Dietary restriction and beta-cell sensitivity to glucose in adult male rhesus monkeys

We examined the effects of dietary restriction (DR) and age on ss-cell function and peripheral insulin sensitivity in rhesus monkeys. A semipurified diet was provided either ad libitum for approximately 8 hours/day to controls (C) or as approximately 70% of baseline intake to restricted (R) animals for 10 years. The minimal model of C-peptide secretion and kinetics and the labeled 2-compartment minimal model of glucose kinetics were identified using plasma glucose, C-peptide, and insulin concentrations during an intravenous glucose tolerance test. R monkeys had less body fat, lower basal ss-cell sensitivity to glucose (?(b)), greater insulin sensitivity, and lower first-phase plasma insulin response. DR did not significantly affect first-phase and second-phase ss-cell sensitivity to glucose. Indices of body fatness were highly predictive of the effect of DR on ?(b), fasting insulin concentration and insulin responses to glucose. Enhanced peripheral insulin sensitivity among R monkeys was strongly correlated with lower ?(b).     

Caloric restriction and cardiovascular aging in cynomolgus monkeys (Macaca fascicularis): metabolic, physiologic, and atherosclerotic measures from a 4-year intervention trial

Caloric restriction (CR) retards aging processes, extends maximal life span, and consistently improves insulin resistance in lower species. Insulin resistance is associated with cardiovascular disease, but data is lacking demonstrating that increased insulin sensitivity reduces atherosclerosis progression. We initiated a study in 32 adult cynomolgus monkeys to evaluate increased insulin sensitivity secondary to CR on atherosclerosis extent. Following pretrial determinations, animals were randomized to a moderately atherogenic (0.25 mg cholesterol/Cal containing 30% of calories from fat)-fed control group or CR group (30% reduction) with equivalent dietary cholesterol intake. CR significantly improved insulin sensitivity and reduced intraabdominal fat over the 4-year intervention, while no significant differences were seen for the lipid profile between groups. Despite improved insulin sensitivity with CR, atherosclerosis extent did not differ between the ad libitum-fed or CR groups. These studies demonstrate that CR significantly improves insulin sensitivity, but when elevated plasma cholesterol concentrations were held similar, there was no effect on atherosclerosis extent. However, the composition of these lesions and changes in endothelial function may have been improved but were not evaluated in this study. Thus, further studies are needed to determine if improved insulin sensitivity might decrease arterial inflammation and improve endothelial function, despite no changes in atherosclerosis extent.     

Attenuation of sarcopenia by dietary restriction in rhesus monkeys

Sarcopenia, the loss of muscle mass with normal aging, devastates quality of life-and related healthcare expenditures are enormous. The prevention or attenuation of sarcopenia would be an important medical advance. Dietary restriction (DR) is the only dietary intervention that consistently extends median and maximum life span, as well as health span in rodents. Evidence suggests that DR will have a similar effect in primates. Furthermore, DR opposes sarcopenia in rodents. We tested the hypothesis that DR will reduce age-related sarcopenia in a nonhuman primate. Thirty adult male rhesus monkeys, half fed a normal calorie intake and half reduced by 30% in caloric intake, were examined over 17 years for changes in dual-energy X-ray absorptiometry-estimated skeletal muscle mass. Body weight-adjusted skeletal muscle mass declined somewhat in both groups but was far more rapid in the control group. We have shown that moderate, adult-onset DR can attenuate sarcopenia in a nonhuman primate model.     

Hypoglycemic 'stress' and gonadotropin-releasing hormone pulse generator activity in the rhesus monkey: role of the ovary.

Observations of long standing have suggested that the 'stress' of chair restraint inhibits the GnRH pulse generator in normal female monkeys while this phenomenon is rarely observed in ovariectomized animals. The role of the ovary in the response of the GnRH pulse generator to the stress of insulin hypoglycemia was investigated in both intact and ovariectomized rhesus monkeys. Following an overnight fast the animals, previously habituated to restraint, were placed in primate chairs and GnRH pulse generator activity monitored electrophysiologically. Insulin-induced reductions in mean blood glucose concentrations of 10-40% of control values interrupted pulse generator activity in intact monkeys but were without effect in ovariectomized animals. With larger reductions in blood glucose, pulse generator activity was interrupted in both groups but the inhibition was twice as long in intact than in ovariectomized animals. The reduced responsiveness of ovariectomized animals to insulin hypoglycemia was significantly reversed by estradiol replacement. Naloxone administration did not prevent the hypoglycemia-induced inhibition of pulse generator activity in either intact or ovariectomized rhesus monkeys. It is concluded that hypoglycemic 'stress' inhibits the GnRH pulse generator by a nonopioidergic mechanism and that ovarian products, most probably estradiol, exacerbate this effect.     

Strategy for identifying biomarkers of aging in long-lived species

If effective anti-aging interventions are to be identified for human application, then the development of reliable and valid biomarkers of aging are essential for this progress. Despite the apparent demand for such gerotechnology, biomarker research has become a controversial pursuit. Much of the controversy has emerged from a lack of consensus on terminology and standards for evaluating the reliability and validity of candidate biomarkers. The initiation of longitudinal studies of aging in long-lived non-human primates has provided an opportunity for establishing the reliability and validity of biomarkers of aging potentially suitable for human studies. From the primate study initiated in 1987 at the National Institute on Aging (NIA), the following criteria for defining a biomarker of aging have been offered: (1) significant cross-sectional correlation with age; (2) significant longitudinal change in the same direction as the cross-sectional correlation; (3) significant stability of individual differences over time. These criteria relate to both reliability and validity. However, the process of validating a candidate biomarker requires a greater standard of proof. Ideally, the rate of change in a biomarker of aging should be predictive of lifespan. In short-lived species, such as rodents, populations differing in lifespan can be identified, such as different strains of rodents or groups on different diets, such as those subjected to calorie restriction (CR), which live markedly longer. However, in the NIA primate study, the objective is to demonstrate that CR retards the rate of aging and increases lifespan. In the absence of lifespan data associated with CR in primates, validation of biomarkers of aging must rely on other strategies of proof. With this challenge, we have offered the following strategy: If a candidate biomarker is a valid measure of the rate of aging, then the rate of age-related change in the biomarker should be proportional to differences in lifespan among related species. Thus, for example, the rate of change in a candidate biomarker of aging in chimpanzees should be twice that of humans (60 vs 120 years maximum lifespan); in rhesus monkeys three times that of humans (40 vs 120 years maximum lifespan). The realization of this strategy will be aided by developing a primate aging database, a project that was recently launched in cooperation with the NIA, the National Center for Research Resources, and the University of Wisconsin Regional Primate Research Center.     

In vitro oxidation of low-density lipoprotein in two species of nonhuman primates subjected to caloric restriction

Caloric restriction (CR), which increases longevity and retards age-associated diseases in laboratory rodents, is being evaluated in nonhuman primate trials. CR reduces oxidative stress in rodents and appears to improve risk factors for cardiovascular disease in nonhuman primates. We tested the hypothesis that low-density lipoprotein (LDL) oxidizability is reduced in two monkey species (rhesus and cynomolgus) subjected to chronic CR. In both species, no significant differences occurred between CR and control animals on total, LDL, or high-density lipoprotein (HDL) cholesterol. In rhesus monkeys, triglycerides were higher in controls than CR (139 +/- 23 vs 66 +/- 8 mg/dl,p < .01, respectively). LDL from CR rhesus monkeys was reduced in triglyceride content and molecular weight compared to controls, whereas LDL composition in cynomolgus monkeys was similar in CR and control animals. In keeping with minor deviations in lipids, antioxidants, and LDL composition, no consistent differences in in vitro LDL oxidizability were apparent between CR and controls in either species.     

Influences of aging and dietary restriction on red blood cell density profiles and antioxidant enzyme activities in rhesus monkeys

Dietary restriction (DR) retards aging processes in rodents and other animals but its influence on aging in primates is unknown. In rats, the average density of red blood cells (RBCs) reportedly increases with RBC age and decreases with host age and RBC antioxidant enzyme activities fall with both types of aging. We determined RBC density profiles and antioxidant enzyme activities in four groups (n = 5) of male rhesus monkeys. The “Control” group (11–14 years) was fed a purified diet ad lib and the “DR” group (11–16 years) were fed 70% of the ad lib level for two years. “Young” (6–10 years) and “Old” (27–36 years) monkeys were fed a nonpurified diet ad lib. The average RBC size was least in the most dense fraction (F4) and internal structural complexity increased with RBC density based on flow cytometry analysis but these were not influenced by host age or DR. Catalase activity decreased with increasing density. In contrast to findings in rats, age and fraction differences in glutathione peroxidase activities were insignificant. DR did not influence enzyme activities. These data suggest that aging in rhesus monkeys influences RBC density profiles and antioxidant enzyme activities far less strikingly than has been reported in rats.     

Nonhuman primate models in biogerontology

A variety of animal models are utilized in biogerontological studies including yeast, nematodes, fruit flies, hamsters, mice, rats, and nonhuman primates. Species selection for research is based on many factors including economic feasibility, husbandry, generalizability of findings, available background information, adaptability to experimentation, and often, relevance to human aging. Each model offers its own strengths and limitations; however, nonhuman primates offer the unique advantage of phylogenetic proximity to humans. Among others, costs to purchase and maintain research subjects represent major limitations of nonhuman primate models. Although several nonhuman primate species have been utilized in aging research, rhesus monkeys (Macaca mulatta) are the best characterized and most extensively studied in biomedical gerontology. Nonhuman primate models have been employed as models for human aging in many research areas including neurobiology, skeletal, and reproductive aging and age-related diseases such as cardiovascular disease and diabetes. Primate models are now also being utilized to study interventions into aging such as caloric restriction. It will be several more years until definitive conclusions regarding lifespan effects can be made. However, existing data strongly suggest that many of the beneficial effects reported in rodents on CR also occur in primate models thereby strengthening the possibility that this nutritional paradigm may also impact favorably upon human aging.     

Calorie restriction in rhesus monkeys

Calorie restriction (CR) extends lifespan and reduces the incidence and age of onset of age-related disease in several animal models. To determine if this nutritional intervention has similar actions in a long-lived primate species, the National Institute on Aging (NIA) initiated a study in 1987 to investigate the effects of a 30% CR in male and female rhesus macaques (Macaca mulatta) of a broad age range. We have observed physiological effects of CR that parallel rodent studies and may be predictive of an increased lifespan. Specifically, results from the NIA study have demonstrated that CR decreases body weight and fat mass, improves glucoregulatory function, decreases blood pressure and blood lipids, and decreases body temperature. Juvenile males exhibited delayed skeletal and sexual maturation. Adult bone mass was not affected by CR in females nor were several reproductive hormones or menstrual cycling. CR attenuated the age-associated decline in both dehydroepiandrosterone (DHEA) and melatonin in males. Although 81% of the monkeys in the study are still alive, preliminary evidence suggests that CR will have beneficial effects on morbidity and mortality. We are now preparing a battery of measures to provide a thorough and relevant analysis of the effectiveness of CR at delaying the onset of age-related disease and maintaining function later into life.     

Calorie restriction lowers body temperature in rhesus monkeys, consistent with a postulated anti-aging mechanism in rodents.

Many studies of caloric restriction (CR) in rodents and lower animals indicate that this nutritional manipulation retards aging processes, as evidenced by increased longevity, reduced pathology, and maintenance of physiological function in a more youthful state. The anti-aging effects of CR are believed to relate, at least in part, to changes in energy metabolism. We are attempting to determine whether similar effects occur in response to CR in nonhuman primates. Core (rectal) body temperature decreased progressively with age from 2 to 30 years in rhesus monkeys fed ad lib (controls) and is reduced by approximately 0.5 degrees C in age-matched monkeys subjected to 6 years of a 30% reduction in caloric intake. A short-term (1 month) 30% restriction of 2.5-year-old monkeys lowered subcutaneous body temperature by 1.0 degrees C. Indirect calorimetry showed that 24-hr energy expenditure was reduced by approximately 24% during short-term CR. The temporal association between reduced body temperature and energy expenditure suggests that reductions in body temperature relate to the induction of an energy conservation mechanism during CR. These reductions in body temperature and energy expenditure are consistent with findings in rodent studies in which aging rate was retarded by CR, now strengthening the possibility that CR may exert beneficial effects in primates analogous to those observed in rodents.     

Effect of long-term caloric restriction on GLUT4, phosphatidylinositol-3 kinase p85 subunit, and insulin receptor substrate-1 protein levels in rhesus monkey skeletal muscle

Caloric restriction (CR), a reduction in calorie intake without malnutrition, improves insulin sensitivity in various species, including mice, rats, rhesus and cynomolgus monkeys, and humans. Skeletal muscle is quantitatively the most important tissue for blood glucose clearance. Therefore, we assessed the effect of 6 years of CR (30% reduction in calorie intake) in male rhesus monkeys (14-20 years old) on muscle expression of several proteins involved in insulin action. Whole body insulin sensitivity (assessed by Modified Minimal Model) was significantly increased in CR relative to Control monkeys. CR did not alter the expression of GLUT4 glucose transporter or phosphatidylinositol-3 kinase p85 subunit (PI3K). Insulin receptor substrate-1(IRS-1) abundance tended to be greater for CR compared to Control monkeys (p = .051), but correlational analysis revealed no association between IRS-1 and insulin sensitivity (r2 = .075, p = .271). These findings indicate that the CR-induced increase in insulin sensitivity in rhesus monkeys is unrelated to alterations in GLUT4, P13K, and IRS-1 abundance.     

Plasma concentrations of glucose, insulin, and percent glycosylated hemoglobin are unaltered by food restriction in rhesus and squirrel monkeys.

Plasma concentrations of glucose and percentage of glycosylated hemoglobin have been reported to be reduced in food-restricted rats when compared with ad libitum-fed controls (Masoro et al., 1989). A similar experiment in primates, in which we also measured plasma insulin, is reported in this article. Rhesus and squirrel monkeys were fed either ad libitum or 30% less than weight-matched controls for up to 36 months. No significant age or diet effects on plasma concentration of glucose, insulin, or percentage glycosylated hemoglobin were observed, except that glucose concentration decreased with age in ad libitum-fed rhesus monkeys. Moreover, no correlations between glucose levels and the percentage of glycosylated hemoglobin could be established within any group of animals. These results suggest possible differences in glucose-related metabolism in ad libitum and food-restricted primates as compared to observations made in rats.     

Late onset of dietary restriction reverses age-related decline of malate–aspartate shuttle enzymes in the liver and kidney of mice

Dietary restriction (DR) influences several physiological processes, retards the incidences and severity of various age-related diseases and extends lifespan of various animal species. The effect of DR on the activities of malate–aspartate shuttle enzymes, viz. cytosolic and mitochondrial aspartate aminotransferase (c- and m-AsAT) and malate dehydrogenase (c- and m-MDH) was investigated in the liver and kidney of adult (5-months) and old (21-months) male mice. The results show that the activity (U/mg protein) of both c- and m-MDH and AsAT is decreased significantly in the liver and kidney of old mice compared to adult ones. However, DR in old mice reverses significantly the enzyme activities to a level closer to adult animals. Polyacrylamide gel electrophoresis (PAGE) and specific staining of c-AsAT, one of the selected isoenzymes of the shuttle, showed a similar pattern of activity expression as observed by activity measurements in both the tissues studied. Slot blot analysis of c-AsAT confirmed the lower protein content of this isoenzyme in old mice compared to adult ones and a higher level in old-dietary restricted mice. Thus, our results suggest that the late onset of DR in older mice reverses decline in malate–aspartate shuttle enzymes and that it may allow a better metabolic regulation in older animals.     

Menopausal increases in pulsatile gonadotropin-releasing hormone release in a nonhuman primate (Macaca mulatta)

Reproductive function in all vertebrates is controlled by the circhoral release of the neuropeptide, GnRH, into the portal capillary system leading to the anterior pituitary. Despite its primary role in sexual maturation and the maintenance of adult reproductive function, changes in the concentrations and pattern of GnRH release have not yet been reported in any primate species during the menopausal transition and postmenopause. Such knowledge is essential for ascertaining both the mechanisms for, and consequences of, the menopausal process. Here we used a push-pull perfusion method to measure and compare the parameters of pulsatile GnRH release in adult rhesus monkeys at 8.4 +/- 1.5 yr (young adult females, early follicular phase, n = 6) and 28.8 +/- 0.3 yr (aged females, n = 4, of which two monkeys were in the menopausal transition, and two were postmenopausal). Our results demonstrate that: 1) GnRH release is pulsatile in both young and aged monkeys; 2) mean concentrations of GnRH increase during reproductive aging; and 3) GnRH pulse frequency does not differ between aged monkeys and young monkeys in the early follicular phase. We conclude that not only do GnRH neurons have the continued capacity to release GnRH in a pulsatile manner but also they can do so with enhanced GnRH levels in aged primates. To our knowledge, this is the first direct demonstration of elevated pulsatile GnRH concentrations in a primate species during reproductive senescence, a result that may have implications for menopausal symptoms.     

Effects of calorie restriction on chromosomal stability in rhesus monkeys (<Emphasis Type="Italic">Macaca mulatta</Emphasis>)

The basic tenet of several theories on aging is increasing genomic instability resulting from interactions with the environment. Chromosomal aberrations have been used as classic examples of increasing genomic instability since they demonstrate an increase in numerical and structural abnormalities with age in many species including humans. This accumulating damage may augment many aging processes and initiate age-related diseases, such as neoplasias. Calorie restriction (CR) is one of the most robust interventions for reducing the frequency of age-related diseases and for extending life span in many short-lived organisms. However, the mechanisms for the anti-aging effects of CR are not yet well understood. A study of rhesus monkeys was begun in 1987 to determine if CR is also effective in reducing the frequency of age-related diseases and retarding aging in a long-lived mammal. Male monkeys were begun on the diet in 1987, and females were added in 1992 to examine a possible difference in response to CR by sex. The CR monkeys have been maintained for over 10 years on a low-fat nutritional diet that provides a 30% calorie reduction compared to a control (CON) group. Because of the greater similarity of nonhuman primates to humans in life span and environmental responses to diet compared with those of rodents, the rhesus monkey provides an excellent model for the effects of CR in humans. This study examined the effects of CR on chromosomal instability with aging. Significant age effects were found in both CR and CON groups for the number of cells with aneuploidy: old animals had a higher loss and a higher gain than young animals. However, there was no effect of age on chromosomal breakage or structural aberrations in either diet group. Diet had only one significant effect: the CR group had a higher frequency of chromatid gaps than did the CON group. CR, implemented in adult rhesus monkeys, does not have a major effect on the reduction of numerical or structural aberrations related to aging.     

Pineal peptides restore the age-related disturbances in hormonal functions of the pineal gland and the pancreas

The purpose of this research was to study age-related changes in functioning of pineal and pancreatic glands of non-human primates, rhesus monkeys, and to elucidate the possibility of their corrections with the help of epitalon, a synthetic analogue of the pharmacopoeia drug epithalamin. In old (20-27 years) animals, the basal plasma levels of glucose and insulin were found to be higher, while the night melatonin level was lower in comparison with (6-8 years) young animals. After the glucose administration to old monkeys, a larger area under the curve of the plasma glucose response, a reduced glucose 'disappearance' rate, and a reduced insulin peak (5 min after the glucose administration) were observed in comparison with young animals in similar experiments. The epitalon administration to old monkeys caused the decrease in the basal levels of glucose and insulin and the increase in the basal night melatonin level. Additionally, in the case of old monkeys, epitalon decreased the area under the plasma glucose response curve, markedly increased the glucose 'disappearance' rate and normalized the plasma insulin dynamics in response to glucose administration. Yet, it has not affected the hormonal and metabolic changes in young animals. Thus, epitalon is a promising factor for restoring the age-related endocrine dysfunctions of primates.     

Age-related changes in metabolic parameters of nonhuman primates

Some physiological measures change with age, but the existence of age-related disorders such as type 2 diabetes raises questions about which patterns reflect progressive pathology and which are manifestations of aging. Here we report a retrospective investigation of age-related physiological changes in rhesus monkeys that developed diabetes (D group, n = 65) or exhibited healthy aging (N group, n = 88). Data were available on clinical chemistries, hematology, glucose tolerance, and insulin sensitivity based on oral and intravenous glucose tolerance tests and euglycemic, hyperinsulinemic clamp assessments. Individuals contributed data for an average of 7.6 years, when they were between 5 and 30 years of age. Only glucose disappearance rate, insulin sensitivity rate, and high density lipoprotein levels changed significantly with age in the nondiabetic group. In the diabetic group, significant decreases in glucose tolerance were evident by middle age (age 14 y), and fasting insulin first increased before diabetes was diagnosed, and then declined with advancing age.     

Beyond the rodent model: Calorie restriction in rhesus monkeys

Lifespan extension and reduction of age-related disease by calorie restriction (CR) are among the most consistent findings in gerontological research. The well known effects of CR have been demonstrated many times in rodents and other short-lived species. However, effects of CR on aging in longer-lived species, more closely related to humans, were unknown until recently. Studies of CR and aging using nonhuman primates (rhesus monkeys) were begun several years ago at the National Institute on Aging, the University of Wisconsin-Madison, and the University of Maryland. These studies are beginning to yield useful data regarding the effects of this nutritional intervention in primates. Several studies from these ongoing investigations have shown that rhesus monkeys on CR exhibit physiological responses to CR that parallel findings in rodents. In addition, several potential biomarkers of aging are being evaluated and preliminary findings suggest the possibility that CR in rhesus monkeys could slow the rate of aging and reduce age-related disease, specifically diabetes and cardiovascular disease. It will be several years before conclusive proof that CR slows aging and extends life span in primates is established, however, results from these exciting studies suggest the possibility that the anti-aging effects of CR reported in rodents also occur in longer-lived species such as nonhuman primates, strenghtening the possibility that this nutritional intervention will also prove beneficial in longer-lived species, including humans.     

Effects of age and dietary restriction on liver endogenous antioxidant defenses in male Lobund-Wistar rats

Dietary restriction (DR) of 30% in caloric intake extends both median and maximum life span by about 30%. DR retards the aging process, but the mechanism of action is not clearly understood. The effects of DR on major endogenous antioxidant defenses were studied in 80 male Lobund-Wistar (L-W) rats at various ages throughout the life span. Two groups of rats were fed ad libitum (AL) or restricted diet (DR) from 6 weeks of age. Adult DR rats received 30% less diet with regard to calories per day when compared to adult AL rats. Eight rats in each diet group were killed at 6, 12, 18, 24 and 30 months of age. The livers were excised and prepared for the determinations of major endogenous antioxidant defense parameters. Hepatic reduced glutathione (GSH) levels were decreased at old age in the AL group, however, DR eliminated this decrease. Activities of glutathione reductase (GR) and Se-dependent glutathione peroxidase (GPx) were not affected by age nor by DR. Superoxide dismutase (SOD) activity decreased from 6 to 12 months of age and catalase activity decreased with aging in the AL group, while DR maintained the enzyme activities at similar levels for all ages. Quinone reductase (QR) activity increased with increasing age in the AL group, and DR further increased the enzyme activity at all ages. The results suggest that 30% DR may contribute to the delaying of the aging process by improving endogenous antioxidant defense capability which decreases by 20 to 30% during aging. Invited Paper