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.

Insufficient adaptive capability of pancreatic endocrine function in dexamethasone-treated ageing rats.

This study was aimed at exploring the capability of the pancreatic endocrine adaptive mechanisms of ageing Sprague-Dawley rats to counteract the metabolic challenge induced by the prolonged administration of dexamethasone (DEX) (0.13 mg/kg per day for 13 days). DEX treatment induced peripheral insulin resistance in 3-, 18- and 26-month-old rats, as indicated by the significant and persistent rise of plasma insulin levels in each age group (plasma insulin in 3-, 18- and 26-month-old rats from basal values of 4.3+/-0.8, 4.7+/-0.5 and 5.6+/-1.0 ng/ml (means+/-s.e.m.) respectively, rose to 11.9+/-1.7, 29.1+/-5.5 and 27.9+/-2.7 ng/ml respectively, after 9 days of administration). However, plasma glucose concentrations remained unchanged during the treatment in young rats, whereas they increased up to frankly diabetic levels in most 18-month-old and in all 26-month-old animals after a few days of DEX administration. Plasma free fatty acid concentrations increased 2-fold in 3- and 26-month-old rats and 4-fold in 18-month-old rats and could possibly be involved in the glucocorticoid-induced enhancement in insulin resistance, although they showed no significant correlation with glycaemic values. Incubation of pancreatic islets obtained from treated rats showed that DEX administration increased the insulin responsiveness of islets from not only younger but also older donors. However, in the islets of ageing rats, which already showed an age-dependent impairment of the sensitivity to glucose and other secretagogues, this enhancing effect was clearly attenuated with respect to the younger counterpart. Furthermore, DEX treatment depressed significantly the priming effect of glucose in islets isolated from all the three age groups. In conclusion, our results show that ageing rats are unable to counteract effectively a prolonged hyperglycaemic challenge as such induced by DEX administration. This homeostatic defect can be ascribed to the age-dependent failure of the endocrine pancreas to provide enough insulin to overcome the aggravation of an antecedent state of increased peripheral insulin resistance.

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.

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.

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.

Exploring the mechanisms of in vivo regulation of liver protein breakdown in the rat by the use of the new antilipolytic-agent model.

In this study, we explored the changes in the rate of protein degradation in liver cells in vivo, using a method based on the physiological stimulation of liver autophagy. Male albino rats 1, 2, 6, 12 and 24 months old were fasted overnight, and then received an injection of the antilipolytic agent 3,5-dimethylpyrazole (DMP) to evoke a sudden shortage of lipid fuel. A comparison was made with the in vivo effects of glucagon by giving the 2-month-old group an intraperitoneal injection of this hormone. Samples of liver were taken after 0, 15, 20, 30, 60 and 150 min and processed for electron microscopy, and groups of rats were subjected to short-term single pass liver perfusion. Results show that in the younger age-groups, the DMP stimulation of liver autophagy and amino acid release is highly significant, and compares favourably with the glucagon model of induction of the autophagic process. With older rats, an age-related longer time-lag of the autophagic response and a decrease in the effect of DMP were observed. In conclusion, hormones may activate autophagy, whereas levels of plasma amino acids may tune down the process to adjust the availability of the substrate to tissue needs.

The brown adipose tissue of hyperthyroid rats. A biochemical and ultrastructural study.

Male Sprague-Dawley rats were treated with triiodothyronine (100 micrograms/100 g/day) for 2, 4, 7, 14 and 21 days and the biochemical and ultrastructural changes of the brown adipose tissue were investigated. Results showed that the tissue weight, DNA and phospholipid content increased very early (by day 2 or 4) and that triglycerides increased later. These hormonal effects are not inhibited by the beta 1-antagonist propranolol. From the morphological point of view, triiodothyronine administration induced the early proliferation and maturation of adipocyte precursors (interstitial cells and preadipocytes). It is concluded that triiodothyronine administration causes a very early hyperplasia in the brown adipose tissue similar to that observed during exposure to cold by mechanisms that may not be secondary to the involvement of norepinephrine.

Mitochondrial myopathy in rats fed with a diet containing beta-guanidine propionic acid, an inhibitor of creatine entry in muscle cells.

In rats with phosphoryl-creatine depletion (fed a standard Randoin-Causeret diet containing 1% beta-guanidine propionic acid) abnormal mitochondria were observed in slow skeletal muscles, often containing paracrystalline inclusions very like those induced by ischaemia or mitochondrial poisons and in human mitochondrial myopathy.

Increased degradation in rat liver induced by antilipolytic agents: a model for studying autophagy and protein degradation in liver?

A dramatic increase in the plasma glucagon/insulin ratio can be induced by treating fasted rats with antilipolytic drugs (e.g., with 3,5-dimethylpyrazole, 12 mg/kg body wt). These hormone changes are the physiologically appropriate response to a rapid decrease in free fatty acids and glucose plasma levels. Under this experimental condition, many vacuolated lysosomes can be observed at the electron microscopic level as early as 30 min and autophagic vacuoles are detectable in the liver cells 1 hr after the administration of the drug. By 1 hr and 45 min, vacuoles often contain recognizable peroxisomes. At the biochemical level, liver proteolysis in vitro is increased significantly. Very interestingly, changes in peroxisomal (but not mitochondrial or reticulum or cytosolic) enzyme activities are detected that are preventable by the administration of glutamine (i.e., of an inhibitor of proteolysis in vivo) but not by an isocaloric amount of glycine or alanine. It is concluded that the administration of antilipolytic agents to fasted animals may provide a convenient (i.e., an inexpensive, highly reproducible and timable) physiologic model to study hormone-induced autophagy in liver cells.

Effects of antilipolytic agents on rat liver peroxisomes and peroxisomal oxidative activities.

The mechanisms involved in the inhibitory effects of antilipolytic agents on rat liver peroxisomal fatty acid oxidative activity have been explored. Treatment of fasting rats with antilipolytic drugs (either 3,5-dimethylpyrazole (12 mg/kg body weight) or Acipimox (25 mg/kg body weight] resulted in a decrease in free fatty acid and glucose plasma levels within 5-10 and in a significant increase in the plasma glucagon to insulin ratio within 15. Changes in the fatty acid oxidative activity appeared with a 2.5-3 h delay and were then very rapid (a 30-40% decrease in the activity occurred in additional 2 h). Many peroxisomal enzyme activities (including non-beta-oxidative activities such as uricase and D-amino acid oxidase) exhibited similar changes with the same delay. Simultaneously with the enzyme changes, at the electron microscope level many autophagic vacuoles were detected in the liver cells, often containing peroxisomal structures. Glutamine, an inhibitor of proteolysis in vivo, prevented the decrease in enzyme activities. It was concluded that the decrease in peroxisomal enzyme activities may be the consequence of enhanced peroxisome degradation due to the stimulation of autophagic processes in liver cells.

Effect of cold adaptation on liver peroxisomes and peroxisomal oxidative activities of rat. A morphometric/stereologic and biochemical study.

The variations in liver peroxisomes and in peroxisomal enzymes were studied in the rat during adaptation to cold (5 degrees C). An increase in the number and in the volume and surface fractions of peroxisomes was detected by day 7. Qualitative ultrastructural changes of the peroxisome compartment were observed. Several peroxisomal enzyme activities were found to exhibit a significant increase with different temporal patterns. These results are discussed with regard to the possible contribution of liver peroxisomes to non-shivering thermogenesis.