Enhancement of age-related increases in DNA I-compound levels by calorie restriction: comparison of male B-N and F-344 rats.

Caloric restriction (CR), known to extend median and maximum life spans, improve resistance to carcinogenesis, and significantly retard age-associated degenerative diseases in rodents, was previously reported to modulate levels of indigenous, age-dependent DNA modifications, called I-compounds, in male Brown-Norway (B-N) rats. Since profiles of these adduct-like derivatives are species-, strain-, sex-, and tissue-specific, we explored this apparent CR/I-compound relationship in a comparative study between male B-N and male Fischer 344 (F-344) rats, the latter having a shorter life expectancy and high incidence of renal disease. Control animals were fed NIH-31 diet ad libitum (AL), while the caloric intake of CR animals was limited to 60% of AL, starting at 3.5 months. Liver and kidney DNA from 1, 8, 12, 16, 24 (AL, CR), and 30 (CR only) month old rats was analyzed by 32P-postlabeling. Corresponding tissues from the two strains yielded similar DNA profiles. Total liver I-compound levels displayed 2.3-4.6-fold age-dependent increases from 1 to 24 months, and kidney values at 24 months were 5.2-8 times higher than those at 1 month. In both strains, I-compound levels of CR animals were higher, up to 2-fold, than in age-matched AL rats. Regression analyses indicated linear relationships between most CR relative adduct labeling values (both total and individual fractions) and age, whereas many AL values exhibited this type of link with log age. These findings confirm that a correlation exists between CR and I-compound levels, and, given the above physiological benefits of CR, indicate that I-compounds represent biomarkers of aging with potential utility in intervention studies.

Formation of ribonucleotides in DNA modified by oxidative damage in vitro and in vivo. Characterization by 32P-postlabeling.

Oxygen free radicals generated by the interaction of Fe2+ and H2O2 (Fenton reaction) are capable of reacting with DNA bases, which may induce premutagenic and precarcinogenic lesions. Products formed in DNA by such reactions have been characterized as hydroxylated derivatives of cytosine, thymine, adenine, and guanine and imidazole ring-opened derivatives of adenine and guanine. As shown here by 32P-postlabeling, incubation of DNA under Fenton reaction conditions gave rise to additional oxidation products in DNA that were characterized as putative ribonucleosides by enzymatic hydrolysis of the oxidized DNA, 32P-postlabeling, and co-chromatography in multiple systems with authentic markers. Formation of these products in DNA was enhanced by the presence of L-ascorbic acid in the reaction mixtures and their total amounts were similar to those of the major DNA oxidation product, 8-hydroxy-2'-deoxyguanosine. The ribonucleoside guanosine was also formed in kidney DNA of male rats treated with ferric nitrilotriacetate, a renal carcinogen. It is postulated that ribonucleotides alter conformation and function of DNA and thus their presence in DNA may lead to adverse health effects.

DNA damage induced by cigarette smoke condensate in vitro as assayed by 32P-postlabeling. Comparison with cigarette smoke-associated DNA adduct profiles in vivo.

Cigarette smoke induces a multitude of bulky/aromatic DNA adducts in vivo as revealed by 32P-postlabeling assay. The formation of such adducts is thought to involve metabolic activation of aromatic chemicals especially polycyclic aromatic hydrocarbons (PAHs) present in tumor-initiating cigarette tar fractions, via cytochrome P450-associated monooxygenases. Because radicals are present in both the gas and particulate (tar) phase of cigarette smoke and in aqueous extracts of cigarette smoke condensate (CSC), we addressed the question as to whether cytochrome P450-independent, possibly free radical-mediated reactions may contribute, also, to formation of cigarette smoke-associated bulky DNA adducts. Rat-lung DNA was incubated with aqueous extracts of CSC in the absence of microsomes under various conditions and analyzed by 32P-postlabeling. Radioactively labeled bulky reaction products were found to accumulate in a time- and CSC concentration-dependent manner. The resulting chromatographic profiles resembled cigarette smoke-associated DNA-adduct patterns observed in vivo. Pretreatment of aqueous CSC extract with radical scavengers/reducing agents (ascorbic acid, glutathione) diminished adduct formation in a concentration-dependent manner. Adduct formation in vitro may involve oxygen-free radicals, which are known to be present in aqueous CSC extracts and could (i) attack DNA directly to produce bulky adducts, (ii) induce radical sites on DNA covalently binding CSC components, or (iii) convert CSC components to DNA-reactive electrophiles. In addition, DNA may react with direct-acting mutagens in CSC. Adduct fractions derived from in vitro and in vivo experiments showed similar chromatographic behavior, suggesting that metabolic activation as well as processes not involving metabolism lead to formation of smoking-induced bulky DNA adducts in vivo.

Bulky adducts detected by 32P-postlabeling in DNA modified by oxidative damage in vitro. Comparison with rat lung I-compounds.

Oxygen free radicals, such as the hydroxyl radical generated by interaction of Fe2+ and H2O2 (Fenton reaction), are produced in mammalian cells as a result of aerobic metabolism and under various pathological conditions and are known to elicit mutations and potentially other adverse effects by reacting with DNA bases. Several products thus formed have recently been characterized as hydroxylated derivatives of cytosine, thymine, adenine, and guanine and imidazole-ring-opened derivatives of adenine and guanine in DNA. As shown herein by 32P-postlabeling, incubation of DNA under Fenton reaction conditions led to additional products which, by virtue of resistance to nuclease P1 catalyzed 3'-dephosphorylation and chromatographic behavior, appeared to be bulky adducts rather than small polar, hydroxylated or ring-opened nucleotide derivatives. Two major and five minor DNA derivatives were measured after 32P-postlabeling and TLC mapping of DNA oxidized in vitro under conditions known to lead to formation of reactive oxygen species. Amounts of products formed depended on Fe2+ and H2O2 concentrations and increased in the presence of L-ascorbic acid. One of the two major products was also detected in lung DNA of rats where its amount increased with animal age. Thus, at least one I-compound appeared to have its origin in the interaction of DNA with reactive oxygen species.

Effects of aging and caloric restriction on I-compounds in liver, kidney and white blood cell DNA of male Brown-Norway rats.

Rodent tissues display species-, strain-, sex- and tissue-specific adduct-like DNA modifications termed I-compounds, which increase with age, are modulated by diet and are presumably derived from indigenous metabolic intermediates. We have explored whether I-compounds are affected by caloric restriction, which is known to extend life span and retard age-related degenerative and neoplastic diseases. Male Brown-Norway rats were fed NIH-31 diet ad libitum (AL). Calorically restricted (CR) rats received 60% of AL consumption, starting at 3.5 months. DNA was analyzed by 32P-postlabeling at 1, 4, 8, 12, 16 and 24 months of age in liver, kidney and white blood cells. I-compounds in AL liver and kidney exhibited complex tissue specific profiles; I-compound levels increased with age, plateaued between 8 and 18 months depending on tissue and diet and were 8.7 (liver) and 27.4 (kidney) modifications in 10(8) nucleotides at 24 months, thereby exceeding the corresponding 1-month values by 3.7- and 16.6-fold. CR resulted in similar profiles but did not diminish age-related increases, rather I-compound levels in CR liver and kidney were increased by about 70% and 30% versus age-matched AL rats. White blood cells exhibited few I-compounds and at low levels; age-related increases were small overall but more pronounced in CR rats. Higher I-compound levels in CR animals, which were presumably a consequence of metabolic effects elicited by CR, thus correlated with extended life span and, therefore, may be beneficial, in agreement with previous findings showing an association between reduced I-compound levels and hepatocarcinogenesis as well as organ susceptibility to diseases.

Induction of rat liver DNA alterations by chronic administration of peroxisome proliferators as detected by 32P-postlabeling.

The mechanisms of the hepatocarcinogenicity of non-mutagenic peroxisome proliferators, i.e. compounds used as hypolipidemic drugs and industrial plasticizers, are not sufficiently understood. To gain more information on the mechanism of their action, the chronic effects of two structurally diverse peroxisome proliferators on rat-liver DNA were investigated by the 32P-postlabeling assay. Male F-344 rats (1.5 month old) were fed ciprofibrate (0.025%) in the diet for 2, 5, 8, and 16 months or Wy-14643 (0.1%) for 18 months. Liver DNA from individual treated animals (3-4 per group) and age-matched controls was analyzed by the nuclease P1/bisphosphate version of the 32P-postlabeling assay. Three distinct types of exposure-related DNA alterations were observed: (i) A significant reduction of the age-dependent accumulation of I-compounds (putative indigenous DNA modifications) (type 1), (ii) adduct-like DNA derivatives induced by the treatments (type 2), and (iii) as yet structurally uncharacterized radiolabeled material occupying substantial areas of DNA adduct maps and accumulating in an exposure time-dependent manner (type 3). DNA from liver tumors generated by these agents displayed only traces of I-compounds, lacked all but one adduct-like derivatives, and had no type 3 alterations. Thus, in contrast to the non-mutagenicity of peroxisome proliferators in short-term assays, chronic administration of these compounds led to DNA alterations that were detectable by 32P-postlabeling assay.

Lack of I-compounds in DNA from a spectrum of Morris hepatomas.

A partial, progressive loss of I-compounds (age-dependent, putative indigenous DNA modifications) has been observed recently during hepatocarcinogenesis induced in rats by 2,3,7,8-tetrachlorodibenzo-p-dioxin, choline-devoid diet or peroxisome proliferators. It was of interest, therefore, to investigate the status of I-compounds in hepatic neoplasms. I-compounds were measured by 32P-postlabeling in eight transplantable rat (Morris) hepatomas of different growth rates and in host liver. Most I-compounds seen in liver were not detected in any of the hepatomas, and those present exhibited low levels. Hepatomas displayed an overall level of one I-compound in 2 x 10(8) DNA nucleotides, which was 7-16 times lower than liver values. The extent of I-compound deficiency did not correlate with tumor growth rate. These results, taken together with previously documented pronounced tissue-, sex-, strain- and species-specificity of I-compound profiles, suggest that I-compounds are normal DNA modifications and that their deficiency may contribute to development and maintenance of neoplasia.

A new sensitive 32P-postlabeling assay based on the specific enzymatic conversion of bulky DNA lesions to radiolabeled dinucleotides and nucleoside 5'-monophosphates.

A new sensitive 32P-postlabeling assay for DNA adducts has been developed in which DNA is hydrolyzed initially by nuclease P1 and prostatic acid phosphatase instead of micrococcal nuclease and spleen phosphodiesterase as employed in previous postlabeling procedures. When DNA containing bulky adducts, X1, X2, .....Xn, is digested with nuclease P1 at pH 5, normal nucleotides are released as 5'-monophosphates, pN, while adducts are excised as 5'-phosphorylated dinucleotides, pXipN, because internucleotide linkages on the 3' side of X resist attack by nuclease P1. Addition of prostatic acid phosphatase to such a digest results in 5'-dephosphorylation of the nucleotides to normal nucleosides, N, and adducted dinucleotides, XipN, carrying a 5'-terminal free hydroxyl group. The dinucleotides but not nucleosides are converted to 5'-32P-labeled dinucleotides, [32P]pXipN, by T4 polynucleotide kinase-catalyzed [32P]phosphate transfer from [gamma-32P]ATP. Upon mapping on polyethyleneimine--cellulose anion-exchange TLC, the labeled dinucleotide adducts produce characteristic autoradiographic fingerprints. Alternatively, they are further digested with snake venom phosphodiesterase to yield 5'-monophosphates, [32P]pXi and pN. TLC profiles of the monophosphate adducts are distinct from those of the dinucleotides. These reactions provide the basis of the new 32P-postlabeling scheme, which is compared in this paper with a previously reported protocol yielding adducts in the form of 5'-32P-labeled 3',5'-bisphosphates, [32P]pXip. The results show that the availability of three different types of 32P-postlabeled derivatives for the same adduct aids in the analysis and chromatographic characterization of DNA adducts from diverse exogenous and endogenous sources.