Gabriella Cavallini

The anti-ageing effects of caloric restriction may involve stimulation of macroautophagy and lysosomal degradation, and can be intensified pharmacologically.

Caloric restriction (CR) and a reduced growth hormone (GH)-insulin-like growth factor (IGF-1) axis are associated with an extension of lifespan across taxa. Evidence is reviewed showing that CR and reduced insulin of GH-IGF-1 axis may exhibit their effects at least partly by their common stimulatory action on autophagy, the cell repair mechanism responsible for the housekeeping of cell membranes and organelles including the free radical generators peroxisomes and mitochondria. It is shown that the life-long weekly administration of an anti-lipolytic drug may decrease glucose and insulin levels and stimulate autophagy and intensify anti-ageing effects of submaximal CR.

Ageing-related changes in the in vivo function of rat liver macroautophagy and proteolysis.

Autophagy is a universal, highly regulated mechanism responsible for the degradation of long-lived proteins, cytomembranes and organelles during fasting and may be the cell repair mechanism that mediates the anti-ageing effects of calorie restriction (Bergamini and Gori, 1995). The function of autophagy was studied in vivo on male Sprague Dawley rats fed ad libitum or 40% food restricted. Autophagy was induced in overnight fasted rats by the injection of an anti-lipolytic agent and was investigated by electron microscopy. Changes in regulatory plasma nutrients and hormones were assessed and rate of proteolysis was calculated from the release of 14C(6)-valine from pre-labelled resident proteins. Results in rats fed ad libitum showed that autophagic-proteolytic response to antilypolitic agents was paramount in one month-old rats; was high but delayed in 2 month-old rats, decreased remarkably in 6 month-old rats and almost negligible at older age. Parallel ageing-related changes were observed in the effects of treatment lowering glucose and insulin plasma levels. Calorie restriction prevented all changes. In view of the known suppressive effects of insulin, it may be concluded that the age-changes of autophagy are secondary to the ageing-related alteration in glucose metabolism and hormone levels, whose appearance is delayed by calorie restriction. Data may support the hypothesis that ad libitum feeding accelerates the rate of ageing by raising insulin plasma levels and suppressing autophagy and membrane maintenance, and that calorie restriction may break this vicious circle.

The role of autophagy in aging: its essential part in the anti-aging mechanism of caloric restriction.

Abstract:  Aging denotes a postmaturational deterioration of cells and organisms with the passage of time, an increased vulnerability to challenges and prevalence of age‐associated diseases, and a decreased ability to survive. Causes of this deterioration may be found in an enhanced production of reactive oxygen species (ROS) and oxidative damage and incomplete “housekeeping.” Caloric restriction is the most robust anti‐aging intervention known so far. Similar beneficial effects on median and maximum life span were obtained by feeding animals a 40%‐reduced diet or by every‐other‐day ad libitum feeding. In both instances, animals are forced to spend a great part of their time in a state of fasting and activated autophagy. Autophagy is a highly conserved process in eukaryotes, in which the cytoplasm, including excess or aberrant organelles, is sequestered into double‐membrane vesicles and delivered to the lysosome/vacuole, for breakdown and eventual recycling of the resulting macromolecules. This process has an essential role in adaptation to fasting and changing environmental conditions, cellular remodeling during development, and accumulation of altered ROS‐hypergenerating organelles in older cells. Several pieces of evidence show that autophagy is involved in aging and is an essential part of the anti‐aging mechanism of caloric restriction. As an application, intensification of autophagy by the administration of an antilipolytic drug rescued older cells from accumulation of altered mtDNA in less than 6 hours. It is concluded that the pharmacologic intensification of autophagy (PISA treatment) has anti‐aging effects and might prove to be a big step toward retardation of aging and prevention of age‐associated diseases in humans.

Autophagic Degradation Contributes to Muscle Wasting in Cancer Cachexia

Muscle protein wasting in cancer cachexia is a critical problem. The underlying mechanisms are still unclear, although the ubiquitin-proteasome system has been involved in the degradation of bulk myofibrillar proteins. The present work has been aimed to investigate whether autophagic degradation also plays a role in the onset of muscle depletion in cancer-bearing animals and in glucocorticoid-induced atrophy and sarcopenia of aging. The results show that autophagy is induced in muscle in three different models of cancer cachexia and in glucocorticoid-treated mice. In contrast, autophagic degradation in the muscle of sarcopenic animals is impaired but can be reactivated by calorie restriction. These results further demonstrate that different mechanisms are involved in pathologic muscle wasting and that autophagy, either excessive or defective, contributes to the complicated network that leads to muscle atrophy. In this regard, particularly intriguing is the observation that in cancer hosts and tumor necrosis factor α-treated C2C12 myotubes, insulin can only partially blunt autophagy induction. This finding suggests that autophagy is triggered through mechanisms that cannot be circumvented by using classic upstream modulators, prompting us to identify more effective approaches to target this proteolytic system.

The protection of rat liver autophagic proteolysis from the age-related decline co-varies with the duration of anti-ageing food restriction

Restricting caloric intake (CR) well below that of ad libitum (AL) fed animals retards and/or delays many characteristics of ageing and the occurrence and progression of age-associated diseases, efficacy depending on duration. The hypothesis that the anti-ageing effect of CR might involve stimulation of the cell-repair mechanism autophagy was tested. The effects of ageing and duration of anti-ageing CR on liver autophagic proteolysis (AP) were explored in male AL Sprague-Dawley rats aged 2-, 6-, 12- and 24-months; and 24-month-old rats on a CR diet initiated at 2-, 6- and 12-month of age or initiated at age 2-months and interrupted at age 18 months. The age-related changes in the regulation of AP were studied by monitoring the rate of valine release in the incubation medium from isolated liver cells by an HPLC procedure. Results show that the maximum attainable rate and the regulation of AP decline with increasing age; that changes are prevented by anti-ageing CR initiated at young age, that the protective effects of CR change with the duration of diet. It is concluded that the data are compatible with the hypothesis that AP and improved membrane maintenance might be involved in the antiageing mechanism of CR.

Alternate-day fasting protects the rat heart against age-induced inflammation and fibrosis by inhibiting oxidative damage and NF-kB activation

The free radical theory of aging is currently one of the most popular. In parallel, many studies have demonstrated the association of fibrosis and increased oxidative stress in the pathogenesis of some chronic human diseases, and fibrosis is often characteristic of aging tissues. One of the few interventions that effectively slow aging is calorie restriction and the protection against the age-associated increase of oxidative stress remains one of the foremost hypotheses to explain this action. As an alternative to traditional calorie restriction, another dietary regimen, termed alternate-day fasting, has also been tested, whose antiaging mechanisms have not been explored so much extensively. We thus studied the effects of alternate-day fasting, started at 2 months of age, on oxidative stress and fibrosis in the heart during aging. In the left ventricle of the heart of elderly (aged 24 months) versus young (aged 6 months) male rats we found a significant increase in oxidative stress paralleled by increased fibrosis. In parallel there was a significant increase in inflammatory cytokine levels and in NF-kB DNA binding activity with advancing age. Alternate-day fasting protected against all these age-related phenomena. These data support the hypothesis that this kind of dietary restriction protects against age-related fibrosis, at least in part by reducing inflammation and oxidative damage, and this protection can thus be considered a factor in the prevention of age-related diseases with sclerotic evolution.

Evidence for selective mitochondrial autophagy and failure in aging.

Autophagy is a major intracellular degradation/recycling system ubiquitous in eukaryotic cells. It contributes to the turnover of cellular components by delivering portions of the cytoplasm and organelles to lysosomes, where they are digested. Starvation-induced autophagy is required for maintaining an amino acid pool for gluconeogenesis and for the synthesis of proteins essential to survival under starvation conditions. In addition, autophagy plays an important role in the degradation of excess or injured organelles, including mitochondria. To test the hypothesis of an involvement of a decrease in autophagy in the process of aging, we explored the antiaging effects of pharmacological stimulation of autophagy on the age-dependent accumulation of 8-OHdG-rich mitochondria in rat liver. Male 3-month and 16-month-old 24 hours-fasted Sprague Dawley rats were injected with the antilipolytic agent [3,5-dimethylpyrazole (DMP)] intraperitoneally. Results showed that drug injection rescued older cells from the accumulation of 8-OHdG in the mtDNA in less than 6 hours, but no significant decrease in the level of cytocrome c oxidase activity was observed. Together, these data provide indirect evidence that 8-OHdG might accumulate in a small pool of mitochondria with increasing age rather than be degraded by the autophagic machinery selectively. Addendum to: Stimulation of Macroautophagy Can Rescue Older Cells from 8-OHdG mtDNA Accumulation: A Safe and Easy Way to Meet Goals in the SENS Agenda A. Donati, M. Taddei, G. Cavallini and E Bergamini Rejuvenation Res 2006; 9:408-12

Ageing and oxidative stress: A role for dolichol in the antioxidant machinery of cell membranes?

Dolichol is a polyprenol compound broadly distributed in membranes, biosynthetized by the general isoprenoid pathway from acetate via mevalonate and farnesyl pyrophosphate. Dolichol lays inside the membrane between the two leaflets of the lipid bilayer very close to the tail of phospholipid fatty acids. No definite catabolic pathways for this molecule have yet been identified. Evidence is produced that dolichol levels increase dramatically with increasing age; that anti-ageing caloric restriction retards this age-associated change; that dolichol may act as a radical scavenger of peroxidized lipids belonging to the cell membranes. In view of the polyunsaturated fatty acids (PUFA), dolichol and Vitamin E location and stechiometry, it is proposed that molecules might interact each-other to form a highly matched free-radical-transfer chain, whose malfunctioning might be involved in statin toxicity and neurodegenerative diseases.

Effects of aging and anti-aging caloric restrictions on carbonyl and heat shock protein levels and expression

Heat shock proteins (Hsps) are induced by stressful stimuli and have been shown to protect cells and organs from such stresses both in vitro and in vivo, and play a positive role in lifespan determination. An attenuated response to stress is characteristic of senescence and no Hsp induction is observed upon exposure to stress and no protective effect of a mild stress is observed in cells from aged individuals. The artificial over-expression of Hsps, can produce a protective effect against a variety of damaging stimuli in cells from aged rats or aged humans, in whom cardiovascular disease is a major cause of morbidity in older age. Here, we show that aging significantly decreases the levels of Hsp27, Hsp60, Hsp72 and Hsc70 in right atrium and left ventricle of the rat heart, both at level of protein and of mRNA. Two different caloric restriction regimens have been found to counteract in part the decrease in the levels of Hsp expression in the aged heart tissue as well as the tendency to an increase of the levels of carbonyl in cardiac proteins. Our data suggest that cardiac Hsp levels may be a determinant of longevity in rodents, and that generation of new regimens of caloric restriction may eventually show how to improve modulation of cardiac aging.

Age-related changes of cholesterol and dolichol biosynthesis in rat liver

Ageing has been defined as a gradually decreased ability to maintain homeostatic potential and increased risk to die, associated with a tissue accumulation of altered proteins and lipids. Among other, increased concentration of an isoprenoid compound, dolichol (Dol), in mammalian tissues during ageing has been reported and it has been considered as a new biomarker of ageing. However, the mechanism and the role of this accumulation is still unknown. Aim of this work was to study the mechanism of age-dependent Dol accumulation in the liver analysing the activity of the hepatic rate-limiting enzyme of isoprenoid biosynthesis, the 3-hydroxy 3-methylglutaryl CoA reductase (HMGCoA reductase), the Dol synthesis by mevalonate (MVA), the Dol level in the plasma, and the cholesterol (Chol) synthesis and content of ageing rat fed ad libitum (AL) or subjected to the effect of food restriction. Since the caloric restrictions are the most reproducible way to slow ageing and to extend life span, animals on these nutritional regimens were used to study ageing related mechanisms. The data show that during ageing the hepatic Dol accumulation is associated with an increase of HMGCoA reductase activity, which is affected by diet restriction, and with an increase of MVA incorporation in Dol and Chol, which is not. In addition, the liver of aged rats maintains the capability to regulate its Chol content and to modify Chol delivery into the blood.