Relationship between life expectancy, endogenous antioxidants and products of oxygen free radical reactions in the housefly, Musca domestica

Potential Use of Moringa oleifera Twigs Extracts as an Anti-Hyperuricemic and Anti-Microbial Source

Moringa oleifera (MO) grows throughout most of the tropics and has several industrial and medicinal uses. Besides the various uses of the plant parts such as its leaves, seed kernels, roots, or stem barks, the twigs (MT) of this plant are usually regarded as excessive parts. Although there have been few studies conducted to determine the value of this plant part, in fact, its potential uses—especially the pharmaceutical effects—of this biomaterial remains an up-to-date topic for scientists to discover due to the lack of interest so far. This study aims to identify the optimized fractions of different solvents for the extraction of antioxidants, for xanthine oxidase inhibition agents, and for anti-microbial activities. The two most active fractions obtained by column chromatography were the Hexane-Ethyl Acetate elution at a 9:1 (E1) and 8:2 (E2) ratio, respectively. With regard to antioxidant activity, E1 and E2 displayed relatively high DPPH radical scavenging capacity (IC50 = 87.7 and 99.0 µg/mL), which was only four times weaker than the control BHT (IC50 = 21.4 µg/mL). The highest inhibition activity against xanthine oxidase was also observed clearly in E1 and E2, which showed relatively low IC50 (54.7 and 42.0 µg/mL, respectively). These levels were inconsiderably higher than that of the positive control (IC50 = 20.8 µg/mL), proving that E1 and E2 exerted relatively strong antioxidant activity in terms of XOD inhibition. Regarding the antimicrobial test, E2 showed the highest inhibition activities against E. coli, K. pneumoiae, L. monocytogenes, B. subtilis, and P. mirabilis. The result indicates that (1) E1 and E2 were the strongest fractions for constraining free radical agents and several bacteria, and thus, (2) Moringa oleifera twigs are also a potential source for the prevention of gout-related symptoms.

Cerium caused life span shortening and oxidative stress resistance in Drosophila melanogaster

To investigate the effects of the rare earth element cerium (Ce) on the life span and biomarkers of oxidative stress in the fruit fly (Drosophila melanogaster). Fruit flies were fed on media with different dose of ceric sulfate (1, 4, 16, 64, 256, 1024mg/L, corresponding to cerium concentrations of 0.45, 1.65, 6.91, 26.3, 104, and 429microg/g culture medium). Mean life span, maximum life span, and fertility were calculated. There was a significant decrease in mean life span and maximum life span with increasing doses of cerium. At some concentrations, there was a decrease in reproductive output, especially concentrations >6.91microg/g. We also measured superoxide dismutase (SOD) activity, catalase (CAT) activity, and lipid peroxidation product levels (malondialdehyde (MDA) content). Cerium caused a significant increase in MDA content and decrease in SOD and CAT activities at concentrations >6.91microg/g. These results suggest that cerium may result in oxidative toxicity to D. melanogaster.

Early onset senescence occurs when fibroblasts lack the glutamate-cysteine ligase modifier subunit

Cellular senescence is the irreversible entry of cells into growth arrest. Senescence of primary cells in culture has long been used as an in vitro model for aging. Glutamate-cysteine ligase (GCL) controls the synthetic rate of the important cellular antioxidant glutathione (GSH). The catalytic subunit of GCL, GCLC, is catalytically active and essential for life. By contrast the modifier subunit of GCL, GCLM, is dispensable in mice. Although it is recognized that GCLM increases the rate of GSH synthesis, its physiological role is unclear. Herein, we show that loss of Gclm leads to premature senescence of primary murine fibroblasts as characterized by: (a) diminished growth rate, (b) cell morphology consistent with senescence, (c) increases in senescence-associated beta-galactosidase activity, and (d) cell cycle arrest at the G(1)/S and G(2)/M boundaries. These changes are accompanied by increased intracellular ROS, accumulation of DNA damage, and induction of p53 and p21 proteins. We also found that N-acetylcysteine increases intracellular GSH and prevents premature senescence in Gclm(-/-) cells. These results suggest that the control of GCLM, which in turn controls aspects of the cellular redox environment via GSH, is important in determining the replicative capacity of the cell.

Ageing in nematodes: do antioxidants extend lifespan in Caenorhabditis elegans?

Antioxidants are often investigated as a promising strategy for extending lifespan. Accordingly, there is significant interest in novel antioxidant compounds derived from natural sources such as plant extracts. However, because lifespan studies are laborious and expensive to conduct, candidate compounds are frequently selected based simply on their in vitro antioxidant efficacy, with the implicit assumption that in vitro antioxidants are also in vivo antioxidants, and that in vivo antioxidants will decrease functionally relevant oxidative damage and thereby extend lifespan. We investigated the validity of these assumptions in the model organism, Caenorhabditis elegans. Nematodes were exposed to 6 plant extracts, selected out of a total of 34 based on a simple in vitro antioxidant assay. We found no correlation between in vitro and in vivo antioxidant capacities. Antioxidant efficacies were also not predictive of lifespan benefits. Further studies into those extracts that produced significant lifespan extension indicated that a direct antioxidant effect is unlikely to be the main factor responsible for the modulation of nematode lifespan.

[Immunological markers of ageing]

Ageing is a process involving morphological and physiological modifications that gradually appear with time and lead to death. Given the heterogeneous nature of the process among individuals and among the different organs, tissues, and systems in the same individual, the concept of <<biological age>> has been developed. The search for parameters that enable us to evaluate biological age--and therefore longevity--and the analysis of the efficacy of strategies to retard the ageing process are the objectives of gerontology. At present, one of the most important theories of ageing is the <<oxidative-inflammatory>> theory. Given that immune cell function is an excellent marker of health, we review the concepts that enable different functional and oxidative stress parameters in immune cells to be identified as markers of biological age and longevity. None of these parameters is universally accepted as a biomarker of ageing, although they are becoming increasingly important.

Somatic mtDNA mutations cause aging phenotypes without affecting reactive oxygen species production

The mitochondrial theory of aging proposes that reactive oxygen species (ROS) generated inside the cell will lead, with time, to increasing amounts of oxidative damage to various cell components. The main site for ROS production is the respiratory chain inside the mitochondria and accumulation of mtDNA mutations, and impaired respiratory chain function have been associated with degenerative diseases and aging. The theory predicts that impaired respiratory chain function will augment ROS production and thereby increase the rate of mtDNA mutation accumulation, which, in turn, will further compromise respiratory chain function. Previously, we reported that mice expressing an error-prone version of the catalytic subunit of mtDNA polymerase accumulate a substantial burden of somatic mtDNA mutations, associated with premature aging phenotypes and reduced lifespan. Here we show that these mtDNA mutator mice accumulate mtDNA mutations in an approximately linear manner. The amount of ROS produced was normal, and no increased sensitivity to oxidative stress-induced cell death was observed in mouse embryonic fibroblasts from mtDNA mutator mice, despite the presence of a severe respiratory chain dysfunction. Expression levels of antioxidant defense enzymes, protein carbonylation levels, and aconitase enzyme activity measurements indicated no or only minor oxidative stress in tissues from mtDNA mutator mice. The premature aging phenotypes in mtDNA mutator mice are thus not generated by a vicious cycle of massively increased oxidative stress accompanied by exponential accumulation of mtDNA mutations. We propose instead that respiratory chain dysfunction per se is the primary inducer of premature aging in mtDNA mutator mice.

A new sensitive assay reveals that hemoglobin is oxidatively modified in vivo

Free radical formation in heme proteins is recognised as a factor in mediating the toxicity of peroxides in oxidative stress. As well as initiating free radical damage, heme proteins damage themselves. Under extreme conditions, where oxidative stress and low pH coincide (e.g., myoglobin in the kidney following rhabdomyolysis and hemoglobin in the CSF subsequent to subarachnoid hemorrhage), peroxide can induce covalent heme to protein cross-linking. In this paper we show that, even at neutral pH, the heme in hemoglobin is covalently modified by oxidation. The product, which we term OxHm, is a "green heme" iron chlorin with a distinct optical spectrum. OxHm formation can be quantitatively prevented by reductants of ferryl iron, e.g., ascorbate. We have developed a simple, robust, and reproducible HPLC assay to study the extent of OxHm formation in the red cell in vivo. We show that hemoglobin is oxidatively damaged even in normal blood; approximately 1 in 2,000 heme groups exist as OxHm in the steady state. We used a simple model (physical exercise) to demonstrate that OxHm increases significantly during acute oxidative stress. The exercise-induced increase is short-lived, suggesting the existence of an active mechanism for repairing or removing the damaged heme proteins.

D-galactose-caused life shortening in Drosophila melanogaster and Musca domestica is associated with oxidative stress

D-galactose causes aging acceleration in different animal models but the mechanism is unclear. In the present study, we investigated the effects of D-galactose on lifespan and oxidative stress biomarkers in the fruit fly (Drosophila melanogaster) and housefly (Musca domestica). D-galactose was added to drinking water (20 mg/ml) for housefly and to culture medium (6.5%) for fruit fly from 24 h after emergence. Oxidative stress was estimated by measuring the activity of Cu-Zn-superoxide dismutase (SOD) and the levels of lipid peroxidation products, namely malondialdehyde (MDA) and lipofuscin in housefly brain (male) and in fruit fly (male and female). D-galactose caused a significant decrease in mean lifespan (by 12.6% of male and 15.9% of female) and maximum lifespan (by 12.9% of male and 17.1% of female) in fruit fly, and also a significant decrease in mean lifespan (by 27.1% of male, 19.8% of female) and maximum lifespan (by 27.1% of male, 21.9% of female) in housefly. MDA and lipofuscin increased with age in fruit fly and in housefly brains while change of the SOD activity showed a biphasic shape with age. D-galactose caused a significant increase in MDA and lipofuscin and decrease in SOD activity in the age-matched fruit flies and houseflies. These data indicate that D-galactose shortens the lifespan of the two different fly species and that the life shortening effect is associated with an increase in oxidative stress.

Mitochondrial DNA and aging

Among the numerous theories that explain the process of aging, the mitochondrial theory of aging has received the most attention. This theory states that electrons leaking from the ETC (electron transfer chain) reduce molecular oxygen to form O2•− (superoxide anion radicals). O2•−, through both enzymic and non-enzymic reactions, can cause the generation of other ROS (reactive oxygen species). The ensuing state of oxidative stress results in damage to ETC components and mtDNA (mitochondrial DNA), thus increasing further the production of ROS. Ultimately, this ‘vicious cycle’ leads to a physiological decline in function, or aging. This review focuses on recent developments in aging research related to the role played by mtDNA. Both supportive and contradictory evidence is discussed.

Understanding aging: revealing order out of chaos

Aging is often described as an extremely complex process affecting all of the vital parameters of an individual. In this article, we review how understanding of aging evolved from the first analyses of population survival to the identification of the molecular mechanisms regulating life span. Abundant evidence implicates mitochondria in aging and we focus on the three main components of the mitochondrial theory of aging: (1) increased reactive oxygen species (ROS) production, (2) mitochondrial DNA (mtDNA) damage accumulation, and (3) progressive respiratory chain dysfunction. Experimental evidence shows a relationship between respiratory chain dysfunction, ROS damage, and aging in most of the model organisms. However, involvement of the mtDNA mutations in the aging process is still debated. We recently created a mutant mouse strain with increased levels of somatic mtDNA mutations causing a progressive respiratory chain deficiency and premature aging. These mice demonstrate the fundamental importance of the accumulation of mtDNA alterations in aging. We present here an integrative model where aging is provoked by a single primary event leading to a variety of effects and secondary causes.

Selected contribution: Carotid body as a model for aging studies: is there a link between oxygen and aging?

The carotid body (CB) is the site in the body that triggers awareness of changes in blood oxygen pressure. Aging is characterized by a decrease in oxygen supply to tissues, in reduction of tissue Po2, and in the activity of several enzymes and metabolic factors. The ventilatory response to hypoxia is attenuated with aging related to the age-dependent structure modifications including the basal reduction of oxygen requirements. The aged CB shows an increase in extracellular matrix, a reduction in number and volume of type I cells, and a reduction in volume of mitochondria that was consistent with and similar to that during chronic hypoxia; this phenomenon seems to operate also during aging as shown by the reduced volume of mitochondria in the aged CB. During chronic hypoxia, CB hypertrophy is less evident in aged CB than in young CB. Therefore, hypoxia and aging seem to share some type of link at different cell sites. CB represents an experimental model adequate for studying aging processes because of its high blood flow and metabolism, and thus it serves as a means to understanding the oxygen modulation of the aging process.

Ageing and the free radical theory

The free radical theory proposes that ageing is the cumulative result of oxidative damage to the cells and tissues of the body that arises primarily as a result of aerobic metabolism. Several lines of evidence have been used to support this hypothesis including the claims that: (1) variation in species life span is correlated with metabolic rate and protective antioxidant activity; (2) enhanced expression of antioxidative enzymes in experimental animals can produce a significant increase in longevity; (3) cellular levels of free radical damage increases with age; and (4) reduced calorie intake leads to a decline in the production of reactive oxygen species and an increase in life span. The free radical theory may also be used to explain many of the structural features that develop with ageing including the lipid peroxidation of membranes, formation of age pigments, cross-linkage of proteins, DNA damage and decline of mitochondrial function. Despite this, many uncertainties concerning the role of oxidative damage in ageing remain and alternative explanations cannot be ruled out. Free radicals only occur in trace quantities in biological tissues, their cellular levels and actions cannot be measured in vivo, and definitive proof that oxidised molecules are the primary cause of ageing is lacking. Moreover, ageing is also likely to be a multifactorial process and not reducible to any one single cause. Thus, despite its positive features, the evidence for the free radical theory is either correlative or inconclusive.

Oxidative damage during aging targets mitochondrial aconitase

The mechanisms that cause aging are not well understood. The oxidative stress hypothesis proposes that the changes associated with aging are a consequence of random oxidative damage to biomolecules. We hypothesized that oxidation of specific proteins is critical in controlling the rate of the aging process. Utilizing an immunochemical probe for oxidatively modified proteins, we show that mitochondrial aconitase, an enzyme in the citric acid cycle, is a specific target during aging of the housefly. The oxidative damage detected immunochemically was paralleled by a loss of catalytic activity of aconitase, an enzyme activity that is critical in energy metabolism. Experimental manipulations which decrease aconitase activity should therefore cause a decrease in life-span. This expected decrease was observed when flies were exposed to hyperoxia, which oxidizes aconitase, and when they were given fluoroacetate, an inhibitor of aconitase. The identification of a specific target of oxidative damage during aging allows for the assessment of the physiological age of a specific individual and provides a method for the evaluation of treatments designed to affect the aging process.

Oxidative stress, caloric restriction, and aging

Under normal physiological conditions, the use of oxygen by cells of aerobic organisms generates potentially deleterious reactive oxygen metabolites. A chronic state of oxidative stress exists in cells because of an imbalance between prooxidants and antioxidants. The amount of oxidative damage increases as an organism ages and is postulated to be a major causal factor of senescence. Support for this hypothesis includes the following observations: (i) Overexpression of antioxidative enzymes retards the age-related accrual of oxidative damage and extends the maximum life-span of transgenic Drosophila melanogaster. (ii) Variations in longevity among different species inversely correlate with the rates of mitochondrial generation of the superoxide anion radical (O2) and hydrogen peroxide. (iii) Restriction of caloric intake lowers steady-state levels of oxidative stress and damage, retards age-associated changes, and extends the maximum life-span in mammals.

Low levels of reactive oxygen species as modulators of cell function

In this paper, we present various arguments supporting the hypothesis that reactive oxygen species (ROS) could be responsible for the modulation of various cellular functions, besides their well known toxic effects. We first review the recent evidence indicating that ROS are able to modulate genome expression through specific and precise mechanisms during cell activation. The role of the nitrogen reactive radicals such as nitric oxide is separately analyzed because of its specific role in the nervous and vascular systems. The action of the other ROS on gene activation will then be reviewed by first looking at their possible involvement in the activation of transcription factors like NF-kappa B. Arguments will then be developed in favor of the implication of the ROS in the cellular effects of PMA, TNF-alpha and other cytokines on the modulation of the genetic expression. Possible mechanisms will be presented for linking the production of the ROS with cell activation. In a general way we postulate that ROS can play a role of secondary messengers in several cell responses to external stimuli. In the second part of the paper, we will examine the long term influence of ROS and their possible roles in cellular aging. Different links exist between ROS and aging and the relationship between them is probably indirect. We propose to consider the effect of ROS as one of the multiple challenges that cells have to face, the cell being considered as a global system which must optimize its energy expenditure for carrying out its basic functions such as turnover, differentiated phenotype functions, multiplication, defense and repair processes. This thermodynamic point of view will help to understand the effect of low ROS stresses, among others, on accelerated aging.

Protein oxidative damage is associated with life expectancy of houseflies

The objective of this study was to test some of the predictions of the oxidative-stress hypothesis of aging, which postulates that aging is causally associated with the molecular damage inflicted by reactive oxygen species. Protein carbonyl content was used as an index of molecular oxidative modifications. The carbonyl content was found to be associated with the physiological age or life expectancy of flies rather than with their chronological age. Exposure of flies to sublethal hyperoxia (100% oxygen) irreversibly enhanced the carbonyl content of the flies and decreased their rate of oxygen consumption. Results of this study indicate that protein carbonyl content may be a biomarker of aging and support the general concept that oxidative stress may be a causal factor in the aging process.

Relationship between antioxidants, prooxidants, and the aging process

It is argued that reduced oxygen species may be one of the causal factors underlying the aging process. Experimental studies strongly support the view that the rate of metabolism is inversely associated with the rate of aging. It is pointed out that Pearl's rate of living theory is widely misunderstood, because of the mistaken belief that it advocates a fixed metabolic potential for different species or genotypes within a species. The in vivo level of oxidative stress tends to increase with age in insects and mammals as indicated by increased exhalation of alkanes. A search for the causes of this increase revealed that an age-associated decline in antioxidant defenses is neither widespread nor very impressive in magnitude. A comparison of antioxidant defenses (activities of SOD, catalase, and glutathione) in six different mammalian species did not suggest a clear association between these defenses and maximum life span potential of the species. In contrast, mitochondrial rates of O2- and H2O2 were found to increase with age in insects and mammals, and the MLSP of six mammals was found to be inversely correlated with liver mitochondrial rates of O2- and H2O2 generation. It seems that the age-related increase in oxidative stress is mainly due to the enhanced rate of O2- and H2O2 generation. It is hypothesized that variations in the rates of aging in different species, that are otherwise closely related phylogenetically, may be in part due to differences in rates of O2- and H2O2 production. Overall, the rates of oxidant generation are a better correlate of the rates of aging than are the levels of antioxidant defenses.

Lung antioxidant enzymes, peroxidation, glutathione system and oxygen consumption in catalase inactivated young and old Rana perezi frogs

In the lung of Rana perezi no differences as a function of age have been found for any of the five major antioxidant enzymes, reduced (GSH), oxidized (GSSG) or glutathione ratio (GSSG/GSH), oxygen consumption (VO2) and for in vivo or in vitro stimulated tissue peroxidation. This frog shows a moderate rate of oxygen consumption and a life span substantially longer than that of rats and mice. Chronic (2.5 months) catalase depletion in the lung did not affect survival or any additional antioxidant enzyme, GSH, GSSG or in vivo and in vitro lung peroxidation in any age group. Only the GSSG/GSH ratio and the VO2 were elevated in catalase depleted old but not young frogs. After comparison of these results with those obtained in other animal species by other authors we suggest the possibility that decreases in antioxidant capacity in old age be restricted to species with high basal metabolic rates. Nevertheless, scavenging of oxygen radicals can not be 100% effective in any species. Thus, aging can still be due to the continuous presence of small concentrations of O2 radicals in the tissues throughout the life span in animals with either high or low metabolic rates.

Relationship between antioxidant defenses and longevity in different mammalian species

The general objective of this investigation was to examine the relationship between oxygen free radicals and the aging process. Comparisons of antioxidant defenses were made in six different mammalian species, namely, mouse, rat, guinea pig, rabbit, pig and cow, which range from 3.5 to 30 years in their maximum life span potential (MLSP). Activities of superoxide dismutase (SOD), catalase, and glutathione peroxidase, and concentration of glutathione were measured in the liver, the heart, and the brain. SOD and catalase activities were positively correlated whereas glutathione concentration was negatively correlated with MLSP. Glutathione peroxidase activity exhibited a variable pattern: being positively correlated with MLSP in the brain and negatively correlated in the liver and the heart. In each organ, MLSP was correlated with relatively high levels of one or two of the above antioxidants and low levels of the other antioxidants, indicating the possibility of a compensatory balance among various components of the antioxidant system. No obvious pattern of a relationship was detectable between the overall level of antioxidant defenses and MLSP among the mammalian species examined. The implications of this finding concerning the role of oxidative stress in the aging process and the free radical hypothesis of aging are discussed.

Aging-related changes in brain metabolism are altered by early developmental exposure to diazepam

To study the long-term effects of prenatal diazepam (DZ) exposure, 31P NMR (nuclear magnetic resonance) spectra and levels of thiobarbituric acid (TBA)-reactive material were measured in the brains of rats from 3 to 26 months of age. In control rats, there were aging-related increases in levels of TBA-reactive material, decreases in intracellular pH (pHi) and alterations in phosphocreatine (PCr) utilization. Prenatal (late gestational) DZ exposure induced lasting, dose-related and age-related alterations in levels of TBA-reactive material and pHi. The results indicate that the prenatal chemical environment can influence cellular metabolism throughout the lifetime of the organism, and that the process of aging can in turn interact with the consequences of prenatal drug exposure.

Effect of aging on pulmonary superoxide dismutase

Pulmonary Cu,Zn superoxide dismutase was examined in young (1-month-old), adult (4-5-month-old) and aged (24-months-old) rats to determine if partially inactive forms of the enzyme accumulate in the lung with age. Measurement of Cu,Zn superoxide dismutase activity in lung homogenates showed that total Cu,Zn superoxide dismutase activity/mg DNA was essentially the same in adult and aged rats. The average value of Cu,Zn superoxide dismutase/mg DNA for young rats was less than half that of adult and aged rats. Cu,Zn superoxide dismutase was purified from the lung homogenates and fractionated into isoelectric variants by either isoelectric focusing or chromatofocusing. Three main isoelectric variants of Cu,Zn superoxide dismutase were recovered with pI values of 5.15, 4.88 and 4.75. In all age groups studied, the pI 4.88 variant had a markedly higher specific activity than the other two variants, as well as the highest metal content and greatest resistance to inactivation of all three variants. The pI 4.88 variant declined from 88% of the total Cu,Zn superoxide dismutase activity in the young animals to only 70% in the aged animals. The results of this study indicate that the proportion of the relatively inactive forms of pulmonary Cu,Zn superoxide dismutase increased with age.

Oxidative stress as a causal factor in differentiation and aging: a unifying hypothesis

In this article, the authors have pointed out flaws in the current version of the free radical hypothesis of aging and have advanced a new hypothesis that reconciles and encapsulates existing information. The main premise of this hypothesis is that aging is a continuation of development and is thus influenced by genetically programmed phenomena. Completion of various genetic programs and the duration of life are linked to a metabolic potential which is itself a genetically determined sum of energy expenditure. Nevertheless, the rate at which metabolic potential is reached is linked to the rate of metabolism and the level of oxidative stress both of which are influenced by epigenetic stimuli. The current version of the free radical hypothesis postulates that partially reduced oxygen species are produced in aerobic cells in an uncontrolled fashion and do not play any useful physiological function. The principle tenet of the free radical hypothesis is that molecular damage is the underlying cause of aging and that O2- radicals and derivatives induce most of the damage sustained by cells during aging. The authors regard this hypothesis as flawed because it fails to explain either low randomly occurring damage can lead to age-associated changes that are species-specific, or the sequential nature of the changes that occur in aging organisms. In contrast to the free radical hypothesis, our hypothesis can explain the specific and sequential nature of aging-related changes because they are postulated to be neither dependent upon uncontrolled damage nor the cellular capacity to prevent it. Instead, the authors suggest that the damage accumulated during aging is a secondary effect rather than a direct cause of senescence. The authors have shown that cells exert control not only on their level of antioxidant defense but also on their rate of oxidant production. The authors postulate that aging is the terminal stage of development, and as such is influenced genetically. The authors also postulate that a definite sum of energy is required to complete the genetic programs associated with aging. Thus, the rate of aging is linked to the level of oxidative stress; the rate of energy utilization is postulated to determine the level of oxidative stress. Oxidative stress is one of the factors which appears to govern changes in gene expression during differentiation and we suggest that it causes alterations in gene expression during aging. In the authors revised hypothesis, free radicals promote aging by affecting specific genetic programs and the incidental damage they inflict in cells is only a by-product of this process.(ABSTRACT TRUNCATED AT 400 WORDS)

Age-related changes in antioxidant enzymes and prooxidant generation in tissues of the rat with special reference to parameters in two insect species

The objective of this study was to explore the relationship between partially reduced oxygen species and the aging process. Effect of age on antioxidant defenses and prooxidant generation was evaluated by comparing the activities of superoxide dismutase, catalase, glutathione peroxidase and glutathione reductase, and rates of mitochondrial O-2 and H2O2 generation in the liver, heart, and brain of 3-month and 18-month-old Sprague-Dawley rats. In addition, comparisons of antioxidant defenses and mitochondrial prooxidant generation were made between short-lived insects and the rat tissues. Results indicated that antioxidant enzymes exhibit a mixed pattern of age-related alterations. In each organ of the rat examined, activities of some enzymes were up with age and of others down with age. The overall magnitude of decline in antioxidant defenses observed here and elsewhere in the literature was deemed to be unlikely to be functionally significant. In contrast, the rate of mitochondrial O-2 and H2O2 generation increased in various tissues of the rat. Antioxidant defenses in insects were comparable to tissues in the rat but rates of O-2 and H2O2 generations were notably higher. Results are interpreted to suggest that rates of prooxidant generation may be more crucial than antioxidant levels as possible longevity determinants.

Relationship between life expectancy and endogenous DNA single-strand breakage, strand break induction and DNA repair capacity in the adult housefly, Musca domestica

The objective of this study was to investigate the relationship between genomic damage and the physiological rate of aging. Endogenous DNA single-strand breaks, susceptibility of DNA to exogenously induced strand breaks and the capacity to repair strand breakage were compared, using the alkaline elution technique, in flies of the same chronological age but with different life expectancy. Distinctions between physiological and chronological ages were made (1) by experimentally altering the life spans of houseflies by varying the level of physical activity, and (2) by phenotypic selection of short- and long-lived cohorts from the same population. The degree of endogenous DNA single-strand breaks was found to be unrelated to physiological age. However, flies selected for relatively shorter life expectancy exhibited a greater susceptibility to exogenously-induced (gamma-irradiation) single-strand breakage. Flies with a longer life expectancy exhibited a more efficient repair capacity to reverse single-strand breakage than those with a shorter life expectancy.

Review of genetic investigations into the aging processes of Drosophila

The field has progressed to the point where a genetic investigation of the aging processes in Drosophila can be viewed as constituting both a serious and a feasible research program. There now exists at least one single gene mutant which yields an accelerated aging phenotype, at least two single gene null mutants affecting enzymes implicated in regulating the aging process and resulting in premature death, and at least two strains created by artificial selection which produce extended-longevity phenotypes. In addition, genes such as adh have an indirect and interactive effect upon the animal's longevity and might also play an important role in the genetic regulation of this process. Although far from complete, some essential tools are now in place and are being used to answer some of the questions posed by Martin. Of the several theories put forth to explain aging in Drosophila, it appears as if the data best uphold the free radical and the protein synthesis/gene expression theories. It is entirely possible that these two theories are complementary aspects of a broader underlying process. The genetic mechanisms controlling these physiological processes clearly do so in concert with certain environmental factors. The net effect of their interactions may be the decreased synthetic and repair ability of the cell as suggested by Lamb and by Webster. It is probably true that aging and longevity are multicausal phenotypes. Our only hope of understanding such a complex phenotype is to dissect it genetically, one (or a few) genes at a time under rigidly controlled conditions. Thorough genetic description of each system will be the prerequisite to their molecular analysis. This will likely result in multiple explanations, ideally one for each system. Yet these multiple molecular genetic explanations may well enable us to see some commonality underlying the aging process in this organism. The fact that several different lines of evidence appear to be converging on a small number of theoretical explanations is an encouraging sign. We should also be heartened by the extraordinary increase in our knowledge of embryonic development in Drosophila as a result of just such a strategy. And we should not forget that the homeotic mutants which now play such a large role in the deciphering of embryogenesis were once classified as "complex loci" and that the then-accepted explanations gave no hint of the underlying molecular relationships. For now it is fair to conclude that aging in Drosophila may be viewed as a genetically-determined, environmentally-modulated, event-dependent process.(ABSTRACT TRUNCATED AT 400 WORDS)

Evaluation of average life span of epithelial and stromal cells of human prostate by superoxide dismutase activity

Little is known about the cell kinetics on which development of benign prostatic hyperplasia is based. This prompted us to study the superoxide dismutase (SOD) activity, which is known 1) to correlate with the life span of cells and 2) to decrease with advancing age of cells. Therefore, SOD was measured in epithelium and stroma of the human prostate from patients of various ages (20-86 years) and compared with the activity in the postmitotic skeletal muscle. It was found that the highest mean specific SOD activity is present in skeletal muscle (4.0 mU.mg protein-1), followed by the stroma (2.1 mU.mg protein-1) and epithelium (1.4 mU.mg protein-1). Similar results were obtained when SOD activity was expressed per DNA (5.03, 1.73, and 0.16 mU.micrograms DNA-1, respectively). Comparing the slope of the age-dependent regression lines, it was demonstrated that the slope of the stroma is much closer to the slope of the postmitotic skeletal muscle than the slope of the epithelium. From the data, it was calculated that the average life span of stromal cells is probably longer than 30 years and of epithelial cells longer than 2 years. Hence in human prostatic tissue the average cell death rate might be rather low.

Strategies and criteria for the development of molecular biomarkers of senescence

While it may be possible to employ panels of molecular parameters which correlate with senescence in vivo or in vitro, in a manner analogous to the use of mutagenesis assays for economic carcinogen screening, such an endeavor would at present be impeded by the absence of a clear mechanistic rationale for focusing on particular biomarkers, and by the complexity of the senescent phenotype and its multilevel interactions. Nevertheless, insight into the mechanism(s) of senescence may derive indirectly from correlative studies, or directly from strategies of molecular intervention, provided that such studies meet reasonable criteria for relevance and functionality. Even the control of expression of a single gene may be quite complex, with multigenic interactions and the potential to produce a cascade affecting many downstream genes. In order to understand such processes, functional assays and selective systems will need to be developed.

Metabolic rates in genetically based long lived strains of Drosophila

The goal of these experiments was to determine if the increased longevity characteristics of our genetically selected long lived line of Drosophila could be attributed to metabolic differences. The data shows an inverse relationship between life span and temperature for both the long lived (L) and normal (R) strains; however, the higher longevity of the L strain relative to the R strain is not affected by these treatments. Therefore, the genetic factors unique to the L strain do not affect the same processes affected by the temperature treatments. A second set of experiments detected a linear relationship between the MDMR (mean daily metabolic rate) and the ambient adult temperature. However, at each temperature, the MDMR of either strain was statistically equivalent; a finding which demonstrates that an increased life span depends on something other than conservation of calories. A third set of experiments looked at the metabolic efficiency of the two strains and were not able to detect any statistically significant differences. The two strains appear to expend approximately equivalent numbers of calories per day in an approximately equivalent manner. These data are interpreted in the context both of a previously postulated genetic switch mechanism believed responsible for initiating the onset of senescence, and of contemporary reinterpretations of the "rate of living" theory which implicates the essential role of various anti-oxidant defense systems.

Effect of hydrogen peroxide administration on life span, superoxide dismutase, catalase, and glutathione in the adult housefly, Musca domestica

The general objective of this study was to further elucidate the relationship between oxidative stress and the aging process. H2O2 is known to be a progenator of reactive oxygen species, such as hydroxyl free radical, by various mechanisms involving, among others, a superoxide anion radical-driven Fenton cycle, or splitting of the 0-0 bond by hemoproteins. Effects of H2O2 administration on life span, activities of superoxide dismutase, catalase, concentrations of endogenous H2O2, and glutathione in the housefly are described. Adult male flies were given various concentrations of H2O2, ranging from 0 to 100 mM H2O2, in their drinking water. Life span was shortened by H2O2 intake except in 10 mM H2O2 administrated flies, which exhibited the longest life span. Flies administered 10 mM H2O2 also contained the highest concentration of reduced glutathione (GSH). Superoxide dismutase and catalase activities were not affected by H2O2 intake. Compensatory elevation in GSH may be responsible for the increase in life span observed in 10 mM H2O2 administered flies.

Correlates of longevity in two strains of the housefly, Musca domestica

The general objective of this study was to identify biochemical correlates of longevity in the housefly by comparing two strains of flies that have different longevities. The average and the maximum life spans of the longer-lived "Cambridge" strain flies were 46% and 23%, respectively, greater than the shorter-lived "Thuron" strain flies. The hypothesis that longer-lived organisms have relatively more efficient mechanisms to minimize oxidative stress and maintain a relatively more reduced redox potential was tested. All measurements were made on 8-day-old male flies maintained under identical conditions. Flies of the longer-lived strain had a lower metabolic rate and contained lesser amounts of H2O2 and thiobarbituric acid-reactants than the flies of the shorter-lived strain. Reduced glutathione concentration and activities of catalase, glutathione reductase and thioltransferase were higher in the longer-lived strain indicating that longer-lived flies manifest lower levels of oxidative stress and greater ability to maintain a relatively more reducing environment than the shorter-lived flies. Superoxide dismutase (SOD) activity was similar in the two strains, but the SOD/metabolic rate ratio was higher in the longer-lived strain. Total activity of glutathione S-transferases was comparable in the two strains suggesting that differences in detoxification ability are not correlated with longevity. Only S-glutamylcysteine synthetase activity was greater in the shorter-lived strain suggesting that variation in longevity is not due to reduction in the ability to synthesize GSH. Overall, the results support the view that parameters associated with oxidative stress play a role in the aging process of the houseflies.

Age-related changes in the redox status of the housefly, Musca domestica

The objective of this study was to further test the hypothesis that aging in the housefly is associated with increased oxidative stress. Age-related changes in the concentration of glutathione, NAD and NADP, which undergo oxidation-reduction reactions, and of H2O2, a potent cellular oxidant, were examined in the homogenates of adult male houseflies at 4, 8, 12 and 16 days of age. Sixteen days of age represents the beginning of the dying phase of the population when about 20% mortality usually occurs. Results indicate that the ratios of reduced/oxidized forms decline with age; H2O2 concentration steadily increases with age. Results suggest that the intracellular redox potential of the housefly becomes progressively more pro-oxidizing or less reducing during the aging process.

Correlation between life expectancy, flightlessness and actomyosin adenosine triphosphatase activity in the housefly, Musca domestica

The objective of this investigation was to determine if actomyosin ATPase activity in flight muscles is correlated with life expectancy of houseflies. All houseflies lose flying ability before death which permits the identification of shorter-lived flightless 'crawlers' from their longer-lived cohorts, the 'fliers'. Life expectancy of crawlers is about one-third shorter than that of the fliers. Flying performance of houseflies, as measured by the total duration of flying activity during 1 h periods, average duration of flights and the number of rest stops, was highest at 4 days of age and declined thereafter. Actomyosin ATPase activity was higher in the fliers than in the crawlers of the same age. Abolition of flight, by surgical removal of wings at 1 day of age, had no effect on the enzyme activity. Results are interpreted to suggest that actomyosin ATPase activity is correlated with physiological rather than chronological age of flies.