Caloric restriction increases the expression of heat shock protein in the gut

A novel RT-qPCR health assay reveals differential expression of stress and immunoregulatory genes between the seasonal migrations of humpback whales (Megaptera novaeangliae)

Health information is essential for the conservation management of whale species. However, assessing the health of free-ranging whales is challenging as samples are primarily limited to skin and blubber tissue. Reverse transcription quantitative polymerase chain reaction (RT-qPCR) offers a method to measure health from blubber RNA, providing insights into energetic status, stress and immune activity. To identify changes in health, natural differences in baseline gene expression linked to an individual's sex, reproductive status and life-history stage must first be quantified. This study aimed to establish baseline gene expression indices of health in migrating humpback whales (Megaptera novaeangliae). To do this, we developed an assay to quantify seven health-related gene transcripts (Leptin, Leptin Receptor, Adiponectin, Aryl Hydrocarbon Receptor, Tumour Necrosis Factor-α, Interleukin-6, Heat Shock Protein-70) and used Bayesian mixed effect models to assess differential baseline expression based on sex, lactation status and migration stage (northbound to and southbound from the annual breeding grounds). Results showed no significant contribution of sex to differential baseline expression. However, lactating individuals exhibited downregulated AhR and HSP-70 compared to non-lactating conspecifics. Additionally, southbound individuals demonstrated significantly upregulated HSP-70 and downregulated TNF-alpha, suggesting a relationship between these inflammation-linked transcripts and migratory fasting. Our results suggest that baseline differences due to migratory stage and lactation status should be considered in health applications of this assay. Future monitoring efforts can use our baseline measurements to better understand how gene expression is tied to population-level impacts, such as reduced prey availability or migratory stressors.

Fitness correlates of blubber oxidative stress and cellular defences in grey seals (Halichoerus grypus): support for the life-history-oxidative stress theory from an animal model of simultaneous lactation and fasting

Life-history-oxidative stress theory predicts that elevated energy costs during reproduction reduce allocation to defences and increase cellular stress, with fitness consequences, particularly when resources are limited. As capital breeders, grey seals are a natural system in which to test this theory. We investigated oxidative damage (malondialdehyde (MDA) concentration) and cellular defences (relative mRNA abundance of heat shock proteins (Hsps) and redox enzymes (REs)) in blubber of wild female grey seals during the lactation fast (n = 17) and summer foraging (n = 13). Transcript abundance of Hsc70 increased, and Nox4, a pro-oxidant enzyme, decreased throughout lactation. Foraging females had higher mRNA abundance of some Hsps and lower RE transcript abundance and MDA concentrations, suggesting they experienced lower oxidative stress than lactating mothers, which diverted resources into pup rearing at the expense of blubber tissue damage. Lactation duration and maternal mass loss rate were both positively related to pup weaning mass. Pups whose mothers had higher blubber glutathione-S-transferase (GST) expression at early lactation gained mass more slowly. Higher glutathione peroxidase (GPx) and lower catalase (CAT) were associated with longer lactation but reduced maternal transfer efficiency and lower pup weaning mass. Cellular stress, and the ability to mount effective cellular defences, could proscribe lactation strategy in grey seal mothers and thus affect pup survival probability. These data support the life-history-oxidative stress hypothesis in a capital breeding mammal and suggest lactation is a period of heightened vulnerability to environmental factors that exacerbate cellular stress. Fitness consequences of stress may thus be accentuated during periods of rapid environmental change.

Sauna use as a lifestyle practice to extend healthspan

Sauna use, sometimes referred to as "sauna bathing," is characterized by short-term passive exposure to high temperatures, typically ranging from 45 °C to 100 °C (113 °F to 212 °F), depending on modality. This exposure elicits mild hyperthermia, inducing a thermoregulatory response involving neuroendocrine, cardiovascular, and cytoprotective mechanisms that work in a synergistic fashion in an attempt to maintain homeostasis. Repeated sauna use acclimates the body to heat and optimizes the body's response to future exposures, likely due to the biological phenomenon known as hormesis. In recent decades, sauna bathing has emerged as a probable means to extend healthspan, based on compelling data from observational, interventional, and mechanistic studies. Of particular interest are the findings from large, prospective, population-based cohort studies of health outcomes among sauna users that identified strong dose-dependent links between sauna use and reduced morbidity and mortality. This review presents an overview of sauna practices; elucidates the body's physiological response to heat stress and the molecular mechanisms that drive the response; enumerates the myriad health benefits associated with sauna use; and describes sauna use concerns.

Association of Gut Microbiome Dysbiosis with Neurodegeneration: Can Gut Microbe-Modifying Diet Prevent or Alleviate the Symptoms of Neurodegenerative Diseases?

The central nervous system was classically perceived as anatomically and functionally independent from the other visceral organs. But in recent decades, compelling evidence has led the scientific community to place a greater emphasis on the role of gut microbes on the brain. Pathological observations and early gastrointestinal symptoms highlighted that gut dysbiosis likely precedes the onset of cognitive deficits in Alzheimer's disease (AD) and Parkinson's disease (PD) patients. The delicate balance in the number and functions of pathogenic microbes and alternative probiotic populations is critical in the modulation of systemic inflammation and neuronal health. However, there is limited success in restoring healthy microbial biodiversity in AD and PD patients with general probiotics interventions and fecal microbial therapies. Fortunately, the gut microflora is susceptible to long-term extrinsic influences such as lifestyle and dietary choices, providing opportunities for treatment through comparatively individual-specific control of human behavior. In this review, we examine the impact of restrictive diets on the gut microbiome populations associated with AD and PD. The overall evidence presented supports that gut dysbiosis is a plausible prelude to disease onset, and early dietary interventions are likely beneficial for the prevention and treatment of progressive neurodegenerative diseases.

Modelling and analysis of the feeding regimen induced entrainment of hepatocyte circadian oscillators using petri nets

Circadian rhythms are certain periodic behaviours exhibited by living organism at different levels, including cellular and system-wide scales. Recent studies have found that the circadian rhythms of several peripheral organs in mammals, such as the liver, are able to entrain their clocks to received signals independent of other system level clocks, in particular when responding to signals generated during feeding. These studies have found SIRT1, PARP1, and HSF1 proteins to be the major influencers of the core CLOCKBMAL1:PER-CRY circadian clock. These entities, along with abstracted feeding induced signals were modelled collectively in this study using Petri Nets. The properties of the model show that the circadian system itself is strongly robust, and is able to continually evolve. The modelled feeding regimens suggest that the usual 3 meals/day and 2 meals/day feeding regimens are beneficial with any more or less meals/day negatively affecting the system.

Diapause formation and downregulation of insulin-like signaling via DAF-16/FOXO delays axonal degeneration and neuronal loss

Axonal degeneration is a key event in the pathogenesis of neurodegenerative conditions. We show here that mec-4d triggered axonal degeneration of Caenorhabditis elegans neurons and mammalian axons share mechanistical similarities, as both are rescued by inhibition of calcium increase, mitochondrial dysfunction, and NMNAT overexpression. We then explore whether reactive oxygen species (ROS) participate in axonal degeneration and neuronal demise. C. elegans dauers have enhanced anti-ROS systems, and dauer mec-4d worms are completely protected from axonal degeneration and neuronal loss. Mechanistically, downregulation of the Insulin/IGF-1-like signaling (IIS) pathway protects neurons from degenerating in a DAF-16/FOXO–dependent manner and is related to superoxide dismutase and catalase-increased expression. Caloric restriction and systemic antioxidant treatment, which decrease oxidative damage, protect C. elegans axons from mec-4d-mediated degeneration and delay Wallerian degeneration in mice. In summary, we show that the IIS pathway is essential in maintaining neuronal homeostasis under pro-degenerative stimuli and identify ROS as a key intermediate of neuronal degeneration in vivo. Since axonal degeneration represents an early pathological event in neurodegeneration, our work identifies potential targets for therapeutic intervention in several conditions characterized by axonal loss and functional impairment.

Axonal degeneration and neuronal loss are currently considered crucial pathological factors in neurodegenerative diseases. Therefore, delaying or blocking these procesess is key for neuroprotection. In this work, we used an in vivo approach combining invertebrate (C. elegans) and vertebrate (mice) model systems to identify a novel and unexpected player in the mechanisms of axonal degeneration. Here, we demonstrate that both neuronal somas and axons degenerate through a step dependent on oxidative stress that can be efficiently delayed by genetic downregulation of a pathway controlling oxidative stress resistance. Impressively, we discovered that diapause formation, which is a state related to hibernating conditions, fully prevents neuronal degeneration. We uncovered new players in the degenerative mechanisms of neurons with relevance for several conditions associated to axonal degeneration, such as multiple sclerosis, motoneuron, and Parkinson diseases, offering novel potential targets for neuroprotection.

Heat shock and caloric restriction have a synergistic effect on the heat shock response in a sir2.1-dependent manner in Caenorhabditis elegans

The heat shock response (HSR) is responsible for maintaining cellular and organismal health through the regulation of proteostasis. Recent data demonstrating that the mammalian HSR is regulated by SIRT1 suggest that this response may be under metabolic control. To test this hypothesis, we have determined the effect of caloric restriction in Caenorhabditis elegans on activation of the HSR and have found a synergistic effect on the induction of hsp70 gene expression. The homolog of mammalian SIRT1 in C. elegans is Sir2.1. Using a mutated C. elegans strain with a sir2.1 deletion, we show that heat shock and caloric restriction cooperate to promote increased survivability and fitness in a sir2.1-dependent manner. Finally, we show that caloric restriction increases the ability of heat shock to preserve movement in a polyglutamine toxicity neurodegenerative disease model and that this effect is dependent on sir2.1.

Protein homeostasis and aging: The importance of exquisite quality control

All cells count on precise mechanisms that regulate protein homeostasis to maintain a stable and functional proteome. A progressive deterioration in the ability of cells to preserve the stability of their proteome occurs with age and contributes to the functional loss characteristic of old organisms. Molecular chaperones and the proteolytic systems are responsible for this cellular quality control by assuring continuous renewal of intracellular proteins. When protein damage occurs, such as during cellular stress, the coordinated action of these cellular surveillance systems allows detection and repair of the damaged structures or, in many instances, leads to the complete elimination of the altered proteins from inside cells. Dysfunction of the quality control mechanisms and intracellular accumulation of abnormal proteins in the form of protein inclusions and aggregates occur in almost all tissues of an aged organism. Preservation or enhancement of the activity of these surveillance systems until late in life improves their resistance to stress and is sufficient to slow down aging. In this work, we review recent advances on our understanding of the contribution of chaperones and proteolytic systems to the maintenance of cellular homeostasis, the cellular response to stress and ultimately to longevity.

Fasting and refeeding modulate the expression of stress proteins along the gastrointestinal tract of weaned pigs

The gastrointestinal tract (GIT) of young mammals is submitted to aggressions early in life and GIT stress proteins are up-regulated in pigs following weaning. We hypothesized that transient food deprivation may contribute to these changes. Therefore, the effects of fasting and refeeding on GIT stress proteins in weaned pigs were investigated. A complete block experimental design with three groups of five pigs each was set up with the following treatments: A - food offered, B - fasted for 1.5 days, C - fasted for 1.5 days and then re-fed for 2.5 days. After slaughter, the GIT was removed, weighed and sampled. Intestinal villi and crypts were measured and alkaline phosphatase activity was determined. GIT tissue stress protein concentrations were measured by Western blotting. Fasting led to intestinal mucosa and villous-crypt atrophy (p < 0.01) and reduced mucosal alkaline phosphatase total activity in the proximal small intestine (p < 0.05). Heat shock proteins HSP 27 and HSP 90 (but not HSP 70) and neuronal NO synthase (nNOS) increased (p < 0.01) in the stomach, mid-intestine and proximal colon with fasting. Inducible NOS (iNOS) did so in the stomach (p < 0.001). Refeeding partially or totally restored GIT characteristics and stress protein concentrations, except for gastric HSP 90 and iNOS. Significant correlations (p < 0.05 to p < 0.0001) were found among stress proteins, between nNOS and digesta weight, between HSP 27 or HSP 90 and intestinal mucosa weight, and between intestinal or colonic HSP or nNOS and alkaline phosphatase. In conclusion, fasting and refeeding modulate GIT HSP proteins and nNOS in pigs following weaning. Changes in digesta and intestinal mucosa weights and alkaline phosphatase activity may be involved in the modulation of stress proteins along the GIT.

Effects of dietary restriction on mortality and age-related phenotypes in the short-lived fish Nothobranchius furzeri

The short-lived annual fish Nothobranchius furzeri shows extremely short captive life span and accelerated expression of age markers, making it an interesting model system to investigate the effects of experimental manipulations on longevity and age-related pathologies. Here, we tested the effects of dietary restriction (DR) on mortality and age-related markers in N. furzeri. DR was induced by every other day feeding and the treatment was performed both in an inbred laboratory line and a longer-lived wild-derived line. In the inbred laboratory line, DR reduced age-related risk and prolonged maximum life span. In the wild-derived line, DR induced early mortality, did not reduce general age-related risk and caused a small but significant extension of maximum life span. Analysis of age-dependent mortality revealed that DR reduced demographic rate of aging, but increased baseline mortality in the wild-derived strain. In both inbred- and wild-derived lines, DR prevented the expression of the age markers lipofuscin in the liver and Fluoro-Jade B (neurodegeneration) in the brain. DR also improved performance in a learning test based on conditioning (active avoidance in a shuttle box). Finally, DR induced a paradoxical up-regulation of glial fibrillary acidic protein in the brain.

The neuroprotective properties of calorie restriction, the ketogenic diet, and ketone bodies

Both calorie restriction and the ketogenic diet possess broad therapeutic potential in various clinical settings and in various animal models of neurological disease. Following calorie restriction or consumption of a ketogenic diet, there is notable improvement in mitochondrial function, a decrease in the expression of apoptotic and inflammatory mediators and an increase in the activity of neurotrophic factors. However, despite these intriguing observations, it is not yet clear which of these mechanisms account for the observed neuroprotective effects. Furthermore, limited compliance and concern for adverse effects hamper efforts at broader clinical application. Recent research aimed at identifying compounds that can reproduce, at least partially, the neuroprotective effects of the diets with less demanding changes to food intake suggests that ketone bodies might represent an appropriate candidate. Ketone bodies protect neurons against multiple types of neuronal injury and are associated with mitochondrial effects similar to those described during calorie restriction or ketogenic diet treatment. The present review summarizes the neuroprotective effects of calorie restriction, of the ketogenic diet and of ketone bodies, and compares their putative mechanisms of action.

Induction of heat shock proteins may combat insulin resistance

The molecular mechanism responsible for obesity-associated insulin resistance has been partially clarified: increased fatty acid levels in muscle fibers promote diacylglycerol synthesis, which activates certain isoforms of protein kinase C (PKC). This in turn triggers a kinase cascade which activates both IkappaB kinase-beta (IKK-beta) and c-Jun N-terminal kinase (JNK), each of which can phosphorylate a key serine residue in IRS-1, rendering it a poor substrate for the activated insulin receptor. Heat shock proteins Hsp27 and Hsp72 have the potential to prevent the activation of IKK-beta and JNK, respectively; this suggests that induction of heat shock proteins may blunt the adverse impact of fat overexposure on insulin function. Indeed, bimoclomol--a heat shock protein co-inducer being developed for treatment of diabetic neuropathy--and lipoic acid--suspected to be a heat shock protein inducer--have each demonstrated favorable effects on the insulin sensitivity of obese rodents, and parenteral lipoic acid is reported to improve the insulin sensitivity of type 2 diabetics. Moreover, there is reason to believe that heat shock protein induction may have a favorable impact on the microvascular complications of diabetes, and on the increased risk for macrovascular disease associated with diabetes and insulin resistance syndrome. Heat shock protein induction may also have potential for preventing or treating neurodegenerative disorders, controlling inflammation, and possibly even slowing the aging process. The possible complementarity of bimoclomol and lipoic acid for heat shock protein induction should be assessed, and further efforts to identify well-tolerated agents active in this regard are warranted.

Luminal bacterial flora determines physiological expression of intestinal epithelial cytoprotective heat shock proteins 25 and 72

Heat shock proteins (HSP) 25 and 72 are expressed normally by surface colonocytes but not by small intestinal enterocytes. We hypothesized that luminal commensal microflora maintain the observed colonocyte HSP expression. The ability of the small intestine to respond to bacteria and their products and modulate HSPs has not been determined. The effects of luminal bacterial flora in surgically created midjejunal self-filling (SFL) vs. self-emptying (SEL) small-bowel blind loops on epithelial HSP expression were studied. HSP25 and HSP72 expression were assessed by immunoblot and immunohistochemistry. SFL were chronically colonized, whereas SEL contained levels of bacteria normal for the proximal small intestine. SFL creation significantly increased HSP25 and HSP72 expression relative to corresponding sections from SEL. Metronidazole treatment, which primarily affects anaerobic bacteria as well as a diet lacking fermentable fiber, significantly decreased SFL HSP expression. Small bowel incubation with butyrate ex vivo induced a sustained and significant upregulation of HSP25 and altered HSP72 expression, confirming the role of short-chain fatty acids. To determine whether HSPs induction altered responses to an injury, effects of the oxidant, monochloramine, on epithelial resistance and short-circuit current (I(sc)) responses to carbachol and glucose were compared. Increased SFL HSP expression was associated with protection against oxidant-induced decreases in transmural resistance and I(sc) responses to glucose, but not secretory responses to carbachol. In conclusion, luminal microflora and their metabolic byproducts direct expression of HSPs in gut epithelial cells, an effect that contributes to preservation of epithelial cell viability under conditions of stress.

Life long calorie restriction increases heat shock proteins and proteasome activity in soleus muscles of Fisher 344 rats

Heat shock proteins (HSP's) closely interact with 20S proteasome and have been shown to maintain catalytic activity, responsible for the prevention of protein aggregation. A decrease in both proteasome activity and heat shock proteins (HSP's) has been observed with age. We investigated whether life-long calorie restriction (CR), a natural intervention, which prolongs life span, could prevent the age-associated decline in HSP's and restore the proteolytic activity of the 20S proteasome in skeletal muscle. Hence, we investigated HSP's and proteasome activity in the soleus muscle from 12-mo-old (Adult) and 26-28 mo old ad libitum fed (Old), and 26-28 mo old CR (Old-CR; fed 40% of ad libitum for their lifespan) male Fisher 344 rats. Trypsin-like proteasome activity in Old rats was significantly less than both Adult and Old-CR rats. Furthermore, no significant changes where found in chymotrypsin-like proteasome activity due to age or diet. Levels of HSP 72 and 25 were significantly less in Old animals when compared to both Adult and Old-CR rats. In contrast, HSP 90 was elevated in Old rats by 220% compared to adult animals and life-long calorie restriction caused a significant induction (150%) compared to age-matched ad libitum fed animals. Protein carbonyls were significantly elevated in Old when compared to Adult rats, but showed no significant decline due to life long CR. This study shows that HSP's may be largely responsible for the restoration of the trypsin-like activity of the 20S proteasome with age. The large increase in HSP 90 is intriguing and further studies are required to elucidate its role in maintaining 20S proteasome function.

Effect of Dietary Restriction on DNA Synthesis in Vitamin E-Deficient Rats

To assess the effect of dietary restriction on increased oxidative stress conditions, we measured the proliferative response of spleen lymphocytes from the following groups of adult rats: (1) control fed ad libitum (14 months of age); (2) vitamin E-deficient (12 months of age); and (3) vitamin E-deficient maintained on dietary restricted paradigm, that is, every other day schedule (12 months of age) animals. No significant change was observed among the three groups investigated at 24 h. At 48 h, [(3)H]thymidine incorporation was significantly lower in vitamin E-deficient rats vs. the other groups at Con A concentrations of 1 and 5 mug/mL, while at Con A concentration of 10 mug/mL the incorporation of the labeled compound in lymphocytes was significantly lower than only the vitamin E-deficient rats vs. controls. At 72 h: nonstimulated lymphocytes from ad libitum fed control rats showed significant higher values of [(3)H]thymidine incorporation vs. the other groups; no significant difference was found among the three groups investigated at 1 and 10 mug/mL Con A concentrations, while at 5 mug/mL Con A concentration, the lymphocytes from vitamin E-deficient rats showed a significant lower value of [(3)H]thymidine incorporation vs. the other groups. These data support that vitamin E-deficiency impairs the proliferative response of spleen lymphocytes from adult rats, while dietary restriction appears to be able to reverse this alteration. Although the mechanism(s) of action of dietary restriction in prolonging the life span and ameliorating health conditions are not know, it is currently supported that a reduced food intake results in a better control of free radical attacks to biological molecules as well as to several cellular and system functions. With specific reference to the present findings, dietary restriction may help the mitotic process dynamics to be accomplished in a condition of low rate of free radical damage, thus representing a physiological intervention capable of modulating positively the proliferative capacity of spleen lymphocytes and, in turn, the immune system, even in adverse conditions such as increased oxidative stress.

Role and regulation of intestinal epithelial heat shock proteins in health and disease

Mucosal injury and inflammation are cardinal manifestations of inflammatory bowel diseases (IBD), arising when the effects of cytotoxic factors and conditions overwhelm the cell's capacity for defense (i.e. cytoprotection) or repair. To date, most research in this area has focused primarily on agents and processes involved in producing tissue injury, with less consideration given to inherent mechanisms of cytoprotection and cellular repair. Therapeutic approaches to IBD reflect this bias, being largely directed towards down-regulating the inflammatory process by inhibiting the production of immune and inflammatory mediators. This review will focus on the cell's inherent ability to defend itself against cellular stress and injury through the production of evolutionarily conserved stress proteins called heat shock proteins (HSP). The physiological role of these proteins in maintaining intestinal epithelial cell structure and function will be reviewed, with emphasis on studies that examine the role of HSP in IBD. A clearer understanding of the innate cytoprotective mechanisms inherent in intestinal epithelial cells will foster the development of new insights into basic epithelial cell biology, which ultimately can be used to establish target-specific therapies directed at reducing or alleviating mucosal injury, thereby promoting tissue healing and repair.

An in vitro model of caloric restriction

The mechanisms underlying the ability of caloric restriction (CR) to extend life span and enhance stress responsiveness remain elusive. Progress in this area has been slow due to the complexities of using animals for CR studies and assessing life span as the measure of CR effectiveness. It is therefore of great interest to develop in vitro models of CR. Here we use sera obtained from either Fisher 344 rats or Rhesus monkeys that were fed ad libitum (AL) or CR diets to culture various cell types. We show that treatment of cultured cells with CR sera caused reduced cell proliferation, enhanced tolerance to oxidants and heat, and heightened expression of stress-response genes. These phenotypic features mirror the effects of CR in animals. Supplementation of CR serum with insulin and insulin-like growth factor (IGF)-1 partially restored the proliferative and stress-response phenotype that was seen in cells cultured with AL serum, indicating that reduced levels of insulin and IGF-1 likely contribute to the CR-related effects. This in vitro cell culture model recapitulates key in vivo proliferative and stress-response phenotypic features of CR, and further suggests that endocrine mechanisms contribute to the enhanced stress responsiveness observed in CR animals.

Intermittent fasting and dietary supplementation with 2-deoxy-D-glucose improve functional and metabolic cardiovascular risk factors in rats

Hypertension and insulin resistance syndrome are risk factors for cardiovascular disease, and it is therefore important to identify interventions that can reduce blood pressure and improve glucose metabolism. We performed experiments aimed at determining whether intermittent fasting (IF) can improve cardiovascular health and also tested the hypothesis that beneficial effects of IF can be mimicked by dietary supplementation with 2-deoxy-D-glucose (2DG) a non-metabolizable glucose analog. Four-month-old male rats were implanted with telemetry probes to allow continuous monitoring of heart rate, blood pressure, physical activity, and body temperature. Rats were then maintained for 6 months on one of three different dietary regimens: ad libitum feeding, IF, or 2DG supplementation. Rats on the IF regimen consumed 30% less food over time and had reduced body weights compared with rats fed ad libitum, whereas rats on the 2DG regimen did not reduce their food intake and maintained their body weight. Heart rate and blood pressure were significantly decreased within 1 month in rats on IF and 2DG diets and were maintained at reduced levels thereafter. Body temperature was significantly decreased in group IF, but not in group 2DG. Levels of serum glucose and insulin were significantly decreased in rats maintained on IF and 2DG-supplemented diets, suggesting that IF and 2DG diets affect insulin sensitivity in a similar manner. Finally, rats in groups IF and 2DG exhibited increased levels of plasma adrenocorticotropin and corticosterone, indicating that these diets induced a stress response. We conclude that reductions in blood pressure, heart rate, and insulin levels, similar to or greater than those obtained with regular physical exercise programs, can be achieved by IF and by dietary supplementation with 2DG by a mechanism involving stress responses.

Chaperones come of age

Chaperone function plays a key role in repairing proteotoxic damage, in the maintenance of cell architecture, and in cell survival. Here, we summarize our current knowledge about changes in chaperone expression and function in the aging process, as well as their involvement in longevity and cellular senescence.

Resistance to stress as a function of age in transgenic Drosophila melanogaster overexpressing Hsp70

This study investigated the resistance to stress as a function of age in Drosophila melanogaster overexpressing Hsp70. The resistances to starvation, paraquat, and cold in flies from 1 to 7 week-old have been measured. The line carrying the insertion vector without the transgenes is more resistant to starvation and cold than the parental and transgenic lines. In contrast, transgenic flies carrying extra-copies of hsp70 are more resistant to paraquat, however this is due to an especially high resistance in two age groups compared to all the other groups. I showed that exposure to a mild heat shock does not increase starvation resistance, slightly increases paraquat resistance, and strongly increases cold resistance. The transgenic flies expressing Hsp70 at higher levels after the heat shock do not exhibit enhanced stress resistance compared to control lines expressing less Hsp70 after the heat shock. The lack of effect of a mild heat shock on starvation and paraquat resistance is not due to a disappearance of the effect with age, since no effect is observed at any age. In contrast, when an effect of Hsp70 induction is observed as on cold resistance, this effect is still observed in old flies.

Does a vegan diet reduce risk for Parkinson's disease?

Three recent case-control studies conclude that diets high in animal fat or cholesterol are associated with a substantial increase in risk for Parkinson's disease (PD); in contrast, fat of plant origin does not appear to increase risk. Whereas reported age-adjusted prevalence rates of PD tend to be relatively uniform throughout Europe and the Americas, sub-Saharan black Africans, rural Chinese, and Japanese, groups whose diets tend to be vegan or quasi-vegan, appear to enjoy substantially lower rates. Since current PD prevalence in African-Americans is little different from that in whites, environmental factors are likely to be responsible for the low PD risk in black Africans. In aggregate, these findings suggest that vegan diets may be notably protective with respect to PD. However, they offer no insight into whether saturated fat, compounds associated with animal fat, animal protein, or the integrated impact of the components of animal products mediates the risk associated with animal fat consumption. Caloric restriction has recently been shown to protect the central dopaminergic neurons of mice from neurotoxins, at least in part by induction of heat-shock proteins; conceivably, the protection afforded by vegan diets reflects a similar mechanism. The possibility that vegan diets could be therapeutically beneficial in PD, by slowing the loss of surviving dopaminergic neurons, thus retarding progression of the syndrome, may merit examination. Vegan diets could also be helpful to PD patients by promoting vascular health and aiding blood-brain barrier transport of L-dopa.

Versatile cytoprotective activity of lipoic acid may reflect its ability to activate signalling intermediates that trigger the heat-shock and phase II responses

Although lipoic acid (LA) and its reduced derivative (DHLA) have broad antioxidant activity, it seems unlikely that this can adequately explain the remarkable neuroprotective effects of LA observed in rodents and in diabetic patients. It is proposed that this protection is mediated, in large measure, by induction of various protective proteins. More specifically, there is some reason to suspect that LA can trigger both heat-shock and phase II responses, and that LA may achieve this by catalyzing the formation of intramolecular disulfides in certain signalling proteins that function as detectors of oxidants and/or electrophiles. This hypothesis is readily testable, and, if true, would suggest that LA may have general utility for preventing or treating neurodegenerative disorders, and possibly also may retard the adverse impact of aging on brain function. This model also predicts that LA should have anticarcinogenic activity.

Dietary restriction stimulates BDNF production in the brain and thereby protects neurons against excitotoxic injury

Dietary restriction (DR) increases the lifespan of rodents and increases their resistance to several different age-related diseases including cancer and diabetes. Beneficial effects of DR on brain plasticity and neuronal vulnerability to injury have recently been reported, but the underlying mechanisms are unknown. We report that levels of brain-derived neurotrophic factor (BDNF) are significantly increased in the hippocampus, cerebral cortex, and striatum of rats maintained on a DR regimen compared to animals fed ad libitum (AL). Seizure-induced damage to hippocampal neurons was significantly reduced in rats maintained on DR, and this beneficial effect was attenuated by intraventricular administration of a BDNF-blocking antibody. These findings provide the first evidence that diet can effect expression of a neurotrophic factor, demonstrate that BDNF signaling plays a central role in the neuroprotective effect of DR, and proffer DR as an approach for reducing neuronal damage in neurodegenerative disorders.

Brain-derived neurotrophic factor mediates an excitoprotective effect of dietary restriction in mice

Dietary restriction (DR; reduced calorie intake) increases the lifespan of rodents and increases their resistance to cancer, diabetes and other age-related diseases. DR also exerts beneficial effects on the brain including enhanced learning and memory and increased resistance of neurons to excitotoxic, oxidative and metabolic insults. The mechanisms underlying the effects of DR on neuronal plasticity and survival are unknown. In the present study we show that levels of brain-derived neurotrophic factor (BDNF) are significantly increased in the hippocampus, cerebral cortex and striatum of mice maintained on an alternate day feeding DR regimen compared to animals fed ad libitum. Damage to hippocampal neurons induced by the excitotoxin kainic acid was significantly reduced in mice maintained on DR, and this neuroprotective effect was attenuated by intraventricular administration of a BDNF-blocking antibody. Our findings show that simply reducing food intake results in increased levels of BDNF in brain cells, and suggest that the resulting activation of BDNF signaling pathways plays a key role in the neuroprotective effect of DR. These results bolster accumulating evidence that DR may be an effective approach for increasing the resistance of the brain to damage and enhancing brain neuronal plasticity.

Beneficial effects of dietary restriction on cerebral cortical synaptic terminals: preservation of glucose and glutamate transport and mitochondrial function after exposure to amyloid beta-peptide, iron, and 3-nitropropionic acid

Recent studies have shown that rats and mice maintained on a dietary restriction (DR) regimen exhibit increased resistance of neurons to excitotoxic, oxidative, and metabolic insults in experimental models of Alzheimer's, Parkinson's, and Huntington's diseases and stroke. Because synaptic terminals are sites where the neurodegenerative process may begin in such neurodegenerative disorders, we determined the effects of DR on synaptic homeostasis and vulnerability to oxidative and metabolic insults. Basal levels of glucose uptake were similar in cerebral cortical synaptosomes from rats maintained on DR for 3 months compared with synaptosomes from rats fed ad libitum. Exposure of synaptosomes to oxidative insults (amyloid beta-peptide and Fe(2+)) and a metabolic insult (the mitochondrial toxin 3-nitropropionic acid) resulted in decreased levels of glucose uptake. Impairment of glucose uptake following oxidative and metabolic insults was significantly attenuated in synaptosomes from rats maintained on DR. DR was also effective in protecting synaptosomes against oxidative and metabolic impairment of glutamate uptake. Loss of mitochondrial function caused by oxidative and metabolic insults, as indicated by increased levels of reactive oxygen species and decreased transmembrane potential, was significantly attenuated in synaptosomes from rats maintained on DR. Levels of the stress proteins HSP-70 and GRP-78 were increased in synaptosomes from DR rats, consistent with previous data suggesting that the neuroprotective mechanism of DR involves a "preconditioning" effect. Collectively, our data provide the first evidence that DR can alter synaptic homeostasis in a manner that enhances the ability of synapses to withstand adversity.

Influence of short-term repeated fasting on the longevity of female (NZB x NZW)F1 mice

Caloric restriction in rodents is well known to retard the rate of aging, increase mean and maximum life-spans, and inhibit the occurrence of many age-associated diseases. However, little is known about the influence of short-term repeated fasting on longevity. In this study, female (NZB x NZW)F1 mice were used to test the physiological effect of short-term repeated fasting (4 consecutive days, every 2 weeks). The results showed that fasting mice survived significantly longer than the full-fed mice, in spite of the fasting group having a heavier body weight than the control group. Mean survival times for fasting and control mice were 64.0+/-15.3 and 47.9+/-9.4 weeks, respectively. Short-term repeated fasting manipulation was also effective on the prolongation of life-span in autoimmune-prone mice.

Malnutrition impairs postresection intestinal adaptation

BACKGROUND

Postresection intestinal adaptation is influenced by several factors, including luminal nutrients. Adaptation is impaired in the absence of luminal nutrients, even if the nutrition is maintained via total parenteral nutrition (TPN). Reduced enteral intake also inhibits adaptation if malnutrition is present, but the mechanism has not been completely defined. Our aim was to study the effect of reduced enteral nutrition on adaptation and enterocyte production and death after 50% proximal resection in rats.

METHODS

Eighteen Lewis rats underwent either transection (n =6) or 50% proximal resection (n =12). The resected animals either ate ad libitum (n = 6) or were offered 75% of ad libitum intake (n =6). Nutritional status and intestinal adaptation were determined 14 days after surgery.

RESULTS

Resected animals receiving 75% normal intake had decreased body weight (89% +/- 4% vs 112% +/- 2% and 112% +/- 1%, p < .05) and serum albumin (2.7 +/- 0.1 vs 3.2 +/- 0.0 g/dL and 3.0 +/- 0.1 g/dL, p < .05) compared with resection with normal intake and transection, respectively. Intestinal weight (0.32 +/- 03 vs 0.22 +/- 0.02 g/cm and 0.19 +/- 0.03 g/cm, p < .05) and diameter (10.5 +/- 0.5 vs 8.5 +/- 1.0 mm and 7.8 +/- 0.8 mm, p < .05) increased after resection alone compared with transection and malnourished resection groups. Gut weight and diameter and villus height were lower in malnourished resected animals than with transection. Crypt cell production rate was significantly lower in the reduced intake animals. Apoptosis was increased in both crypt and villus enterocytes in normally nourished but not malnourished resected animals. Villus apoptosis correlated with villus height.

CONCLUSIONS

Intestinal adaptation is impaired by a 25% reduction in enteral nutrients, confirming that both the route and quantity of nutrient intake are important in this process. Both enterocyte production and loss via apoptosis are decreased by reduced enteral intake and malnutrition after resection. The correlation between villus height and apoptosis suggests that the reduced apoptosis reflects the smaller enterocyte number in malnourished animals rather than an adaptive response to maintain intestinal structure.

Expression of heat shock proteins 47 and 70 in the peritoneum of patients on continuous ambulatory peritoneal dialysis

BACKGROUND

Peritoneal sclerosis, characterized by collagen accumulation, is a serious complication in continuous ambulatory peritoneal dialysis (CAPD) therapy. Heat shock protein 47 (HSP47) is a collagen-specific molecular chaperon and is closely associated with collagen synthesis.

METHODS

We determined the expression of HSP47 and HSP70 (nonspecific for collagen synthesis) by immunohistochemistry in peritoneal tissues of patients on CAPD. The tissue for collagen III, alpha-smooth muscle actin (alpha-SMA), and CD68 (a marker for macrophages) were also stained. Thirty-two peritoneal samples were divided into three groups (group A1, 11 patients who had no ultrafiltration loss; group A2, 9 patients who had ultrafiltration loss; and group B, 12 specimens who had end-stage renal disease prior to induction of CAPD.

RESULTS

In group B, staining for HSP47, HSP70, and collagen III in peritoneal tissues was faint, and only a few cells were positive for alpha-SMA and CD68. In contrast, HSP47, HSP70, and collagen III were expressed in areas of thickened connective tissues in fibrotic peritoneal specimens of CAPD patients. The expression level of HSP47, HSP70, collagen III, and alpha-SMA and the number of CD68-positive cells in group A2 were significantly higher than those in groups A1 and B. HSP47/HSP70-positive cells were mesothelial cells, adipocytes, and alpha-SMA-positive myofibroblasts. Furthermore, the expression level of HSP47 was significantly higher in peritoneal specimens from patients with refractory peritonitis than without it and was significantly higher in patients with more than 60 months of CAPD therapy than that in patients with less than 60 months of CAPD.

CONCLUSION

Our results indicate that CAPD therapy may induce HSPs in the peritoneal tissue, and that peritonitis in CAPD patients may be associated with the progression of peritoneal sclerosis at least through HSP47 expression and chronic macrophage infiltration. Our data also suggest that the progression of peritoneal sclerosis in such patients is associated with deterioration of peritoneal ultrafiltration function.

Dietary restriction protects hippocampal neurons against the death-promoting action of a presenilin-1 mutation

Alzheimer's disease (AD) is an age-related disorder that involves degeneration of synapses and neurons in brain regions involved in learning and memory processes. Some cases of AD are caused by mutations in presenilin-1 (PS1), an integral membrane protein located in the endoplasmic reticulum. Previous studies have shown that PS1 mutations increase neuronal vulnerability to excitotoxicity and apoptosis. Although dietary restriction (DR) can increase lifespan and reduce the incidence of several age-related diseases in rodents, the possibility that DR can modify the pathogenic actions of mutations that cause AD has not been examined. The vulnerability of hippocampal neurons to excitotoxic injury was increased in PS1 mutant knockin mice. PS1 mutant knockin mice and wild-type mice maintained on a DR regimen for 3 months exhibited reduced excitotoxic damage to hippocampal CA1 and CA3 neurons compared to mice fed ad libitum; the DR regimen completely counteracted the endangering effect of the PS1 mutation. The magnitude of increase in levels of the lipid peroxidation product 4-hydroxynonenal following the excitotoxic insult was lower in DR mice compared to mice fed ad libitum, suggesting that suppression of oxidative stress may be one mechanism underlying the neuroprotective effect of DR. These findings indicate that the neurodegeneration-promoting effect of an AD-linked mutation is subject to modification by diet.

Dietary restriction and 2-deoxyglucose administration improve behavioral outcome and reduce degeneration of dopaminergic neurons in models of Parkinson's disease

Parkinson's disease (PD) is an age-related disorder characterized by progressive degeneration of dopaminergic neurons in the substantia nigra (SN) and corresponding motor deficits. Oxidative stress and mitochondrial dysfunction are implicated in the neurodegenerative process in PD. Although dietary restriction (DR) extends lifespan and reduces levels of cellular oxidative stress in several different organ systems, the impact of DR on age-related neurodegenerative disorders is unknown. We report that DR in adult mice results in resistance of dopaminergic neurons in the SN to the toxicity of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). MPTP-induced loss of dopaminergic neurons and deficits in motor function were ameliorated in DR rats. To mimic the beneficial effect of DR on dopaminergic neurons, we administered 2-deoxy-D-glucose (2-DG; a nonmetabolizable analogue of glucose) to mice fed ad libitum. Mice receiving 2-DG exhibited reduced damage to dopaminergic neurons in the SN and improved behavioral outcome following MPTP treatment. The 2-DG treatment suppressed oxidative stress, preserved mitochondrial function, and attenuated cell death in cultured dopaminergic cells exposed to the complex I inhibitor rotenone or Fe2+. 2-DG and DR induced expression of the stress proteins heat-shock protein 70 and glucose-regulated protein 78 in dopaminergic cells, suggesting involvement of these cytoprotective proteins in the neuroprotective actions of 2-DG and DR. The striking beneficial effects of DR and 2-DG in models of PD, when considered in light of recent epidemiological data, suggest that DR may prove beneficial in reducing the incidence of PD in humans.

2-Deoxy-D-glucose protects hippocampal neurons against excitotoxic and oxidative injury: evidence for the involvement of stress proteins

Food restriction can extend life span in rodents and was recently reported to increase the resistance of neurons in the brain to excitotoxic and metabolic insults. In principle, administration to ad libitum fed rodents of an agent that reduces glucose availability to cells should mimick certain aspects of food restriction. We now report that administration of 2-deoxy-D-glucose (2DG), a non-metabolizable analog of glucose, to adult rats results in a highly significant reduction in seizure-induced spatial memory deficits and hippocampal neuron loss. Pretreatment of rat hippocampal cell cultures with 2DG decreases the vulnerability of neurons to excitotoxic (glutamate) and oxidative (Fe2+) insults. The protective action of 2DG is associated with decreased levels of cellular oxidative stress and enhanced calcium homeostasis. 2DG treatment increased levels of the stress-responsive proteins GRP78 and HSP70 in hippocampal neurons, without affecting levels of Bcl-2 or GRP75, suggesting that mild reductions in glucose availability can increase neuronal resistance to oxidative and metabolic insults by a mechanism involving induction of stress proteins. Our findings establish cell culture and in vivo models of "chemical food restriction" which may prove useful in elucidating mechanisms of neuroprotection and in developing preventive approaches for neurodegenerative disorders that involve oxidative stress and excitotoxicity.

HSP70 induction may explain the long-lasting resistance to heat of Drosophila melanogaster having lived in hypergravity

In this study, we showed that in flies kept for 2 weeks at 1 (terrestrial gravity), 3 or 5 x g (hypergravity, HG) before transfer to 1 x g, resistance to heat remained higher in HG flies for several weeks after the transfer. The measurement of heat shock protein 70 (hsp70) indicated no induction of the protein in HG, but the study revealed that flies living in HG expressed more hsp70 only after being submitted to severe stress. The higher induction of hsp70 may explain the higher thermotolerance of these HG-treated young flies. Finally, an unknown protein was observed only in females. This protein may belong to a class of higher molecular weight hsp (hsp110), which have not previously been observed in Drosophila.

Inhibition of heat-shock protein 70 induction in intestinal cells overexpressing cyclooxygenase 2

BACKGROUND & AIMS

The cyclooxygenase (COX) enzymes catalyze the initial step of prostaglandin formation; the inducible form, COX-2, plays a role in inflammation. Heat-shock protein 70 (hsp70) is a stress-responsive gene important for cell survival; induction of hsp70 appears to be mediated, in part, by the prostaglandin pathway. We determined the effect of COX-2 overexpression on hsp70 induction in rat intestinal epithelial (RIE) cells.

METHODS

RIE cells transfected with COX-2 complementary DNA oriented in the sense (RIE-S) or antisense (RIE-AS) direction were subjected to a heat shock; RNA and protein were harvested and analyzed by Northern and Western blots, respectively. Gel shift assays were performed to assess DNA binding.

RESULTS

Both hsp70 messenger RNA and HSP70 protein levels were increased in the RIE-AS cells, whereas induction was markedly inhibited in the RIE-S cells after heat shock. Inhibition of heat-shock factor binding was noted in RIE-S cells, suggesting that heat-shock transcription factor regulation may explain the inhibition of hsp70. The COX-2 selective inhibitor, NS-398, reversed the effects of COX-2 overexpression.

CONCLUSIONS

The results support a functional role for the prostaglandin/COX pathway in the induction of hsp70. The findings underscore a potential regulatory mechanism involving an inverse relationship between COX-2 expression and hsp70 induction.