Decrease of lymphocyte (Na+,K+)ATP-ase activity in aged people

Physiology of aging among healthy, older bottlenose dolphins (Tursiops truncatus): comparisons with aging humans

Changes in hematological and serum chemistry values have been identified among older compared to younger humans. We hypothesized that healthy bottlenose dolphins (Tursiops truncatus) 30 years and older may demonstrate similar clinicopathological changes with increasing age. Retrospective hematological and serum chemistry data generated from routine, fasted blood samples collected over 10 to 20 years among six healthy dolphins that lived at least 40 years were analyzed to (1) assess linear trends in blood variable values with increasing age, (2) compare mean blood values by older age categories (30-35 years, 36-40 years, and >40 years), and (3) compare the prevalence of clinically high or low blood values by older age categories. Absolute lymphocytes, serum globulins, and mean platelet volume increased linearly with increasing old age. Mean white blood cells, neutrophils, serum globulins, erythrocyte sedimentation rates, serum cholesterol, and serum triglycerides; and the prevalence of neutrophilic leukocytosis, hyperglobulinemia, and hypercholesterolemia, were more likely to be higher as geriatric dolphins got older. A linear decrease in serum albumin with increasing age was present for five of six animals. Serum creatinine decreased among dolphins older than 40 years compared to when they were 30-40 years old. Our study demonstrates that older dolphins have changes in hematological and serum chemistry values similar to those found in older humans. As such, bottlenose dolphins may serve as a useful comparative model for aging in humans. Further studies are needed to assess whether these changes are associated with negative health outcomes and whether targeted therapeutics can help improve quality of life among aging dolphins.

Energy expenditure and aging

The study of energy expenditure (EE) has deep roots in understanding aging and lifespan in all species. In humans, total EE decreases substantially in advanced age resulting from parallel changes in resting metabolic rate (RMR) and activity EE. For RMR, this reduction appears to be due to a reduction in organ mass and specific metabolic rates of individual tissues. However, these anatomical changes explain very little regarding the decline in activity EE, which is governed by both genetic and environmental sources. The biological control centers for activity EE are closely coupled with body mass fluctuations and seem to originate in the brain. Several candidate neuromodulators may be involved in the age-related reduction of activity EE that include: orexin, agouti-related proteins and dopaminergic pathways. Unfortunately, the existing body of research has primarily focused on how neuromodulators influence weight gain and only a few studies have been performed in aging models. Recent evidence suggests that activity EE has an important role in dictating lifespan and thus places emphasis on future research to uncover the underlying biological mechanisms. The study of EE continues to unlock clues to aging.

Restriction of energy intake, energy expenditure, and aging

Energy restriction (ER), without malnutrition, increases maximum life span and retards the development of a broad array of pathophysiological changes in laboratory rodents. The mechanism responsible for the retardation of aging by ER is, however, unknown. One proposed explanation is a reduction in energy expenditure (EE). Reduced EE may increase life span by decreasing the number of oxygen molecules interacting with mitochondria, thereby lowering reactive oxygen species (ROS) production. As a step toward testing this hypothesis, it is important to determine the effect of ER on EE. Several whole-body, organ, and cellular studies have measured the influence of ER on EE. In general, whole-body studies have reported an acute decrease in mass-adjusted EE that disappears with long-term ER. Organ-specific studies have shown that decreases in EE of liver and gastrointestinal tract are primarily responsible for initial reductions in EE with ER. These data, however, do not determine whether cellular EE is altered with ER. Three major processes contributing to resting EE at the cellular level are mitochondrial proton leak, Na(+)-K(+)-ATPase activity, and protein turnover. Studies suggest that proton leak and Na(+)-K(+)-ATPase activity are decreased with ER, whereas protein turnover is either unchanged or slightly increased with ER. Thus, two of the three major processes contributing to resting EE at the cellular level may be decreased with ER. Although additional cellular measurements are needed, the current results suggest that a lowering of EE could be a mechanism for the action of ER.

Mechanisms underlying the cost of living in animals

The cost of living can be measured as an animal's metabolic rate. Basal metabolic rate (BMR) is factorially related to other metabolic rates. Analysis of BMR variation suggests that metabolism is a series of linked processes varying in unison. Membrane processes, such as maintenance of ion gradients, are important costs and components of BMR. Membrane bilayers in metabolically active systems are more polyunsaturated and less monounsaturated than metabolically less-active systems. Such polyunsaturated membranes have been proposed to result in an increased molecular activity of membrane proteins, and in this manner the amount of membrane and its composition can act as a pacemaker for metabolism. The potential importance of membrane acyl composition in metabolic depression, hormonal control of metabolism, the evolution of endothermy, as well as its implications for lifespan and human health, are briefly discussed.

Influence of physiological factors on the age-related increase in blood pressure in healthy men

The independent and collective influences of several physiological factors on the age-related increase in blood pressure in healthy men were examined. Twenty-seven younger and 25 older, mostly normotensive, healthy men were studied. Blood pressure, body fat, body fat distribution, maximal oxygen consumption (VO2max), plasma norepinephrine, dietary Na, and erythrocyte Na-K pump activity were measured. Older men showed 57% higher percent body fat, 40% higher plasma norepinephrine concentration, 14% greater mean arterial blood pressure (MAP), and 5% higher plasma K concentration than younger men (all p < 0.01). Older men showed a 38% (p < 0.01) lower VO2max, 19% (p < 0.05) lower energy intake, 18% (p < 0.05) lower Na-K pump rate constant, and a 17% (p < 0.05) lower Na-K pump rate. Group means for MAP were adjusted for combinations of plasma norepinephrine, waist:thigh ratio, VO2max, and the Na-K pump rate constant, to determine if any one variable or combination could account for the age related increase in MAP. Statistical adjustment for plasma norepinephrine, waist:thigh ratio, and Na-K pump rate constant eliminated the significant difference between MAPs for the two groups. Thus, alterations in sympathetic nervous system activity, body fat distribution, and the membrane Na-K pump activity independently contribute to the age-related increase in MAP in healthy men.

Aging impairs membrane potential responsiveness as well as opening of voltage and ligand gated Na+ channels in human lymphocytes

Depolarizing effects of increasing concentrations of extracellular K(+), as well as the repolarizing effect of bretylium tosylate (BT) were evaluated in human lymphocytes from young and elderly volunteers. Cells from elderly volunteers were less responsive to depolarization induced by increased extracellular potassium concentrations than those from young volunteers. Upon a near complete depolarization induced by 140 mM K(+) in the extracellular space, a significant amount of non-responding cells were found in samples from elderly volunteers. BT, which opens the otherwise silent Na(+) channels of partially depolarized cells, with subsequent activation of the Na(+)-K(+) pump (Pieri et al., 1989). repolarized both young and old lymphocytes. However, the degree of the repolarization was only 40% in the case of lymphocytes from elderly volunteers than from that of the young. It is suggested that an increase of membrane microviscosity, characteristic of old cells, may be at least partially responsible for the decreased responsiveness of plasma membrane functions which were observed.

Lymphocyte Na,K-ATPase is reduced in aged people

Na,K-ATPase-dependent 86Rb uptake, maximum velocity (Vmax), Michaelis constant (Km) of the uptake, and [3H]-ouabain binding were investigated in the lymphocytes of 10 elderly subjects (age greater than 60 years), and in 10 middle-aged (41 to 60 years) and 10 young controls (age less than or equal to 40 years). 86Rb uptake was reduced in elderly versus both middle-aged and young subjects (20.14 +/- 3.30 v 35.60 +/- 2.67, P = .002, and v 36.53 +/- 4.49 nmol, P = .012), as was the number of [3H]-ouabain binding sites per cell (32,662 +/- 2,215 v 40,420 +/- 1,184, P = .011, and v 40,596 +/- 1,349, P = .014). Vmax was reduced in elderly v young subjects (1.20 +/- 0.10 v 1.64 +/- 0.13, P = .034), but not versus the middle-age group (1.20 +/- 0.10 v 1.54 +/- 0.12 nmol.min-1, NS). Km was no different among the three groups. No differences were found between middle-aged and young subjects. Significant correlations were observed between age and Na,K-ATPase-dependent 86Rb uptake (r = -.620, P = .00009), Vmax (r = -.439, P = .024), and [3H]-ouabain binding sites (r = -.648, P = .002). Moreover, the site number was positively correlated with both uptake (r = .635, P = .002) and Vmax (r = .554, P = .011). These differences were observed both in women and men. We conclude that there is an age-dependent reduction in lymphocyte Na,K-ATPase activity, which is fully manifested over 60 years, and that this alteration is probably due to the reduced number of functional units of Na,K-ATPase in advancing age.

A new method for testing cell ageing using two mitochondria specific fluorescent probes

Cell culture techniques have considerably improved our understanding of the numerous changes related to aging. For instance, murine lymphocytes obtained from animals older than 6 months progressively lose their, in vitro, proliferative capacity. Numerous studies have shown that this loss is due to changes in the mitochondrial compartment such as reduction in the transmembrane potential and/or membrane mass. Using two mitochondria specific probes with a potential-dependent (Rhodamine 123) or independent (Nonyl Acridine Orange) uptake, we found that the decline in the respiratory activity in the mouse occurred approximately 6 months prior to the decrease in mitochondrial membrane mass. The analysis of the Rh 123/NAO fluorescence ratio measured in splenocytes obtained from mice aged more than 6 months, showed that there was a linear loss of respiratory efficiency per unit of mitochondrial membrane mass. Moreover, cells with a ratio of less than 0.85 were incapable of proliferating and remained quiescent. The time separating the infection points of the two dye uptake curves might provide informations about the regulation and coordination of nuclear and/or mitochondrial genomes. Moreover, the ratio between the two fluorescent probes, in particular during the linear phase, may also have a predictive value.

Membrane signal transduction in T cells in aging humans

The interaction of the T cell receptor complex with the ligand is associated with early molecular events involved in the process of signal transduction. These events include, changes in membrane potentials, intracellular free calcium [(Ca++)i], and the activation and translocation of protein kinase C (PKC). The aim of this study was to elucidate the abnormalities in membrane signal transduction pathway as the basis of T cell-mediated immune deficiency associated with aging. Peripheral blood mononuclear cells from aging humans and sex-matched young subjects were stimulated with anti-CD3 monoclonal antibody, WT31 monoclonal antibody (defines epitopes for alpha/beta T cell receptor genes), and phytohemagglutinin (PHA), and examined for the changes in plasma membrane potentials, changes in (Ca++)i, and the activation of PKC. The membrane potentials were measured with DiOC5 dye using FACS. Intracellular free calcium was measured with quin-2 dye and spectrofluorimeter, and the membrane and cytosolic PKC were measured by an enzyme assay. The resting membrane potentials in aging T cells were decreased (plasma membrane depolarized) when compared to T cells from young subjects. In T cells from aging humans, there was a lack of a change in the membrane potentials or membrane potentials were increased (plasma membrane hyperpolarized) following activation with anti-CD3 and WT31 monoclonal antibodies, whereas in young T cells membrane potentials were decreased (depolarized). The basal [Ca++]i levels in aging T cells were less than that in young T cells, and a much smaller rise in [Ca++]i was observed following activation with PHA and anti-CD3 monoclonal antibody in aging T cells than in the young T cells. In aging cells there was less translocation of PKC from cytosol to the membrane following activation with anti-CD3 and WT31. This study demonstrates that the abnormal membrane signal transduction pathway plays a role in T cell dysfunctions associated with human aging.

An in vitro analogue of immune dysfunction with altered immunoglobulin production in the aged

The consequences of aging of the immune system include impaired T-lymphocyte responsiveness and aberrant immunoglobulin production. Although T cells from elderly individuals have a well-described defect in lymphoblastic transformation in response to some polyclonal mitogens, immunoglobulin abnormalities have lacked a clear in vitro model. Peripheral blood mononuclear cells from 13 young and 13 old healthy donors were cultured with phytohemagglutinin (PHA) or pokeweed mitogen (PWM). Old-donor-cell phytohemagglutinin (PHA), but not PWM, cultures had significantly lower lymphoblastic transformation compared with young donor cultures. IgG, IgA, and IgM production tended to be lower in old- versus young-donor PWM cell cultures. By contrast, despite lower lymphoblastic transformation in old-donor PHA cell cultures, immunoglobulin production was higher for old- versus young-donor cell cultures. No significant age differences were present in initial lymphocyte counts, percent B cells, T cells or monocytes, or helper/suppressor ratios to explain this enhancement in immunoglobulin production. PHA-stimulated mononuclear cell cultures in the aged demonstrate not only a defect in proliferation but also increased immunoglobulin production. This in vitro system may be useful to characterize further the pathogenesis of altered immunoglobulin production in the elderly.

Effect of vanadate of PHA-induced proliferation of human lymphocytes from young and old subjects

The effect of sodium orthovanadate on mitogen-induced proliferation of lymphocytes from young and old human subjects is reported. We found that vanadate is not mitogenic per se; it has an inhibitory effect during the first 3 days of culture, when both differentiation and proliferation take place; it enhances DNA synthesis, acting as a co-mitogen, in the following days of culture, when proliferation prevails. In spite of the fact that lymphocytes from the two groups differ in their responsiveness to PHA and in the activity of (Na+,K+)ATPase, no difference was found as for the effects of vanadate.