolysis. Hydrolysis of the trans isomer in cuticle, gut, and fat body homogenates was only partially inhibited by α-naphthyl N-propylcarbamate (NPC). Concentrations of NPC giving maximal inhibition of trans isomer hydrolysis had little effect on the hydrolysis of the cis isomer. These results demonstrate that pyrethroid-hydrolyzing activity is broadly distributed in insect tissues and results from the combined activity of several esterases with different properties. It is likely that the trans and cis isomers of permethrin are hydrolyzed by separate enzymes in this insect.     

Membrane damage in human erythrocytes caused by captan and captafol

Treatment of human erythrocytes with 5 × 10^?5M captan or captafol caused a rapid increase in the efflux of intracellular potassium. Captafol had a more pronounced effect than captan on cation permeability. Captafol also decreased anion permeability whereas captan did not affect this process. Glutathione (5 × 10^?4M) had little effect in reducing potassium efflux when added to the cells after they were incubated for 1 h with captan or captafol, but it was effective in reducing the potassium loss when added to the cells prior to their treatment with the fungicides. Captafol caused an increase in osmotic fragility of the cells. Incubation of the cell membranes with captafol resulted in the liberation of a small fraction of membrane phospholipids, whereas captan produced no effect. Both the fungicides readily reacted with the sulfhydryl groups in the isolated membrane; 31.5 and 45.7% of the membrane sulfhydryl groups had disappeared following treatment with captan and captafol, respectively. It is suggested that the reaction of captan or captafol and/or their reaction products with the sulfhydryl and amino groups of the red cell membrane protein produces changes in the structure of the membrane with consequent alteration in its permeability.     

Deuterium isotope effects on the formation of mercapturic acids from lindane in rats

Metabolism experiments with rats showed that significant isotope effects ($\text{k}{}_{\mathrm{<mtext>H</mtext>}}\text{k}{}_{\mathrm{<mtext>D</mtext>}}\text{= 2.4}\text{to}\text{3.5}$) were associated with the in vivo formation of dichloro and trichlorophenylmercapturic acids from a 1:1 mixture of normal and hexadeuterated lindane. This is evidence that rate-determining dehydrogenation and dehydrochlorination, both of which proceed with significant isotope effects, are essential in the pathway of dichloro- and trichlorophenylmercapturic acid formation from lindane. No significant primary isotope effects were associated ($\text{k}{}_{\mathrm{<mtext>H</mtext>}}\text{k}{}_{\mathrm{<mtext>D</mtext>}}\text{= 1.31 ± 0.17}$) with the formation of monochlorophenylmercapturic acid. This suggests that the 1,2-dechlorination to tetrachlorocyclohexene followed by glutathione conjugation is the probable pathway that produces this metabolite from lindane.     

The effect of diflubenzuron [1-(4-chlorophenyl)-3-(2,6-difluorobenzoyl)urea] on soybean [Glycine max (L.) Merr.] photosynthesis,respiration, and leaf ultrastructure

The effect of the insecticide diflubenzuron [1-(4-chlorophenyl)-3-(2,6-difluorobenzoyl)urea] on photosynthesis, respiration, and leaf ultrastructure of soybean [Glycine max (L.) Merr., cv. Swift] was examined on plants treated at the second trifoliate leaf stage with 0, 0.067, and 0.269 kg of active ingredien/ha of diflubenzuron. Photosynthesis and respiration were measured with an infrared CO₂ analyzer in an open flow system prior to diflubenzuron application and at 4, 24, 48, and 96 hr after treatment with diflubenzuron. Diflubenzuron had no effect on soybean photosynthesis at any rate examined. Respiration was stimulated by the high rate (0.269 kg/ha) in a transitory manner. Tissue samples removed from both old and new leaves, 9 days after diflubenzuron application, were used for the ultrastructure study with the transmission electron microscope. The lower trifoliate leaves contained more starch grains than the upper ones being formed after treatment, but no aberrations or degradation of leaf ultrastructure due to diflubenzuron treatment were evident.     

Pesticide action: Different response of erythrocyte membrane acetylcholinesterase to inhibition by organophosphorus compounds under varied dietary conditions

The inhibitory effect of malathion in conjunction with maloxon or other derivatives on the activity of rat erythrocyte membrane-bound acetylcholinesterase has been investigated after feeding diets known to affect the lipid composition of the membrane. The inhibition of AchE by preincubation of membrane preparations with this organophosphorus compound, possibly with contaminants, differed with the diet: the curve was sigmoidal after supplementation with corn oil and hyperbolic after supplementation with lard. In the latter case the kinetics of the inhibition became sigmoidal by assaying in the presence of cortisol or isoproterenol or by previous solubilization of the enzyme. These results indicate that some organophosphorus compounds can differentiate conformational states of acetylcholinesterase present in the erythrocyte membrane.     

Long-term effects of DDT on the behavior and central nervous system activity in Periplaneta americana

The effects of p,p′-DDT and four of its analogs on electrical activity in the central nervous system of the cockroach, Periplaneta americana (L.), were investigated. Cockroaches were injected intraabdominally with an organochlorine compound at LD₅₀ 96-hr doses (except for p,p′-DDE). Extracellular recordings were made from the central nervous system at 1 hr, 24 hr, or 3 weeks postinjection. p,p′-DDT, methoxychlor, and p,p′-DDD induced behavioral changes (tremors, jitters, hyperexcitability) and repetitive firing in the central nervous system prior to 1 hr postinjection. By 24 hr postinjection, most behavioral signs of poisoning had disappeared, though repetitive firing could still be readily elicited in the central nervous system. Cockroaches injected with o,p′-DDT, however, usually required about 48 hr before overt signs of poisoning became apparent. Cockroaches treated with p,p′-DDT or o,p′-DDT behaved normally at 3 weeks postinjection but still displayed a significant occurrence of repetitive firing in the central nervous system. A mechanism is proposed to explain how a cockroach might recover behaviorally from a sublethal dose of an organochlorine compound but still display repetitive firing in its central nervous system. A direct “cause and effect” relationship between repetitive firing in the central nervous system and mortality (and external signs of poisoning) is therefore questioned.