The role of macroautophagy in the ageing process, anti-ageing intervention and age-associated diseases.

Macroautophagy is a degradation/recycling system ubiquitous in eukariotic cells, which generates nutrients during fasting under the control of amino acids and hormones, and contributes to the turnover and rejuvenation of cellular components (long-lived proteins, cytomembranes and organelles). Tight coupling between these two functions may be the weak point in cell housekeeping. Ageing denotes a post-maturational deterioration of tissues and organs with the passage of time, due to the progressive accumulation of the misfunctioning cell components because of oxidative damage and an age-dependent decline of turnover rate and housekeeping. Caloric restriction (CR) and lower insulin levels may slow down many age-dependent processes and extend lifespan. Recent evidence is reviewed showing that autophagy is involved in ageing and in the anti-ageing action of anti-ageing calorie restriction: function of autophagy declines during adulthood and is almost negligible at older age; CR prevents the age-dependent decline of autophagic proteolysis and improves the sensitivity of liver cells to stimulation of lysosomal degradation; protection of autophagic proteolysis from the age-related decline co-varies with the duration and level of anti-ageing food restriction like the effects of CR extending lifespan; the pharmacological stimulation of macroautophagy has anti-ageing effects. Besides the involvement in ageing, macroautophagy may have an essential role in the pathogenesis of many age-associated diseases. Higher protein turnover may not fully account for the anti-ageing effects of macroautophagy, and effects of macroautophagy on housekeeping of the cell organelles, antioxidant machinery of cell membranes and transmembrane cell signaling should also be considered.

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.

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.

Effects of ageing and increased haemolysis on the levels of dolichol in rat spleen.

Dolichol is a long-chain polyisoprenoid. No enzyme pathway for dolichol degradation was discovered. Dolichol accumulates in human and rodent tissues during ageing. Red blood cells contain a larger amount of dolichol and red blood cell life span is shorter in older rats. The effects of age and of the load of dolichol from red blood cell degradation on the ageing-associated accumulation of dolichol in spleen were studied in 2, 6, 12, 18 and 24 month-old male Sprague Dawley rats fed ad libitum (AL) or on an anti-ageing dietary regimen (EOD). Tissue dolichol was extracted and assayed by HPLC [J. Gerontol. 53A (1998) B87]. Levels of dolichol increased in spleen, liver, kidney and muscle in parallel fashion from the age of 2 to 12 months. Unexpectedly, spleen dolichol decreased in older rats whereas liver, kidney and muscle dolichol increased significantly. The effects of haemolysis on spleen dolichol were tested by the administration of phenylhydrazine. Results show that haemolysis does not increase, but rather decreases the levels of dolichol in erythroclastic organs. It is concluded that the levels of spleen dolichol may decrease in the absence of any known enzymatic degradative pathway if the spleen and its resident phagocytes are forced to cope with a higher number of red blood cells to be cleared. Free-radical mediated decomposition of dolichol by phagocytic cells during erythrophagocytosis might be involved in the process.

Age-related changes in the autophagic proteolysis of rat isolated liver cells: effects of antiaging dietary restrictions.

Autophagy is a process that sequesters and degrades organelles and macromolecular constituents of cytoplasm for cellular restructuring and repair and as a source of nutrients for metabolic use in early starvation. The effects of two antiaging dietary regimens (initiated in rats at the age of 2 months), namely, 40% dietary restriction (DR) and every-other-day ad-libitum feeding, that exhibited different effects on metabolism and similar effects on longevity on the age-related changes in the regulation of autophagic proteolysis were studied by monitoring the rate of valine release in the incubation medium from isolated liver cells of male albino Sprague-Dawley rats aged 2, 6, 12, 18, 24, and 27 months. (The liver cells were incubated in vitro with added amino acids and 10(-7) M insulin or glucagon.) Age-matched male albino Sprague-Dawley rats fed ad libitum served as a control. Results show that in ad-libitum-fed rats, after a transient increase by age 6 months, autophagic proteolysis and regulation by amino acid exhibit a dramatic age-related decline, and that the age-related changes are prevented by dietary antiaging intervention. A comparison shows that the protective effects of DR and every-other-day ad-libitum feeding are partially different in 24-month-old rats (but the beneficial effects of the two diets on regulation of autophagic proteolysis are always similar). With regard to endocrine regulation, results confirm that the liver cell response to glucagon (but not to insulin) declines with increasing age, and they show that antiaging DRs significantly improve the effects of glucagon (and have no effect on the response to insulin). The interactions of age by diet, glucagon (and in older rats, insulin), and amino acids are significant. It is concluded that DR significantly improves the susceptibility of liver cells to lysosomal degradation, and it prevents decline with increasing age. It is suggested that improved liver autophagy and lysosomal degradation might be part of the antiaging mechanisms of DR.

Age-related changes in the regulation of autophagic proteolysis in rat isolated hepatocytes.

During intervals between meals, autophagy is a major source of nutrients and may remove damaged organelles and membranes. Age-related changes in the regulation of autophagic proteolysis were studied by monitoring the rate of valine release from liver cells of 2-, 6-, 12-, 18-, and 24-month-old male Sprague-Dawley rats fed ad libitum, and incubated in vitro with added amino acids and 10(-7) M of insulin or glucagon. The maximum rate of proteolysis and its maximum inhibition by amino acids were reached at 6 months and declined thereafter. In contrast, the rate of protein degradation in the presence of high concentrations of amino acids was not affected by aging. The inhibitor effect of insulin was additive to that of amino acids and was not altered significantly by age. The conclusion is that altered regulation of autophagic proteolysis decreases susceptibility of older cells to lysosomal degradation, and it may lead to the accumulation of altered organelles and membranes.

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.

The age-related accumulation of protein carbonyl in rat liver correlates with the age-related decline in liver proteolytic activities.

Increases of protein carbonyl in animal tissues have been associated with the aging process. So far, the accumulation of oxidized proteins, highly susceptible to proteolysis, has been attributed to age-related changes in proteasomal alkaline proteases. Carbonyl in protein was monitored in six different tissues of male Sprague-Dawley rats fed ad libitum up to the age of 27 months, and of 24 and 27-month-old rats subjected to anti-aging diet restriction (every-other-day feeding ad libitum). Alkaline protease activities and liver lysosomal proteolysis were studied. The levels of protein carbonyl were significantly different in different tissues, and quite stable throughout life; accumulation was restricted to liver tissue very late in life, between ages 24 and 27 months; was fully prevented by diet restriction; was not accompanied by any diet-restriction-sensitive decline of alkaline protease activity; and was accompanied by a dramatic age-related decline in lysosomal proteolysis that was partially prevented by anti-aging diet restriction. No correlation was found between levels of alkaline protease activity and levels of protein carbonyl in the different tissues from younger animals. It is concluded that the process of autophagy, a well-known mechanism for cell maintenance, may deserve more interest in aging studies.

Age-dependent accumulation of dolichol in rat liver: is tissue dolichol a biomarker of aging?

Dolichols are long hydrophobic molecules broadly distributed in all tissues and cellular membranes of eukariotic cells. Dolichol affects membrane structure and fluidity, membrane-associated protein activities, and membrane sensitivity to oxidative stress. Reports have shown that dolichols exhibit a remarkable (6- to 30-fold) age-related increase in the tissues of adult and mature rats and of old flies, mice, and humans. In our longitudinal study, the age-related accumulation of dolichol was monitored in the liver tissue of male Sprague Dawley rats fed ad libitum up to age of 27 months. In addition 24-month-old rats subjected to different regimens of anti-aging diet restriction (40% calorie restriction or every-other-day feeding ad libitum) were tested. A parallel study of the accumulation of carbonyl in liver protein (a proposed biomarker of aging) was made. In addition, the age-related decline of liver autophagy/proteolysis was studied in isolated liver cells, in view of the essential role of this function in liver membrane maintenance. Results show that an age-dependent accumulation of dolichol can be observed in the liver of the rats fed ad libitum but not in the liver of 24-month-old food-restricted rats, that accumulation of dolichol precedes the accumulation of altered liver proteins, and that dolichol accumulation is accompanied by a decline in liver autophagy. It is concluded that dolichol accumulation satisfies the proposed primary and secondary applicable criteria and the desirable features required to be qualified as a biomarker of aging.

The regulation of liver protein degradation by aminoacids in vivo. Effects of glutamine and leucine.

The effects in vivo of the two major in vitro regulatory aminoacids, leucine and glutamine, on liver protein degradation were explored in male young adult Sprague Dawley rats. Protein degradation was stimulated by the injection of the antilipolytic drug 3,5 dimethylpyrazole (DMP), which rises glucagon and lowers insulin plasma levels. At the appropriate time-points (20 and 40 min) after the injection of DMP, glutamine or leucine (12.5 mg/kg b.w.) were injected intraperitoneally. The rate of liver protein breakdown was evaluated 60 min after the injection of DMP on the basis of the release of valine into the perfusate during a short term single pass liver perfusion. The aminoacid was assayed by an HPLC procedure. Results show that the administration of glutamine inhibited the DMP-induced increase in the rate of valine release from the perfused liver whereas the administration of leucine did not; neither of the aminoacids appeared to have any effect on the metabolic or endocrine changes that are required for the induction of liver autophagy and protein breakdown by DMP. It is concluded that the aminoacid glutamine has a powerful action on the in vivo regulation of liver protein breakdown, which is not apparent with leucine.

Effects of different types of anti-aging dietary restrictions on age-related atrial natriuretic factor changes: an immunochemical and ultrastructural study.

The effects of two types of anti-aging dietary restrictions restrictions-60% diet restriction (DR) and every-other-day feeding (intermittent feeding, IF)-on age-related changes in atrial natriuretic factor (ANF) metabolism were studied in male Sprague Dawley rats by standard radioimmunological procedures and transmission electron microscopy. Both diet restrictions decreased plasma ANP (atrial natriuretic peptide) levels significantly (12-month-old rats: ad libitum fed controls 96 +/- 17.3 pg/mL, IF 63 +/- 4.8 pg/mL, DR 74 +/- 14.4 pg/mL; 24-month-old rats: AL 109 +/- 6.3 pg/mL, IF 75 +/- 8.9 pg/mL, DR 65 +/- 9.1 pg/mL). Dietary restriction prevented the age-related increase in ANP concentration in both the right atrium (12-month-old rats: AL 0.25 +/- 0.033 microgram/mg, IF 0.22 +/- 0.023 microgram/mg, DR 0.30 +/- 0.044 microgram/mg; 24-month-old rats: AL 0.39 +/- 0.037 microgram/mg, IF 0.10 +/- 0.015 microgram/mg, DR 0.07 +/- 0.011 microgram/mg) and left atrium (12-month-old rats: AL 0.23 +/- 0.033 microgram/mg, IF 0.13 +/- 0.019 microgram/mg, DR 0.17 +/- 0.035 microgram/mg; 24-month-old rats: AL 0.44 +/- 0.037 microgram/mg; IF 0.07 +/- 0.009 microgram/mg, DR 0.07 +/- 0.011 microgram/mg). Endocrine cardiocytes of diet-restricted senescent rats could be readily distinguished ultrastructurally from cells of ad libitum fed controls due to a higher number of beta-atrial specific granules of lower electrondensity. In conclusion, anti-aging diet restriction regimens fully prevented the age-related increase in the hormone store in atrial tissue, and lowered plasma ANP levels.

Changes in endocrine atrial rat cardiocytes during growth and aging: an ultrastructural, morphometric and endocrinological study.

The effects of age on atrial natriuretic factor (ANF) metabolism were studied in male Sprague Dawley rats by standard radioimmunological procedures, transmission electron microscopy, and ultrastructural morphometry. Plasma atrial natriuretic peptide (ANP) levels increased during growth (1-month-old rats: 64 +/- 8.7 pg/mL; 2-month-old rats: 105 +/- 8.1 pg/mL) and did not change thereafter. Immunoreactive (ir)-ANP concentration increased significantly in senescent rats, both in the right (12-month-old rats: 254 +/- 33 ng/mg; 24 month-old: 415 +/- 77 ng/mg) and left atrium (226 +/- 30 and 498 +/- 60 respectively). The ultrastructural morphological features of the endocrine cardiocytes of senescent rats were the presence of a few lysosomal structures and atrial specific granules of higher electron-density. Ultrastructural morphometry studies did not reveal any significant increase in the number or in the mean individual volume of atrial specific granules, compared with young adult rats. In conclusion, unlike younger rats, morphometric data in older and senescent rats show that atrial granularity may not necessarily change together with atrial ir-ANP contents; ir-hormone assay findings show that senescent rats have ANP plasma levels within the norm, and a much larger hormone store in atrial tissue.

Endocrine and amino acid regulation of liver macroautophagy and proteolytic function.

Regulation of liver macroautophagy and protein degradation by hormones and direct regulatory amino acids were studied in male 2-mo-old Sprague-Dawley albino rats with the use of the antilipolytic agent 3,5'-dimethylpyrazole (DMP; 12 mg/kg body wt ip) as a stimulatory agent. Injection of DMP decreased glutamine plasma levels and glutamine release from the perfused liver. Autophagic vacuoles were observed in the pericanalicular area of liver cells after 30 min. Levels and release of other regulatory amino acids did not exhibit any significant decrease but subsequently increased. Intraperitoneal administration of glutamine inhibited the proteolytic response. In conclusion, these studies demonstrate that in vivo induction and control of liver macroautophagy and protein degradation by the physiological mechanism (i.e., by shortage of nutrients) involve unbalanced and asynchronous changes in the levels of selected direct regulatory amino acids (i.e., a decrease in glutamine and a subsequent increase in leucine and tyrosine levels).

The induction of mitochondrial myopathy in the rat by feeding beta-guanidinopropionic acid and the reversibility of the induced mitochondrial lesions: a biochemical and ultrastructural investigation.

The long-lasting depletions of creatine phosphate induced by feeding rats with a beta-guanidinopropionic acid (GPA)-supplemented diet induces specific mitochondrial alterations in skeletal muscles very similar to those observed in human mitochondrial myopathies. The slow-twitch soleus muscle appears to be affected primarily, while the fast-twitch extensor digitorum longus is affected less severely and only after a longer period of treatment (6 months). Changes in the enzyme activities of glucose metabolism appear to be secondary and differ between the two muscles. Withdrawal of GPA from the diet after 2 months of treatment shows that both mitochondrial alterations and biochemical modification are reversible.

Beneficial effects of the oral administration of vanadyl sulphate on glucose metabolism in senescent rats.

We investigated the effects of the oral administration of vanadyl sulphate (0.5 mg/ml in the drinking water) on glucose homeostasis of 3-month- and 24-month-old rats. Results show that aging is associated with alteration of the oral glucose tolerance test and impairment of the postprandial accumulation of glycogen in skeletal muscles and that the oral administration of vanadyl sulphate rapidly normalizes the inbalance of glucose metabolism in senescent rats. It is suggested that vanadate administration may restore the ability of skeletal muscles of senescent rats to respond to circulating insulin efficiently.

A new method for the investigation of endocrine-regulated autophagy and protein degradation in rat liver.

The effect of the antilipolytic agent 3,5-dimethylpyrazole (DMP) on liver autophagy and protein degradation was studied on male young adult rats (200 g body wt) of the Sprague-Dawley strain by electron microscopy and short-term single-pass liver perfusion and HPLC amino acid assay in the perfusate. Treatment with DMP (12 mg/kg body wt) enlarged the lysosomal-autophagic compartment in liver cells in 30 min and increased significantly the concentrations of valine and total amino acid in blood plasma (taken at sacrifice) and valine concentration in the liver perfusate in 60 min. These effects of DMP stimulating liver were secondary to the metabolic and endocrine effects of the drug (which caused a decrease in FFA, glucose, and insulin and an increase in glucagon and corticosterone plasma levels with a shorter latency, about 15 min). The effects of DMP were compared to those of other treatments inducing liver autophagy and protein degradation in vivo. Alterations after DMP or glucagon injections were similar, but they were larger and lasted for a longer time with DMP administration. Treatment with vinblastine or chloroquine enlarged the lysosomal-autophagic compartment without increasing protein breakdown.

Effects of the administration of thyroid hormone on the plasma levels of atrial natriuretic peptides and on atrial myoendocrine cells in the rat: an immunochemical, ultrastructural, and stereological study.

The effects of an altered thyroidal status on the levels of immunoreactive (ir-) atrial natriuretic peptide (ANP) in serum and in the right and left atria, as well as on the subcellular structures of atrial myoendocrine cells were explored in groups of male Sprague Dawley rats given the vehicle or triiodothyronine in the toxicological dose-range (50 micrograms/100 g bw/day) for 0,5, 1,2,4,7 or 14 days. Plasma levels of ir-ANP were 30% higher in T3-treated rats compared with controls at 0,5 and 1 day after hormone administration and then decreased to levels 30-40% lower than controls at days 2 and 4 to rise again above control values on day 7 and 14. Atrial ir-ANP levels decreased at first both in the right and in the left atria with different latencies (1 and 2 days, respectively) and rose back towards control levels by day 4. Changes in the numerical density of specific granules followed a parallel temporal pattern. An increased in the individual volume of the granules followed was also observed. Investigation into the circulatory effects of T3 administration showed that the heart rate was increased by hour 12 after hormone administration (simultaneously with the early rise in plasma ir-ANP levels) and that blood pressure was increased by day 2.(ABSTRACT TRUNCATED AT 250 WORDS)