Dietary restriction is the only known experimental method to extend lifespan in mammals, but the mechanisms of this phenomenon are still unknown. It is determined that the keeping of animals on the calorie restricted diet results in essential changes of a drug-metabolizing enzymes contents, that is also confirmed by the change of response of the enzyme system to thyroxine action. As a whole, the results obtained will be coordinated with the point of view, according to which the action mechanisms of the dietary restriction consist in considerable change of a wide spectrum of biochemical processes, including the change of the level of monooxygenase system functioning.

1. We characterized the dose-dependent induction of the microsomal monooxygenase system by phenobarbital (PB) and 3-methylcholanthrene (MC) in the female Fischer 344 rat, which was either calorie restricted (CR) or fed ad libitum (AL). 2. Maximal induction of the major inducible isozymes (2B1/2B2 or 1A1) in rat was achieved at the lowest of the inducer doses employed (10 mg/kg body weight) in both feeding groups. 3. The patterns of dose-dependent PB induction and its magnitude differed between total P450 induction and induction of catalytic activities in AL and CR groups, whereas no differences between CR and AL rat were found in either spectrally detected P450 or EROD activity patterns of dose-dependent MC induction. 4. Calorie restriction increased the inducibility of some hepatic drug-metabolizing enzyme activities. 5. Monoclonal antibody-directed inhibition of MC-induced ethoxyresorufin O-deethylation (EROD) was 55-60% at all induction levels in AL rat and 65-70% in CR rat, while MAb inhibition of PB-induced pentoxyresorufin O-depenthylation (PROD) averaged about 55% in AL and 60% in CR rat.

ABSTRACT: The effects of fasting on liver, kidney, and lung monooxygenases were studied using hamsters starved for 4 days. Fasting treatment increased microsomal cytochrome P450 content and NADPH-cytochrome P450 reductase activity in kidney and lung. The treatment caused significant increases of aniline hydroxylation, N-nitrosodimethylamine demethylation, and 7-ethoxycoumarin O-deethylation activities in the liver, kidney, and lung. Fasting caused a threefold increase of benzphetamine N-demethylation activity in lung and a 25% increase in liver and had no effect in kidney. Benzo[a]pyrene hydroxylation activities in the fasted hamster liver, kidney, and lung were higher, lower, and similar to the controls, respectively. Gel electrophoresis of tissue microsomes from control and fasted hamsters revealed that fasting enhanced the intensity of protein band(s) in the P450 molecular weight region. Immunoblotting of the microsomal proteins showed that fasting induced a protein crossreactive with rabbit antibody raised against human P450 2E1 in hamster liver, kidney, and lung. Immunoblotting analysis using mouse monoclonal antibody 2-66-3 raised against rat P450 2B1 revealed that fasting induced an immunorelated protein preferentially in hamster lung, with minimal effects on liver and kidney. Protein blots probed with mouse monoclonal antibody 1-12-3 indicated that fasting induced a protein related to P450 1A1 in hamster liver, kidney, and lung. These results demonstrate that fasting causes a variety of inductive effects on the enzyme components and catalytic activities of monooxygenase systems as well as on the P450s 2E, 2B, and 1A in the hamster tissues.