Structural limits of specificity of methylcholanthrene-repressible nitrosamine N-dealkylases. Inhibition by analog substrates.

The dealkylation of dimethyl-, diethyl- and dipropylnitrosamine by hepatic microsomes of Sprague-Dawley rats is repressed by pretreatment of the animals with 3-methylcholanthrene (MC), and this repression progressively decreases with the increase of alkyl chain length. In contrast to its effect on the demethylation of dimethylnitrosamine (DMN), in vivo phenobarbital induces rather than represses the deethylation of diethylnitrosamine. The rates of demethylation of the DMN analog substrates (dimethylformamide, dimethylacetamide, dimethylpropionamide, and dimethylbutyramide), although low as compared to DMN, increase with the acyl chain length. These analogs are potent in vitro inhibitors of Dmn demethylation when used in combination with DMN as substrates, and the inhibition decreases with the length of the acyl chain. Dimethylaminoacetone, which corresponds to the insertion of a CH2 group between the N atom and the carbonyl group in dimethylacetamide, is not an in vitro inhibitor of DMN demethylation; the demethylation rates are additive when theis compound is used as substrate in combination with DMN. The rate of demethylation of dimethylaminoacetone is substantially higher than the rates of the dimethylacylamides, and is significantly repressed by MC-pretreatment. The rate of demethylation of methylphenylnitrosamine is not influenced by MC-pretreatment; the compound is, however, a potent inhibitor of demethylation when used as substrate in combination with DMN. The demethylation rates of 1,1-dimethylhydrazine (the reduction product of DMN) and dimethylaniline are not influenced by MC-pretreatment; neither do they affect the overall rate of demethylation when used as substrate in combination with DMN.

Dimethylnitrosamine-demethylase: absence of increased enzyme catabolism and multiplicity of effector sites in repression. Hemoprotein involvement.

Evidence is presented that the previously observed decrease of the Vmax of hepatic microsomal demethylation of dimethylnitrosamine (DMN), following pretreatment of rats with 3-methylcholanthrene (MC), is not due to increase in the rate of breakdown but to decrease of de novo synthesis. Determinations of Vmax at time intervals in the transition from the high steady-state level induced by a carbohydrate-devoid casein diet, down to the low steady-state level of carbohydrate-containing basal diet, yielded two consecutive slopes; descent from the basal diet level to the lower steady-state level following pretreatment with MC yielded one slope. Plotting these slopes against the initial Vmax values gave a typical exponential curve (or straight line if the logs of slopes are used) indicating that the rate of enzyme decay in the MC-treated animals is not greater than that expected from normal enzyme catabolism. A multiplicity of effector sites appears to be involved in the repressor action of different structural types; for example, repression by MC (46.6%) and by phenobarbital (23.9%) in combination are approximately additive (62.0%), rather than competitive, indicating that the two agents act at different sites. A P-450 type cytochrome is involved in the demethylation of DMN. DMN-demethylase is inhibited by carbon monoxide, but the susceptibility to CO is far greater than that observed previously with 3,4-benzopyrene hydroxylation; inhibition of DMN-demethylase as a function of CO concentration follows typical enzyme kinetics. However, while both phenobarbital and MC powerfully repress the DMN-demethylase, we have confirmed that they are strong inducers of the synthesis of P-450 and P-448, respectively, as estimated from the difference spectra.

Effect of polychlorinated biphenyls (Aroclor 1254) on inducible and repressible microsomal N-demethylases in the mouse and rat.

A comparative study of the effects of the polychlorinated biphenyl mixture Aroclor 1254, 3-methylcholanthrene, and starvation on hepatic dimethylnitrosamine (DMN) demethylase (a repressible enzyme) and azo dye N-demethylase (an inducible enzyme) has been carried out. As previously observed with polycyclic hydrocarbons and phenobarbital, Aroclor in rats is a potent inducer of liver tissue proliferation and of azo dye N-demethylase. However, in mice, although the inducing effect on liver tissue proliferation and azo dye N-demethylase activity is maintained, there is no change in DMN demethylase activity as a result of Aroclor administration. As in rats, 3-methylcholanthrene induces the azo dye N-demethylase in mice. This hydrocarbon, which is known to substantially repress the DMN demethylase in rats, has, however, no effect on this enzyme in mice. While starvation is known to have a substantial inducing effect on DMN demethylase in rats, in mice starvation brings about a moderate induction of DMN demethylase.