Glutathione,oxidative stress and aging

The free radical theory of aging proposes that the impairment in physiological performance associated with aging is caused by the detrimental effects of oxygen free radicals. This is interesting because it provides us with a theoretical framework to understand aging and because it suggests a rationale for intervention, i.e., antioxidant administration. Thus, the study of antioxidant systems of the cell may be very important in gerontological studies. Glutathione is one of the main nonprotein antioxidants in the cell which, together with its related enzymes, constitute the “glutathione system.” The involvement of glutathione in aging has been known since the early seventies. Several studies have reported that reduced glutathione is decreased in cells from old animals, whereas oxidized glutathione tends to be increased. Recent experiments from our laboratory have underscored the importance of cellular compartmentation of glutathione. Mitochondrial glutathione plays a key role in the protection against free radical damage associated with aging. Oxidative damage to mitochondrial DNA is directly related to an oxidation of mitochondrial glutathione. In fact, aging is associated with oxidative damage to proteins, nucleic acids, and lipids. These molecular lesions may be responsible for the low physiological performance of aged cells. Thus, antioxidant supplementation may be a rational way to partially protect against age-associated impairment in performance. Apoptosis, a programmed cell death, is an area of research which has seen an explosive growth. Glutathione is involved in apoptosis: apoptotic cells have lower levels of reduced glutathione, and administration of glutathione precursors prevent, or at least delay, apoptosis. Age-associated diseases constitute a major concern for researchers involved in aging. Free radicals are involved in many such diseases; for instance, cancer, diabetes or atherosclerosis. The key role of glutathione and other antioxidants in the pathophysiology of aging and age-associated diseases is discussed in this review.     

Cyclic GMP protects endothelial progenitors from oxidative stress

Endothelial progenitor cells (EPCs) play a critical role in the repair of damaged blood vessels and/or in the growth of new ones in ischemic tissues. Elevated levels of oxygen radicals, which accumulate in the ischemic tissue, could compromise the angiogenic potential of EPCs. To determine if oxidative stress alters the angiogenic response of EPCs and to identify possible cellular targets that protect EPCs from the damaging effects of oxidative stress, we have investigated vascular development in embryonic bodies (EBs) under hyperoxic conditions. Murine EBs at differentiaton day 2 were cultured for 3 days under normoxic (21% O₂) or hyperoxic (60% O₂) conditions. Hyperoxic EBs showed a moderate reduction in Pecam-1, Vegfr-2, eNOS and Tie2 mRNA levels compared to normoxic EBs. However, immunostaining of hyperoxic EBs with antibodies against PECAM-1 after 1 week recovery at room air revealed a defective vasculature completely deficient in branches, while normoxic EBs developed a normal vascular plexus. Oxygen-induced defective vascular development correlated with a dramatic decrease in soluble guanylyl cyclase, phosphodiesterase (Pde) 4B and Pde4C mRNAs. Oxidative stress did not affect the expression of adenylyl cyclase 6 and Pde5. The abnormal vascular development caused by hyperoxia was reverted by pharmacological treatments that increased cGMP levels, such as 8-bromo-cGMP or 4-{[3′,4′-(methylenedioxy)benzyl]amino}-6-methoxyquinazoline, a specific inhibitor of PDE5. These results indicated that oxidative stress inhibits vascular development from EPCs through its effects on levels of cyclic nucleotides and suggested that therapies that target cyclic nucleotide turnover may be useful in protecting vascular repair under oxidative conditions.     

Long-term smoking and ethanol exposure accentuates oxidative stress in hearts of mice

The present study was undertaken to investigate the influence of ethanol on the cardiac antioxidant defense system of mice exposed to cigarette snoke. Cigarette smoke exposure for 10 wk led to an increase in the levels of lipid peroxidation in the heart. These levels increased further in animals co-exposeds to ethanol and cigarette, smoke. Concomitantly, the levels of glutathione were found to decrease after cigarette smoke exposure. In the animals co-exposed to ethanol and cigarette smoke, there was a further decrease in glutathione levels. Catalase activity increased in the animal sexposed to cigarette smoke; this activity increased further with combined exposed to cigarette smoke and ethanol. On the other hand, superoxide dismutase (SOD) activity was not affected by cigarette smoke exposure, while it increased in the ethanol-exposed group. SOD activity was higher in the hearts of animals co-exposed to cigarette smoke and ethanol as compared to animals that received ethanol alone. The actvity of heat-stable lactate dehydrogenase in serum was not affected when the animals were exposed to either cigarette smoke or ethanol, whereas this activity was observed to be, elevated in animals co-exposed to cigarette smke and ethanol. It appears from these results that ethanol potentates the cigarette-smoke-induced peroxidative damage to heart.     

Senescence marker protein 30 functions as gluconolactonase in L-ascorbic acid biosynthesis, and its knockout mice are prone to scurvy

We originally identified senescence marker protein 30 (SMP30) as a distinctive protein whose expression decreases in an androgen-independent manner with aging. Here, we report its sequence homology found in two kinds of bacterial gluconolactonases (GNLs) by using the blast search. Then, through a biochemical study, we identify SMP30 as the lactone-hydrolyzing enzyme GNL of animal species. SMP30 purified from the rat liver had lactonase activity toward various aldonolactones, such as d- and l-glucono-delta-lactone, d- and l-gulono-gamma-lactone, and d- and l-galactono-gamma-lactone, with a requirement for Zn(2+) or Mn(2+) as a cofactor. Furthermore, in SMP30 knockout mice, no GNL activity was detectable in the liver. Thus, we conclude that SMP30 is a unique GNL in the liver. The lactonase reaction with l-gulono-gamma-lactone is the penultimate step in l-ascorbic acid (AA) biosynthesis, and the essential role of SMP30 in this synthetic process was verified here by a nutritional study using SMP30 knockout mice. These knockout mice (n = 6), fed a vitamin C-deficient diet, did not thrive; i.e., they displayed symptoms of scurvy such as bone fracture and rachitic rosary and then died by 135 days after the start of receiving the deficient diet. The AA levels in their livers and kidneys at the time of death were <1.6% of those in WT control mice. In addition, by using the SMP30 knockout mouse, we demonstrate that the alternative pathway of AA synthesis involving d-glucurono-gamma-lactone operates in vivo, although its flux is fairly small.     

Epimorphin protects hepatocytes from oxidative stress by inhibiting mitochondrial injury

Background and Aims: Many investigations have demonstrated that cell injuries caused by generation of reactive oxygen species (ROS) is a common mechanism of various hepatic disorders. Recently, we have demonstrated that epimorphin, originally cloned as a mesenchymal protein, protects cultured intestinal epithelial cells from ROS. We therefore examine whether epimorphin protects primary cultured hepatocytes from ROS‐induced cell injury. Methods: We explored the cell viability and the intracellular ROS levels of purified murine hepatocytes after exposure to 0.5 mM H₂O₂ with or without pretreatment of epimorphin. Then, we observed mitochondrial permeability transition (MPT) and depolarization using confocal microscopy to make clear the mechanism that epimorphin inhibited cell injuries after exposure to H₂O₂. In addition, to clarify the signaling pathways related to cell survival, we carried out Western blotting analysis with phosphorylated stress‐activated protein kinase/c‐Jun N‐terminal kinase (SAPK/JNK) polyclonal antibody to evaluate the inhibition of JNK by epimorphin. Finally, we evaluated the cell viability in hepatocytes administered JNK inhibitor. Results: Epimorphin protected primary cultured hepatocytes from H₂O₂‐induced cell injuries independent of intracellular ROS levels. Epimorphin also inhibited onset of MPT, depolarization of the mitochondrial membrane potential, and eventually cell killing. The cell protective function of epimorphin after exposure to H₂O₂ was not dependent on Akt signaling but on JNK signaling. Conclusion: Epimorphin can protect hepatocytes from MPT‐dependent cell injury induced by ROS. Since hepatic disorders could be caused by MPT‐dependent cell injuries with excessive ROS, epimorphin might open a new therapeutic avenue for hepatic disorders.     

Mitochondria and oxidative stress in heart aging

As average lifespan of humans increases in western countries, cardiac diseases become the first cause of death. Aging is among the most important risk factors that increase susceptibility for developing cardiovascular diseases. The heart has very aerobic metabolism, and is highly dependent on mitochondrial function, since mitochondria generate more than 90 % of the intracellular ATP consumed by cardiomyocytes. In the last few decades, several investigations have supported the relevance of mitochondria and oxidative stress both in heart aging and in the development of cardiac diseases such as heart failure, cardiac hypertrophy, and diabetic cardiomyopathy. In the current review, we compile different studies corroborating this role. Increased mitochondria DNA instability, impaired bioenergetic efficiency, enhanced apoptosis, and inflammation processes are some of the events related to mitochondria that occur in aging heart, leading to reduced cellular survival and cardiac dysfunction. Knowing the mitochondrial mechanisms involved in the aging process will provide a better understanding of them and allow finding approaches to more efficiently improve this process.     

Reproductive protein protects functionally sterile honey bee workers from oxidative stress

Research on aging shows that regulatory pathways of fertility and senescence are closely interlinked. However, evolutionary theories on social species propose that lifelong care for offspring can shape the course of senescence beyond the restricted context of reproductive capability. These observations suggest that control circuits of aging are remodeled in social organisms with continuing care for offspring. Here, we studied a circuit of aging in the honey bee (Apis mellifera). The bee is characterized by the presence of a long-lived reproductive queen caste and a shorter-lived caste of female workers that are life-long alloparental care givers. We focus on the role of the conserved yolk precursor gene vitellogenin that, in Caenorhabditis elegans, shortens lifespan as a downstream element of the insulin/insulin-like growth factor signaling cascade. Vitellogenin protein is synthesized at high levels in honey bee queens and is abundant in long-lived workers. We establish that vitellogenin gene activity protects worker bees from oxidative stress. Our finding suggests that one mechanistic explanation for patterns of longevity in bees is that a reproductive regulatory pathway has been remodeled to extend life. This perspective is of considerable relevance to research on longevity regulation that builds largely on inference from solitary model species.     

Acute vincristine pretreatment protects adult mouse cardiac myocytes from oxidative stress

Vincristine is a chemotherapeutic agent that disrupts microtubules. We noted that paclitaxel (Taxol), which stabilizes microtubules, protected cultured adult mouse cardiac myocytes from oxidative stress induced by H(2)O(2). We hypothesized that vincristine, which disrupts microtubules, should have the opposite effect. To our surprise, we found that pretreatment with concentrations of vincristine ranging from 30 to 120 micromol/L for 60 min preserved myocyte viability and morphology after incubation with 30 micromol/L of H(2)O(2) for 35 min as measured by trypan blue exclusion. The cardioprotective effects of vincristine were also observed during prolonged hypoxia. With continuous exposure to vincristine, survival lasted for as long as 24 h, but longer periods of exposure up to 42 h resulted in extensive cell death. Despite microtubule disruption evidenced on deconvolution microscopy, vincristine activated a prosurvival pathway resulting in increased phosphorylation of Akt, ERK and GSK-3beta and in reduced cytochrome C release into the cytosol. Pharmacological inhibitors of Akt and Erk attenuated the cardioprotective effect of vincristine. We conclude that short-term pretreatment with vincristine exerts dramatic protective effects in cultured adult mouse myocytes subjected to acute oxidative stress. Despite causing microtubule disruption, vincristine initiates a prosurvival signaling pathway. As vincristine and doxorubicin are often used in conjunction to treat patients, it is possible that vincristine could be used to modify the cardiotoxicity of doxorubicin.     

Effects of a growth hormone-releasing hormone antagonist on telomerase activity, oxidative stress, longevity, and aging in mice

Both deficiency and excess of growth hormone (GH) are associated with increased mortality and morbidity. GH replacement in otherwise healthy subjects leads to complications, whereas individuals with isolated GH deficiency such as Laron dwarfs show increased life span. Here, we determined the effects of treatment with the GH-releasing hormone (GHRH) receptor antagonist MZ-5-156 on aging in SAMP8 mice, a strain that develops with aging cognitive deficits and has a shortened life expectancy. Starting at age 10 mo, mice received daily s.c. injections of 10 μg/mouse of MZ-5-156. Mice treated for 4 mo with MZ-5-156 showed increased telomerase activity, improvement in some measures of oxidative stress in brain, and improved pole balance, but no change in muscle strength. MZ-5-156 improved cognition after 2 mo and 4 mo, but not after 7 mo of treatment (ages 12, 14 mo, and 17 mo, respectively). Mean life expectancy increased by 8 wk with no increase in maximal life span, and tumor incidence decreased from 10 to 1.7%. These results show that treatment with a GHRH antagonist has positive effects on some aspects of aging, including an increase in telomerase activity.     

Daily melatonin protects the endothelial lineage and functional integrity against the aging process,oxidative stress,and toxic environment and restores blood flow in critical limb ischemia area in mice

We tested the hypothesis that daily melatonin treatment protects endothelial lineage and functional integrity against the aging process, oxidative stress/endothelial denudation (ED), and toxic environment and restored blood flow in murine critical limb ischemia (CLI). In vitro study using HUVECs, in vivo models (ie, CLI through left femoral artery ligation and ED through carotid artery wire injury), and model of lipopolysaccharide‐induced aortic injury in young (3 months old) and aged (8 months old) mice were used to elucidate effects of melatonin treatment on vascular endothelial integrity. In vitro study showed that menadione‐induced oxidative stress (NOX‐1/NOX‐2), inflammation (TNF‐α/NF‐kB), apoptosis (cleaved caspase‐3/PARP), and mitochondrial damage (cytosolic cytochrome c) in HUVECs were suppressed by melatonin but reversed by SIRT3‐siRNA (all P < .001). In vivo, reduced numbers of circulating endothelial progenitor cells (EPCs) (C‐kit/CD31+/Sca‐1/KDR+/CXCR4/CD34+), and angiogenesis (Matrigel assay of bone marrow‐derived EPC and ex vivo aortic ring cultures) in older (compared with younger) mice were significantly reversed through daily melatonin administration (20 mg/kg/d, ip) (all P < .001). Aortic vasorelaxation and nitric oxide release were impaired in older mice and reversed in age‐match mice receiving melatonin (all P < .01). ED‐induced intimal/medial hyperplasia, reduced blood flow to ischemic limb, and angiogenesis (reduced CD31+/vWF+ cells/small vessel number) were improved after daily melatonin treatment (all P < .0001). Lipopolysaccharide‐induced aortic endothelial cell detachment, which was more severe in aged mice, was also alleviated after daily melatonin treatment (P < .0001). Daily melatonin treatment protected both structural and functional integrity of vascular endothelium against aging‐, oxidative stress‐, lipopolysaccharide‐, and ischemia‐induced damage probably through upregulating the SIRT signaling pathway.     

Decreased senescence marker protein-30 could be a factor that contributes to the worsening of glucose tolerance in normal aging

In our recent paper, we proposed that senescence marker protein-30 (SMP30) could be a novel molecule which was involved in an impairment of β-cell function with aging. SMP30 knockout (KO) mice and wild-type (WT) mice were fed a standard diet (SD) or a high fat diet (HFD) for 8 weeks from 7 weeks of age. In an intraperitoneal glucose tolerance test at 15 weeks of age, blood glucose levels in SD-fed KO mice were significantly increased by 25% at 30 min after glucose administration compared to SD-fed WT mice. Insulin levels in SD-fed KO mice were significantly decreased by 37% at 30 min postglucose compared to SD-fed WT mice. Interestingly, an insulin tolerance test showed a greater glucose lowering effect in SD-fed KO mice. Morphometric analysis revealed no differences in the degree of HFD-induced compensatory increase in β-cell mass and proliferation. Collectively, these data indicate that impairment of the early phase of insulin secretion underlies glucose intolerance in KO mice. Decreased SMP30 may contribute to the worsening of glucose tolerance that occurs in normal aging.     

Decreased senescence marker protein-30 could be a factor that contributes to the worsening of glucose tolerance in normal aging

In our recent paper, we proposed that senescence marker protein-30 (SMP30) could be a novel molecule which was involved in an impairment of β-cell function with aging. SMP30 knockout (KO) mice and wild-type (WT) mice were fed a standard diet (SD) or a high fat diet (HFD) for 8 weeks from 7 weeks of age. In an intraperitoneal glucose tolerance test at 15 weeks of age, blood glucose levels in SD-fed KO mice were significantly increased by 25% at 30 min after glucose administration compared to SD-fed WT mice. Insulin levels in SD-fed KO mice were significantly decreased by 37% at 30 min postglucose compared to SD-fed WT mice. Interestingly, an insulin tolerance test showed a greater glucose lowering effect in SD-fed KO mice. Morphometric analysis revealed no differences in the degree of HFD-induced compensatory increase in β-cell mass and proliferation. Collectively, these data indicate that impairment of the early phase of insulin secretion underlies glucose intolerance in KO mice. Decreased SMP30 may contribute to the worsening of glucose tolerance that occurs in normal aging.     

Hepatic and renal expression of senescence marker protein-30 and its biological significance

A novel rat hepatic protein was detected and isolated, the amount of which is down-regulated in an androgen-independent manner with ageing. This protein was designated as senescence marker protein-30 (SMP30). Senescence marker protein-30 turned out to be identical to a hepatic calcium-binding protein called regucalcin (RC). This review gives an overview of SMP30 in its structure, expression and possible physiological function(s). A hypothetical role of SMP30 in ageing and calcium homeostasis is also discussed.     

Treatment with pravastatin attenuates oxidative stress and protects osteoblast cell viability from indoxyl sulfate

Chronic kidney disease has a high level of oxidative stress, a phenomenon that is induced, at least in part, by the accumulation of uremic toxins. Several reports have revealed that indoxyl sulfate, one of the uremic toxins, accelerates oxidative stress in chronic kidney disease. On the other hand, it is also well known that statins have pleiotropic effects; however, it still remains unclear whether statins suppress osteoblastic cell dysfunction or cytotoxicity induced by uremic toxins. To elucidate whether statins ameliorate osteoblast dysfunction induced by uremic toxins, we conducted an in vitro study using primary cultured osteoblastic cells from mouse calvariae. Indoxyl sulfate induced reactive oxygen species production and reduced cell viability in osteoblastic cells in a dose dependent manner. The addition of pravastatin suppressed reactive oxygen species production and ameliorated cell viability. These data suggest that pravastatin attenuates oxidative stress and protects osteoblastic cell viability from indoxyl sulfate.