Long-term sulforaphane-treatment restores redox homeostasis and prevents cognitive decline in middleaged female and male rats, but cannot revert previous damage in old animals.

Aging is a complex and detrimental process, which disrupts most organs and systems within the organisms. The nervous system is morphologically and functionally affected during normal aging, and oxidative stress has been involved in age-related damage, leading to cognitive decline and neurodegenerative processes. Sulforaphane (SFN) is a hormetin that activates the antioxidant and anti-inflammatory responses. So, we aimed to evaluate if SFN long-term treatment was able to prevent age-associated cognitive decline in adult and old female and male rats. Memory was evaluated in adult (15-month-old), and old (21-month-old) female and male Wistar rats after three months of SFN treatment. Young rats (4-month-old) were used as age controls. The antioxidant response induction, the redox state (GSH/GSSG), and oxidative damage were determined in the brain cortex (Cx) and hippocampus (Hc). Our results showed that SFN restored redox homeostasis in the Cx and Hc of adult rats, thus preventing cognitive decline in both sexes; however, the redox responses were not the same in males and females. Old rats were not able to recover their redox state as adults did, but they had a mild improvement. These results suggest that SFN mainly prevents rather than reverts neural damage; though, there might also be a range of opportunities to use hormetins like SFN, to improve redox modulation in old animals.

Sensory and memory processing in old female and male Wistar rat brain, and its relationship with the cortical and hippocampal redox state.

The brain is one of the most sensitive organs damaged during aging due to its susceptibility to the aging-related oxidative stress. Hence, in this study, the sensory nerve pathway integrity and the memory were evaluated and related to the redox state, the antioxidant enzymes function, and the protein oxidative damage in the brain cortex (Cx) and the hippocampus (Hc) of young (4-month-old) and old (24-month-old) male and female Wistar rats. Evoked potentials (EP) were performed for the auditory, visual, and somatosensory pathways. In both males and females, the old rat groups' latencies were larger in almost all waves when compared to the young same-sex animals. The novel object test was performed to evaluate memory. The superoxide dismutase and catalase antioxidant activity, as well as the protein oxidative damage, and the redox state were evaluated. Magnetic resonance (MR) imaging was used to obtain the diffusion tensor imaging, and the brain volume, while MR spectroscopy was used to obtain the brain metabolite concentrations (glutamine, glutamate, Myo-inositol, N-acetyl-aspartate, creatine) in the Cx and the Hc of young and old females. Our data suggest that, although there are limited variations regarding memory and nerve conduction velocity by sex, the differences concerning the redox status might be important to explain the dissimilar reactions during brain aging between males and females. Moreover, the increment in Myo-inositol levels in the Hc of old rats and the brain volume decrease suggest that redox state alterations might be correlated to neuroinflammation during brain aging.

Some naturally occurring compounds that increase longevity and stress resistance in model organisms of aging.

Humans and other organisms show age-related signs of deterioration, which makes aging an interesting process to study. In the present work, we review the anti-aging evidence of several of the most promising natural compounds. Quercetin, rapamycin, resveratrol, spermidine, curcumin or sulforaphane administration increase longevity and stress resistance in model organisms such as yeasts, nematodes, flies and mice. Even more, rapamycin, resveratrol, and curcumin are currently in preclinical tests on the Interventions Testing Program of the National Institute on Aging due to their encouraging results in model organisms. The potential mechanisms underlying the beneficial effects of these compounds are briefly described.

New considerations on hormetic response against oxidative stress.

In order to survive living organisms have developed multiple mechanisms to deal with tough environmental conditions. Hormesis is defined as a process in which exposure to a low dose of a chemical agent or environmental factor that is damaging at higher doses induces an adaptive beneficial effect on the cell or organism. In this paper, we examine several ideas that might be taken into consideration before using hormesis as a therapeutic tool to improve health and life span, and hopefully will open the discussion for new and interesting debates regard hormesis. The first one is to understand that the same stressor or inductor can activate different pathways in a parallel or dual response, which might lead to diverse outcomes. Another idea is related to the mechanisms involved in activating Nrf2, which might be different and have diverse hormetic effects.Last, we discuss mild oxidative stress in association to low-grade chronic inflammation as a stimulating avenue to be explored and the unexpected effects proposed by the obesity paradox theory. All the previous might help to clarify the reasons why centenarians are able to reach the extreme limits of human life span, which could probably be related to the way they deal with homeostasis maintenance, providing an opportunity for hormesis to intervene significantly.

Biochemical alterations during the obese-aging process in female and male monosodium glutamate (MSG)-treated mice.

Obesity, from children to the elderly, has increased in the world at an alarming rate over the past three decades, implying long-term detrimental consequences for individual's health. Obesity and aging are known to be risk factors for metabolic disorder development, insulin resistance and inflammation, but their relationship is not fully understood. Prevention and appropriate therapies for metabolic disorders and physical disabilities in older adults have become a major public health challenge. Hence, the aim of this study was to evaluate inflammation markers, biochemical parameters and glucose homeostasis during the obese-aging process, to understand the relationship between obesity and health span during the lifetime. In order to do this, the monosodium glutamate (MSG) obesity mice model was used, and data were evaluated at 4, 8, 12, 16 and 20 months in both female and male mice. Our results showed that obesity was a major factor contributing to premature alterations in MSG-treated mice metabolism; however, at older ages, obesity effects were attenuated and MSG-mice became more similar to normal mice. At a younger age (four months old), the Lee index, triglycerides, total cholesterol, TNF-α and transaminases levels increased; while adiponectin decreased and glucose tolerance and insulin sensitivity levels were remarkably altered. However, from 16 months old-on, the Lee index and TNF-α levels diminished significantly, while adiponectin increased, and glucose and insulin homeostasis was recovered. In summary, MSG-treated obese mice showed metabolic changes and differential susceptibility by gender throughout life and during the aging process. Understanding metabolic differences between genders during the lifespan will allow the discovery of specific preventive treatment strategies for chronic diseases and functional decline.

Cell proliferation arrest and redox state status as part of different stages during senescence establishment in mouse fibroblasts.

Senescence phenotype can be achieved by multiple pathways. Most of them involve the activation of negative cell cycle regulators as well as a shift to an oxidative status. However, the exact participation of these events in senescence establishment and maintenance is not completely understood. In this study we investigated the content of three final cell cycle regulators, as well as the redox state in some critical points during the pre-senescent and the full-senescent states. Our results highlight the existence of a critical pre-phase in senescent phenotype establishment, in which cell proliferation stops with the participation of the cell cycle inhibitors, and a second maintenance stage where the exacerbated pro-oxidant state inside the cell induces the physiological decline characteristic in senescent cells.

Bcl-2 overexpression in hepatic stellate cell line CFSC-2G, induces a pro-fibrotic state.

BACKGROUND AND AIM: Development of hepatic fibrosis is a complex process that involves oxidative stress (OS) and an altered balance between pro- and anti-apoptotic molecules. Since Bcl-2 overexpression preserves viability against OS, our objective was to address the effect of Bcl-2 overexpression in the hepatic stellate cells (HSC) cell-line CFSC-2G under acetaldehyde and H(2)O(2) challenge, and explore if it protects these cells against OS, induces replicative senescence and/or modify extracellular matrix (ECM) remodeling potential. METHODS: To induce Bcl-2 overexpression, HSC cell line CFSC-2G was transfected by lipofection technique. Green fluorescent protein-only CFSC-2G cells were used as a control. Cell survival after H(2)O(2) treatment and total protein oxidation were assessed. To determine cell cycle arrest, proliferation-rate, DNA synthesis and senescence were assessed. Matrix metalloproteinases (MMP), tissue-inhibitor of MMP (TIMP), transglutaminases (TG) and smooth muscle a-actin (alpha-SMA) were evaluated by western blot in response to acetaldehyde treatment as markers of ECM remodeling capacity in addition to transforming growth factor-beta (TGF-beta) mRNA. RESULTS: Cells overexpressing Bcl-2 survived approximately 20% more than control cells when exposed to H(2)O(2) and approximately 35% proteins were protected from oxidation, but Bcl-2 did not slow proliferation or induced senescence. Bcl-2 overexpression did not change alpha-SMA levels, but it increased TIMP-1 (55%), tissue transglutaminases (tTG) (25%) and TGF-beta mRNA (49%), when exposed to acetaldehyde, while MMP-13 content decreased (47%). CONCLUSIONS: Bcl-2 overexpression protected HSC against oxidative stress but it did not induce replicative senescence. It increased TIMP-1, tTG and TGF-beta mRNA levels and decreased MMP-13 content, suggesting that Bcl-2 overexpression may play a key role in the progression of fibrosis in chronic liver diseases.

Bcl-2 sustains hormetic response by inducing Nrf-2 nuclear translocation in L929 mouse fibroblasts.

Hormesis is the process whereby exposure to a low dose of a chemical agent induces an adaptive effect on the cell or organism. This response evokes the expression of cytoprotective and antioxidant proteins, allowing pro-oxidants to emerge as important hormetic agents. The antiapoptotic protein Bcl-2 is known to protect cells against death induced by oxidants; it has been suggested that Bcl-2 might also modulate steady-state reactive oxygen species levels. The aim of this work was to find out if Bcl-2 might play a role during the hormetic response and in Nrf-2 activation. We have established a model to study the oxidative conditioning hormesis response (OCH) by conditioning the cell line L929 with 50muM H(2)O(2) for 9h. This condition did not induce oxidative damage nor oxidative imbalance, and OCH cells maintained a 70-80% survival rate after severe H(2)O(2) treatment compared to nonconditioned cells. When cells were pretreated with the Bcl-2 inhibitor HA14-1 or were silenced with Bcl-2-siRNA, both the hormetic effect and the Nrf-2 nuclear translocation previously observed were abrogated. Our results suggest a sequence of causal events related to increase in Bcl-2 expression, induction of Nrf-2 activation, and sustained expression of cytoprotective proteins such as GST and gammaGCS.

Msh2 promoter region hypermethylation as a marker of aging-related deterioration in old retired female breeder mice.

Aging is a process where individuals decrease the performance of their physiological systems and cellular stress response, making them more susceptible to disease and death. The increase in DNA damage associated with age might be recognized as the accumulation of physiological and environmentally induced mutations accompanied with a decline in DNA repair. DNA mismatch repair (MMR) is the main postreplicative correction pathway, which is known to decrease with age. However, since infrequent occurrence of direct DNA damage contrasts with the extensive cell and tissue dysfunction seen in older individuals, the withdrawing of DNA-repairing systems might be also related to epigenetic changes, such as DNA methylation. It has been reported that the physiological stress related to breeding might accelerate the acquisition of aging-related markers; therefore, the aim of this work was to link age with epigenetic modifications in this animal population. Hence, the correlation of Msh2 gene silencing with the deterioration of breeding female mice associated to aging was determined. Combined bisulfite restriction analysis assay was used to compare methylation on DNA isolated from twelve-month-old retired breeders against nulliparous female mice aged-matched, and two-month-old young adults. Our experiments clearly reveal Msh2 promoter hypermethylation associated to the aging process. A higher degree methylation was additionally observed in breeding females DNA. Nevertheless, this additional methylation did not correlate with a further decrease Msh2 mRNA, suggesting that the increase in methylation in old retired breeder might account for further epigenetic changes that could additionally promote the aging process.

Physiological deterioration associated with breeding in female mice: a model for the study of senescence and aging.

Longevity is a complex and dynamic process influenced by a diversity of factors. Amongst other, gestation and lactation contribute to organismal decline because they represent a great energetic investment in mammals. Here we compared the rate of senescence onset observed in primary fibroblast obtained from the lungs of retired female breeder mice (12 months old), with the senescence arrival observed in fibroblasts derived from age-matched nulliparous mice. Two-month-old animals were also used as controls of young, fully-developed adults. Cell proliferation, DNA synthesis, and expression of senescence-associated beta-galactosidase activity were evaluated as senescent parameters. In order to test differences in energetic competence at a systemic level, mitochondrial respiration was also evaluated in mitochondria isolated from the livers of the same animals used for the primary cultures. Our data indicated that the cells derived from female mice subjected to the physiological stress of breeding onset into replicative senescence prior than the cells from female mice age-matched without that particular stress. Thus validating the use of retired breeders as a model to study aging and senescence at the cellular level.

Organ- and tissue-specific alterations in the anti-apoptotic protein Bcl-2 in CD1 female mice of different ages.

The anti-apoptotic protein Bcl-2, which also has cytoprotective and antioxidant functions might be one of the crucial factors that altogether, establish how a cell may deal with stress and damage, contributing to longevity. Among the controversial issues to understand Bcl-2 functions in vivo, is to establish its content and variation in tissues during an organismal lifespan. In this work we analyzed the changes of Bcl-2 levels in lung, liver, heart, kidney, spleen and brain homogenates obtained from CD1 mice throughout their lifespan (newborn to 24 months). A tendency of increment was observed in all the organs analyzed, except brain where Bcl-2 was not detected. Bcl-2 over-expression during aging could be interpreted as a protective mechanism preventing cell death, despite the overall accumulated cell damage.

Bcl-2 protects against oxidative stress while inducing premature senescence.

Replicative senescence is a cellular response to stress that has been postulated to serve as a tumor suppression mechanism and a contributor to aging. Numerous experimental studies have demonstrated that an apparently identical senescent state can also be prematurely induced in vitro in different cell types following sublethal oxidative stress stimuli. The former suggests a molecular link between cell cycle regulation and cell survival that could involve regulatory proteins such as Bcl-2. There is strong evidence that, in addition to its well-known effects on apoptosis, Bcl-2 is involved in antioxidant protection and regulation of cell cycle progression. The aim of this work was to determine if the protection against oxidative stress mediated by Bcl-2 could prevent or delay oxidative stress-induced senescence. Using a retroviral infection system, Bcl-2 was overexpressed in primary, nonembryonic mice fibroblasts obtained from lungs derived from 2-month-old CD1 mice. Fibroblasts overexpressing Bcl-2 were exposed to 75 microM H2O2 for 2 h to induce SIPS. The rate of proliferation and the increment of senescent cells were then determined. Our results indicate that overexpression of Bcl-2 protected primary fibroblasts against oxidative stress-mediated reduction in cell proliferation, but did not prevent premature senescence.

Susceptibility of DNA to oxidative stressors in young and aging mice.

The changes that accompany aging may be a result of oxidative damage to DNA that accumulates as a result of aging and age-related illnesses. Furthermore, a higher susceptibility is thought to be more common among elderly than young individuals. In the present study, we examined the severity of DNA damage caused by carbon tetrachloride (CCl4) and H2O2 in cells from young (2 month old) and older (14 month old) mice using both in vivo and in vitro exposures. CCl(4) is known to generate radical oxidative species (ROS) throughout its biotransformation in the liver. Therefore, 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxdGuo) was quantified in liver DNA obtained from young and older mice treated with CCl4. In addition, DNA single-strand breaks were measured by the Comet assay in primary lung fibroblasts cultured from young and older mice and treated in vitro with H2O2. Intracellular ROS production and mitochondrial enzyme activity were determined in parallel. 8-oxodGuo levels were significantly higher in older mouse liver DNA than younger, and increased significantly with CCl4 treatment. When the basal DNA damage was subtracted, the net damage was almost equal for both. In addition, untreated cells cultured from older mice had significantly greater levels of strand breaks than cells derived from young mice. H2O2 increased the level of damage in both cell cultures. Our findings indicate that the DNA damage observed in older animals probably results from the accumulation of endogenous damage with age, perhaps due to insufficient repair, which enhances the injury caused by exposure to the toxic agents.

Senescent phenotype achieved in vitro is indistinguishable, with the exception of Bcl-2 content, from that attained during the in vivo aging process.

Senescent phenotype can be attained by diverse agents, thus suggesting that there might be molecular differences between the senescence achieved in vivo and the senescence-like state attained in vitro under culture conditions. In this study we compare the senescent phenotype reached by cells derived from young animals when cultured in vitro with the one associated with the in vivo aging process. Several in vitro senescence parameters, including MTT reduction, proliferation rate, DNA synthesis, SA-beta-gal staining, and both in vivo and in vitro Bcl-2 content, were determined. Alterations in DNA electrophoretic mobility were evaluated to test differences in bulk chromatin structure. Our results indicate that although it is possible to achieve a senescent phenotype with cells derived from young animals aged in culture, this phenotype differs from the one observed in older animals, due to lack of in vivo damage inducers to which cells are being exposed during natural aging.