Caloric restriction, aging, and antioxidant enzymes

The basic mechanisms of aging and its retardation by caloric restriction (CR) remain unclear. One suggested means by which CR could retard aging is based on production of mitochondrial free radicals, and efficiency of their subsequent metabolism. Currently, there is little information concerning the influences of age and CR on the rates of in vivo mitochondrial free radical production. However, evidence for CR-induced modulation of free radical detoxification capacities is mounting. The direction of the influence of CR on free radical detoxification is tissue-specific. These effects are broad and appear to provide positive advantage.

Effect of caloric restriction on the metabolic activation of xenobiotics

The effect of caloric restriction (CR) on xenobiotic metabolizing enzyme activities results in alterations in the metabolic activation of chemical carcinogens, with a resultant impact on DNA-carcinogen adduct formation and DNA repair. Using aflatoxin B1 (AFB1) and benzo[a]pyrene (BP) as model carcinogens, we studied the effect of CR on the metabolic activation of these carcinogens and carcinogen-induced DNA damage and repair in terms of AFB1-DNA and BP-DNA adduct formation and removal. Male Fischer 344 rats fed calorie restricted diets (60% of the food consumption for ad libitum-fed rats) showed a reduction in the metabolic activation of AFB1 and decrease in both the in vitro and in vivo AFB1-DNA adduct formation. However, CR increased the activity of BP metabolizing enzymes resulting in an enhancement of BP-DNA adduct formation. Our results indicate that the effect of CR on metabolic activation of xenobiotics is dependent upon the selected xenobiotic metabolizing enzymes whose activities may be significantly altered by CR, and upon the nature of the chemical carcinogens which exert different structure-activity relationships during the process of chemically induced carcinogenesis.

Age-related changes in expression and activity of DNA polymerase alpha: some effects of dietary restriction

DNA polymerase alpha (pol alpha) purified from human diploid fibroblasts (HDF) and from livers of C57BL/6N mice showed age-related decreases in: (1) mRNA levels; (2) the amount of enzyme isolated per cell; and (3) enzyme activity (HDF); as well as: a) the amount of enzyme isolated; b) the specific activity; and c) the enzyme fidelity (liver). Hepatic pol alpha from dietary restricted (DR) mice exhibited less of a decline in specific activity and copied synthetic DNA templates with relatively higher fidelity than did enzymes from animals fed ad libitum (AL). Pol alpha from fetal-derived HDF exhibited increased expression compared with aged donor-derived HDF, with both fetal and old cell pol alpha in normal cells being expressed at lower levels than in their transformed cell corollaries. Treatment of human pol alpha from aged donor-derived HDF with a pol alpha accessory protein isolated from log phase murine cells resulted in increased pol alpha binding of DNA and increased pol alpha activity. However, highly active pol alpha isolated from fetal-derived or transformed HDF, or from transformed murine cells, showed little or no activity enhancement in the presence of accessory protein. These data indicate that, as a function of increased age, there is a decrease in pol alpha expression and specific activity in HDF, as well as decreases in specific activity and fidelity of pol alpha in essentially amitotic murine hepatic tissues. Dietary restriction impedes the age-related declines in both activity and fidelity of hepatic pol alpha in mice. The data further indicate that transformation of slowly dividing HDF is associated with increased expression of pol alpha, but suggest that increased expression alone is not sufficient to explain the difference in polymerase activity levels between parental and transformed HDF. Lastly, the data suggest that interaction of pol alpha with an essential accessory protein may be altered as a function of age, an alteration that appears to be correlated with the decline in pol alpha DNA binding and specific activity.

Modulation of toxicity by diet and dietary macronutrient restriction

Restriction of diet and macronutrients has been reported to modulate the toxicity of numerous chemical agents. Of the various forms of restriction studied, using nutritionally adequate diets, food restriction (FR) appears to be most effective, but protein restriction (PR), fat restriction (FtR), carbohydrate restriction (CbR), and excess of dietary fiber (FE) also affect toxicity and the spontaneous diseases that define the background incidence in toxicity tests. The heterogeneity of the dietary macronutrients complicates simple analysis of their effects. Additionally, the interrelationships between these various components in the complex dietary mixture often make experiments difficult to interpret. Despite these complexities, a simple model is presented, which considers the effects of dietary manipulations on the individual steps in the interaction of organism and agent, and puts the varied effects that can occur within an organism into context. Ultimately, many of the effects of dietary modulation on these steps in toxicogenesis can be considered as changing agent exposure and the biologically available dose. The effects of macronutrient restriction are discussed in terms of effects on agent at the interface of organism and toxicant, agent disposition, agent metabolism, and repair of toxicant-induced damage at the level of the genome. After illustrating the influence of these nutritional effects on the chronic bioassay, using mouse liver tumors as an example, the significance of these effects for chronic and short-term testing is discussed. Additionally, methods to address the impact of nutritional factors on toxicity testing are suggested.

Effects of caloric restriction in animals on cellular function, oncogene expression, and DNA methylation in vitro

While the life-extending and disease-modulating effects of caloric restriction (CR) are well documented in whole animal studies and in correlative experiments using cells taken from CR animals, very few studies have used cells in culture after their removal from the CR-fed animal. In using this in vivo-->in vitro approach we have attempted to examine the proposition that the effects of CR can be transferred to individual cells by analyzing the cellular functions of proliferation and transformation, the activation of oncogenes, and the methylation of DNA as a function only of diet. Pancreatic acinar cells excised from CR-fed Brown-Norway rats and placed in rich medium showed different responses compared to cells from ad libitum (AL)-fed controls. CR had the effect of slowing growth rate and protecting against spontaneous and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced transformation over 14 passages of cells in culture. At the molecular level, cells from the CR animals showed reduced c-Ha-ras oncogene expression and mutation as well as reduced mutation of the p53 suppressor gene. CR also increased genomic methylation of ras DNA. We conclude that the effects of CR treatment of the animal are transferred to individual cells and note that these responses (decreased proliferation and transformation; depressed oncogene expression and mutation and decreased suppressor gene mutation; and increased oncogene methylation) are cellular and molecular analogs of in vivo weight loss, life extension, and carcinogenesis modulation, which are hallmarks of CR in the whole animal. The fact that these responses are seen generations after the cells are removed from the CR-treated animal indicates that CR causes a permanent predisposition of pancreatic acinar cells to these modulated responses and shows the value of the in vivo-->in vitro protocol in studies that relate diet to cellular and molecular function.

Effects of caloric restriction on rodent drug and carcinogen metabolizing enzymes: implications for mutagenesis and cancer

Caloric restriction in rodents results in increased longevity and a decreased rate of spontaneous and chemically induced neoplasia. The low rates of spontaneous neoplasia and other pathologies have made calorically restricted rodents attractive for use in chronic bioassays. However, caloric restriction also alters hepatic drug metabolizing enzyme (DME) expression and so may also alter the biotransformation rates of test chemicals. These alterations in DME expression may be divided into two types: (1) those that are the direct result of caloric restriction itself and are detectable from shortly after the restriction is initiated; (2) those which are the result of pathological conditions that are delayed by caloric restriction. These latter alterations do not usually become apparent until late in the life of the organism. In rats, the largest direct effect of caloric restriction on liver DMEs is an apparent de-differentiation of sex-specific enzyme expression. This includes a 40-70% decrease in cytochrome P450 2C11 (CYP2C11) expression in males and a 20-30% reduction of corticosterone sulfotransferase activity in females. Changes in DME activities that occur late in life in calorically restricted rats include a stimulation of CYP2E1-dependent 4-nitrophenol hydroxylase activity and a delay in the disappearance of male-specific enzyme activities in senescent males. It is probable that altered DME expression is associated with altered metabolic activation of chemical carcinogens. For example the relative expression of hepatic CYP2C11 in ad libitum-fed or calorically restricted rats of different ages is closely correlated with the amount of genetic damage in 2-acetylaminofluorene- or aflatoxin B1-pretreated hepatocytes isolated from rats of the same age and caloric intake. This suggests that altered hepatic drug and carcinogen metabolism in calorically restricted rats can influence the carcinogenicity of test chemicals.

Hepatic nuclear ploidy distribution of dietary-restricted mice

Hepatic parenchymal cells in most adult mammals are polyploid, with most of the cells in the quiescent or low-proliferation state. Polyploidization has been related to carcinogenesis and aging, and both end points are significantly affected by dietary restriction (DR). Direct measures of hepatic nuclear polyploidization in DR B6C3F1 mice have not been examined. We examined the effect of DR on distributions of nuclear ploidy in both sexes and on different age groups of B6C3F1 mice. Differences between young and old male mice and between old male and female mice were also compared. Hepatic nuclear ploidy values were measured by flow cytometry. The DNA histograms were analyzed for the percentage of nuclei having different classes of DNA content by gating channels between the areas under the peaks of diploid, tetraploid, and octaploid. The results indicate that 1 or 26 months of DR started at 4 months of age did not alter hepatic nuclear ploidy distributions in young and old mice. Our data suggest that in the male mouse, polyploidization is established by 5 months of age for hepatic nuclei and that ploidy classes are affected by sex at 30 months of age. For females, effects in the octaploid nuclei are seen as a result of DR.

Biomarkers of aging: correlation of DNA I-compound levels with median lifespan of calorically restricted and ad libitum fed rats and mice

I-compounds are species-, tissue-, genotype-, gender-, and diet-dependent bulky DNA modifications whose levels increase with animal age. While a few of these DNA modifications represent oxidation products, the majority of I-compounds appear to be derived from as yet unidentified endogenous DNA-reactive intermediates other than reactive oxygen species. Circadian rhythms of certain I-compounds in rodent liver imply that levels of these DNA modifications are precisely regulated. Caloric restriction (CR), the currently most effective method available to retard aging and carcinogenesis, has been previously shown to elicit significant elevations of I-compound levels in tissue DNA from Brown-Norway (BN) and F-344 rats as compared to age-matched ad libitum fed (AL) animals. The present investigation has extended this work by examining liver and kidney DNA I-compound levels in three genotypes of rats (F-344, BN, and F-344 x BN) and two genotypes of mice (C57BL/6N and B6D2F1) under identical experimental conditions in order to determine whether correlations exist between I-compound levels, measured in middle-aged animals, and median lifespan. Levels of a number of liver and kidney I-compounds were found to display genotype- and diet-dependent, statistically significant positive linear correlations with median lifespan in both species. In particular, the longer-lived hybrid F-344 x BN rats and B6D2F1 mice tended to exhibit higher I-compound levels than the parent strains. CR enhanced I-compound levels substantially in both rats and mice. Thus, I-compounds, measured at middle age, reflected the functional capability ('health') of the organism at old age, suggesting their predictive value as biomarkers of aging. The positive linear correlations between levels of certain I-compounds (designated as type I) and lifespan suggest that these modifications may be functionally important and thus not represent endogenous DNA lesions (type II), whose levels would be expected to correlate inversely with lifespan.

Effect of caloric restriction on aflatoxin B1-induced DNA synthesis, AFB1-DNA binding and cell proliferation in Fischer 344 rats

Young adult male Fischer rats maintained on a reduced calorie diet (60% of ad libitum food consumption) for 6 weeks showed a decrease in the binding of aflatoxin B1 (AFB1) to hepatic or renal nuclear DNA and a reduction of AFB1-induced hepatocellular damage. Repeated dosing of rats with AFB1 resulted in the inhibition of hepatic and renal DNA synthesis measured by [3H]thymidine incorporation. However, the rate of DNA synthesis was greater in ad libitum (AL) rats than in calorically restricted (CR) animals. Three days after AFB1 dosing, the rate of DNA synthesis had recovered to the control level. Cell cycle analyses measured by a flow cytometric method on kidney cells of both AL and CR rats showed that there were no significant changes in cell populations in the S phase between these two groups of rats. AFB1 inhibited the cell proliferation on an average of 33%. The restoration of the cell proliferation in kidney cells was found on the third day after AFB1 dosing. The rate of the regenerative cell proliferation was found to be slightly greater in AL rats than in CR animals. The AFB1-induced regenerative DNA synthesis in both liver and kidney was retarded by CR.

Cell proliferation by cell cycle analysis in young and old dietary restricted mice

The effect of dietary restriction (DR) on cell proliferation determined by cell cycle analysis in tissues of young and old mice was investigated. Using the percentage of S-phase cells as an index of cell proliferation, we found that DR inhibited cell proliferation in spleen and thymus in young mice. No significant changes were found in bone marrow and kidney in the ad libitum (AL) or DR mice regardless of age. In old mice, the DR effect was observed in spleen only. When age increased, a parallel decline in cell proliferation was evidenced by a reduced % of S-phase cells. DR produces a greater cell cycle effect in the young mice than in the old mice. The present data suggests that inhibition of cell proliferation by DR may be affected by type of tissue, age, length of DR, and capacity or rate of cell proliferation.

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.

Effect of caloric restriction on the induction of hepatic cytochrome P-450 and Ah receptor binding in C57BL/6N and DBA/2J mice

While it is known that caloric restriction alters activities of certain xenobiotic metabolizing enzymes, the mechanism(s) by which this occurs have not been determined. In this study, caloric restriction (CR) increases activities of liver cytochrome P450IA1 dependent ethoxyresorufin-O-deethylase (EROD) and aryl hydrocarbon hydroxylase (AHH) and cytochrome P450IIB1 dependent pentoxyresorufin-O- dealkylase (PROD) in DBA/2J or C57BL/6N mice. However, the cytosolic Ah receptor binding in both strains of mice was not increased. The hepatic cytochrome P450IA1 activity was increased by CR in DBA/2J mice (a strain lacking normal Ah receptor binding), indicating that this induction need not be mediated by the Ah receptor. The effects of CR, sex and strain on P450IA1 induction by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) were also determined. Specific induction of cytochrome P450IA1 by TCDD was greater in females than in males of both strains, whereas the P450 isozymes induced in male DBA/2J mice had less specificity toward 7-ethoxyresorufin than those induced in C57BL/6N mice. Moreover, P450IA1 induction by TCDD was significantly potentiated by CR in the DBA/2 strain, indicating the interactive involvement of different regulatory mechanisms.

An in vitro pancreas acinar cell model for testing the modulating effects of caloric restriction and ageing on cellular proliferation and transformation

Pancreatic acinar cells were isolated for culture from a young (Y) and an old (O) Brown-Norway or Fischer 344 rat fed an ad libitum (AL) or calorically restricted (CR) diet. The cells were cultured and cellular growth rates were determined as a function of passage number. An overall increase in cellular growth rate and transformation frequency with age and/or AL diet relative to youth as well as a decrease with CR diet were concordant with reported responses in vivo. Transformation frequency was measured in Brown-Norway cells and followed the same pattern as the growth response: AL/O > AL/Y = CR/Y > CR/O. The cellular model is shown to fit the general multistage requirements of the carcinogenic process as well as general age and diet characteristics of pancreatic cancer. This pancreatic acinar cell age-diet approach may prove to be a valuable tool for determining mechanisms of exocrine pancreatic carcinogenesis as well as other disease states; it may also be of utility in in vitro gerontological nutritional and pharmacological studies since some of the age and diet determinants of biological effects appear to be segregable. Propensity of cells from an old and/or AL diet animal for faster growth and for cellular transformation are programmed into the cells by the time of their excision from the animal (as late as 14 months), indicating a heritable component in the model or a mechanism that is dependent upon elements that control gene expression.

Overview of cancer and aging: a mechanistic perspective

Cancer and aging are approached from the standpoint of damaging agents affecting target cell, local cellular environment, and the organism as a whole. The effects of exogenous agents are represented in a model emphasizing absorption, organismic disposition, and cellular disposition. Endogenous agents are represented similarly. The extent of endogenous damage is illustrated. Factors in the expression of damage as a toxic endpoint are emphasized, with the example of caloric restriction used as an example of environmental modulation of response.

Oxidative DNA damage levels in rats fed low-fat, high-fat, or calorie-restricted diets

Increased fat and caloric content of the diet has been associated with increased mammary tumor incidence. The dietary modulation of cellular redox state may be one mechanism behind this association. We have examined the effects of changes in dietary fat and caloric intake on the levels of 5-hydroxymethyluracil in DNA from rat liver and mammary gland. Female Fischer 344 rats, 40 days old, were maintained on 3% (low-fat), 5% (control), or 20% (high-fat) corn oil diets for 2 weeks. A fourth group of rats had the same daily fat intake as the control group, but total caloric intake was restricted by 40%. As a measure of oxidative DNA damage, 5-hydroxymethyluracil levels were measured in the DNA extracted from liver and mammary gland by gas chromatography-mass spectrometry. 5-Hydroxymethyluracil levels in the liver DNA of the low-fat, high-fat, and calorie-restricted groups were decreased relative to that of control, but the only significant decrease was in the calorie-restricted group (p less than 0.01). In the mammary gland DNA, statistically significant decreases in damage were found in each group relative to control (p less than 0.05). The relationship between fat in the diet and oxidative stress is thus complex. These results show that changes in dietary intake of both fat and calories can modulate oxidative DNA damage levels, and the effect of diet was more clearly evident in the DNA from mammary gland than in DNA from liver.

The high mobility group of nuclear proteins as biomarkers of age and caloric restriction in rats

The quantitative levels and phosphorylation states of the high mobility group (HMG) of proteins were investigated in bone marrow, brain, heart, kidney, liver, pancreas, spleen, testis and thymus of three groups of male Fischer 344 rats. Two groups of rats, young ad libitum (Y/AL - 1 1/2 mo.) and old ad libitum (O/AL - 28 mo.), had free access to rat chow, and a third group of old rats were maintained on a caloric restricted intake (O/CR - 28 mo.). The quantities of HMGs 1,2,14 and 17 were significantly reduced in O/AL rats compared with Y/AL rats in all tissues examined, and in many cases, the amount of HMGs of O/CR rats were increased by varying degrees from O/AL animals. In G2-phase nuclei of bone marrow, spleen and testis, phosphorylation of HMG proteins was reduced significantly in O/AL rats, but was enhanced in O/CR animals (especially HMG14). These levels of HMGs in O/CR animals, altered by age and diet dependent factors, reflect a condition which is more reminiscent of Y/AL than O/AL animals.

Modulation of chemical toxicity by modification of caloric intake

Caloric restriction increases maximum achievable lifespan and offsets the time to development of degenerative disease. Part of these desirable effects may result from positive modulation of toxic events. We have shown that when rodents are placed on a diet that is reduced in total calories by 40%, several beneficial changes on biochemical systems which impact on toxicologic processes are positively enhanced. Lipid metabolism is reduced and, therefore, the potential for lipoperoxidation is reduced. Additionally, activity of enzymes that produce free radicals as byproducts (cytochrome P4502C11) are also reduced. Concurrently, we have shown that the "effective" activity of catalase and the activity of superoxide dismutase (which are required for the detoxification of toxic oxygen radicals) are significantly increased by caloric restriction. The activities of enzymes of drug and xenobiotic metabolism are also altered by caloric restriction. The effect upon activity may be to either decrease or increase activity, dependent upon whether the enzyme activates compounds to intermediates which may be more toxic or whether the enzyme acts to reduce toxicity. We have also shown that caloric restriction may affect the initiation stage of carcinogenesis. Aflatoxin B1 binding to hepatic nuclear DNA was reduced by caloric restriction (caloric restriction reduced both major adducts that are formed upon exposure to aflatoxin B1). caloric restriction also reduced cytochrome P4502C11 which converts aflatoxin B1 to its toxic epoxide, and may partly explain the reduction in binding. These results suggest that caloric restriction may, in part, extend the time to development of degenerative disease by altering basic biochemical mechanisms of toxicity.

Pharmacokinetics of cefuroxime axetil and cefaclor: relationship of concentrations in serum to MICs for common respiratory pathogens

The pharmacokinetics of single doses of cefaclor at 250 and 375 mg and cefuroxime axetil at 250 mg administered under optimal conditions (i.e., cefuroxime axetil after food and cefaclor in the fasted state) were studied in 24 healthy male volunteers. Drug concentrations in serum were related to MICs for common respiratory tract pathogens by using data generated from a recently completed national survey. The time the concentrations in serum exceeded the MICs for Haemophilus influenzae, Streptococcus pneumoniae, and Moraxella (formerly Branhamella) catarrhalis were significantly greater (P less than 0.05) for cefuroxime axetil at 250 mg than for cefaclor at 250 or 375 mg. With the recommended dosing regimens (cefuroxime axetil at 250 mg and cefaclor at 375 mg twice daily or cefaclor at 250 mg three times daily), cefuroxime concentrations exceed the MIC for 90% of the strains tested for a greater time period than cefaclor concentrations with either regimen. The reasons for this difference are (i) the greater potency and slower clearance of cefuroxime compared with those of cefaclor and (ii) the greater sensitivity of these pathogens to cefuroxime.

Cell cycle analysis in bone marrow and kidney tissues of dietary restricted rats

The effect of dietary restriction (DR) on the proportion of cells in various phases of the cell cycle as determined by flow cytometry was investigated in the bone marrow and kidney of young and old Fischer 344 rats. Control rats were fed a standard occurrence of numerous age-associated diseases, including cancer, renal diseases and by the control rats starting at 16 weeks of age until killed at 5 or 20 months old. The relative proportion of cells in the various phases of the cell cycle was independent of tissue type, treatment condition and age, consistently showing an order of G1- greater than S- greater than G2M-phase. In old rats DR did not affect cell cycling in bone marrow of either sex, however, it did cause an increase in the percentage of G1-phase cells in the kidney of male rats. Additionally, DR caused a mathematically significant change in the percentage of cells in all phases of the cell cycle in the bone marrow of young male rats but had no effect in young females. The percentage of S-phase cells in both tissues of both sexes decreased in old rats when compared to young rats regardless of treatment conditions, indicating a parallel decline in cell proliferating activity with aging. To summarize, DR produces a greater cell cycle effect in the young male than the old male rats. Proliferative capacity is enhanced when the young male rats are dietary restricted. This may aid in DNA repair mechanisms and/or immune system response.

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.

Concentration of cefuroxime in serum and middle ear effusion after single dose treatment with cefuroxime axetil

Antimicrobial agents play an important role in the treatment of patients with acute otitis media and otitis media with effusion (OME). The study was undertaken to determine the concentrations of cefuroxime in the blood and middle ear effusions (MEE) of children between 6 and 12 years of age with acute otitis media and chronic OME after a single oral dose administration of cefuroxime axetil, the ester prodrug of cefuroxime. Cefuroxime axetil (250 mg) was administered 2 to 6 hours before either myringotomy for acute otitis media or myringotomy and tube insertion for chronic OME. Blood samples and middle ear aspirates were obtained from 31 children and the samples were analyzed by high performance liquid chromatography. Cefuroxime was recovered in measurable concentrations in all serum samples and in 15 (79%) of the 19 MEE specimens analyzed. No correlation was seen between cefuroxime MEE concentrations and effusion type, bacteriology or serum concentrations. This study shows that cefuroxime does penetrate into MEE when OME is present and that therapeutic concentrations can be achieved in some patients.

Effect of dietary restriction on the fidelity of DNA polymerases in aging mice

DNA polymerases purified from hepatic tissues of C57BL/6 mice showed an age-related decrease in both specific activity and fidelity of the various enzyme forms. Polymerases from dietary restricted mice exhibited less of a decline in specific activity and copied synthetic DNA templates with relatively higher fidelity than did enzymes from animals fed ad libitum. Polymerases treated with inositol-1,4-bisphosphate [I(1,4)P2] showed varying levels of increased activity, with fidelity increases up to 3-fold. These data indicate that aging is associated with decreases in both specific activity and fidelity of DNA polymerases isolated from a nondividing tissue, and that dietary restriction impedes the age-related decline in both specific activity and fidelity of these polymerases. The data further indicate that DNA polymerases may interact with phosphoinositide hydrolysis products resulting in increased specific activity and fidelity of the enzymes. Phosphoinositide interactions with polymerases could constitute an important mechanism moderating the age-related decrease in function and accuracy of DNA polymerases.