Effects of age on energy status and redox state of lymphocytes during blastogenesis

Increased AMP:ATP ratio and AMP-activated protein kinase activity during cellular senescence linked to reduced HuR function

Cytoplasmic export of the RNA-binding protein HuR, a process that critically regulates its function, was recently shown to be inhibited by the AMP-activated protein kinase (AMPK). In the present investigation, treatment of human fibroblasts with AMPK activators such as 5-amino-imidazole-4-carboxamide riboside, antimycin A, and sodium azide inhibited cell growth and lowered the expression of proliferative genes. As anticipated, AMPK activation also decreased both the cytoplasmic HuR levels and the association of HuR with target radiolabeled transcripts encoding such proliferative genes. HuR function was previously shown to be implicated in the maintenance of a "young cell" phenotype in models of replicative cellular senescence. We therefore postulated that AMPK activation in human fibroblasts might contribute to the implementation of the senescence phenotype through mechanisms that included a reduction in HuR cytoplasmic presence. Indeed, AMP:ATP ratios were 2-3-fold higher in senescent fibroblasts compared with young fibroblasts. Accordingly, in vitro senescence was accompanied by a marked elevation in AMPK activity. Evidence that increased AMPK activity directly contributed to the implementation of the senescent phenotype was obtained through two experimental approaches. First, use of AMPK activators triggered senescence characteristics in fibroblasts, such as the acquisition of senescence-associated beta-galactosidase (beta-gal) activity and increased p16INK4a expression. Second, infection of cells with an adenoviral vector that expresses active AMPK increased senescence-associated beta-gal activity, whereas infection with an adenovirus that expresses dominant-negative AMPK decreased senescence-associated beta-gal activity. Together, our results indicate that AMPK activation can cause premature fibroblast senescence through mechanisms that likely involve reduced HuR function.

In vitro effect of extracellular AMP on MCF-7 breast cancer cells: inhibition of glycolysis and cell proliferation

MCF-7 human breast cancer cells propagated in vitro were treated with adenosine derivatives added to the culture medium. The effects on cell proliferation, glycolysis, and glutaminolysis were investigated. Of all adenosine derivatives tested, AMP was the most efficient inhibitor of cell proliferation. In AMP-treated cells, DNA synthesis decreased, whereas RNA and protein syntheses rose normally with time. In terms of carbohydrate metabolism, lactate production from glucose was drastically reduced; therefore, most of lactate produced must have been derived from glutamine. Increases in the enzyme activities involved in glutamate degradation and in the malate-aspartate shuttle were observed. In contrast, actual glycolytic flux rates declined, whereas key glycolytic enzyme activities increased. Metabolites such as fructose 1,6-bisphosphate and pyruvate accumulated in AMP-arrested cells. Based on the lowered NAD level in the AMP-treated cells, lactate dehydrogenase, but not malate dehydrogenase, was impaired; thereby the whole of glycolysis was inhibited. In compensation, glutamine catabolism was increased. NAD concentrations fell drastically because of the known inhibition of P-ribose-PP synthesis through heightened intracellular AMP levels. A hypothetical metabolic scheme to explain these results and to show how extracellular AMP may influence carbohydrate metabolism and cell proliferation is presented.

Partial restoration of Con A-induced proliferation, IL-2 receptor expression, and IL-2 synthesis in aged murine lymphocytes by phorbol myristate acetate and ionomycin

The activation by concanavalin A (Con A) of murine lymphocytes derived from aged animals is impaired, as demonstrated by lower IL-2 synthesis, display of fewer IL-2 receptors, and less [3H]thymidine incorporation relative to similarly treated cells from young animals. The ability of the phorbol ester, phorbol 12-myristate 13-acetate (PMA), and the calcium ionophore, ionomycin, in conjunction with Con A, to improve these parameters of activation has been assessed. When splenic lymphocytes derived from aged mice are cultured with Con A plus ionomycin, IL-2 synthesis and IL-2 receptor expression are increased over the values obtained in parallel cultures triggered by Con A alone up to levels equal to that obtained in Con A-activated young cultures. The proliferative response is less sensitive to the augmenting effect of ionomycin. PMA is much less effective in improving these parameters of Con A activation. PMA plus ionomycin, in the absence of Con A, triggers cell cycle transition of lymphocytes derived from both aged and young animals. Both IL-2 synthesis and IL-2 receptor expression induced by PMA plus ionomycin reach levels equal or near equal that found in parallel cultures of cells from young animals; however, proliferation is lower than in young adult cultures.

Biochemical markers of aging

It is the purpose of this report to identify possible metabolic deficiencies that might serve as biochemical markers of aging. It is proposed that the multiplicity of physical and physiological changes associated with aging could be most readily explained by alterations in the regulation and/or the activities of enzymes that occupy central positions in metabolism. Specifically, a search for metabolic markers of aging might include efforts to determine if there are age-related changes in the following enzymes or enzyme systems: (a) allosteric enzymes that catalyze reactions in highly branched metabolic pathways; (b) enzymes that catalyze opposing reactions between metabolites that are common intermediates in biosynthetic and biodegradative pathways (reactions which in the absence of final control would lead to futile substrate cycling); (c) enzymes that catalyze bimolecular reactions in which one member of a coenzyme pair is a cosubstrate (e.g., reactions involving NAD+ or NADH); (d) enzymes that are regulated by phosphorylation/dephosphorylation cycles; and (e) G-protein-dependent enzyme systems. It is also emphasized that changes in the concentrations and ratios of coenzyme substrate pairs (e.g., [NAD]/[NADH], [CoA]/[acyl CoA]) and the energy charge ratio [ATP] + 0.5 [ADP]/[ATP] + [ADP] + [AMP] may signal deviations from normal metabolism and therefore might be reliable markers of aging. In addition, because of their critical roles in metabolism, changes in the concentration of GTP, GDP and the second messengers, c-AMP, c-GMP should be monitored. Finally, it is noted that the accumulation of the altered forms of some enzymes which occurs during aging reflects imbalance between posttranslational modification of the enzymes and the degradation of the altered enzyme forms. The biological mechanisms involved and the genetic implications are discussed.

Expression of intracellular biochemical defects of lymphocytes in aging: proposal of a general aging mechanism which is not cell-specific

There is a decline in immune capacity with age which is expressed on the organismic level by association with numerous immune-related diseases, on the cellular level by impaired mitogenesis, on the biochemical level by impaired metabolic pathways, and on the molecular level by decreased protein synthesis and degradation. Defects in various cofactors such as calcium and several nucleotides also occur and may be related to the impaired enzyme function during mitogenesis in the aged. The central cause for decreased mitogenesis in the aged could be a decrease in protein synthesis which appears to cause impaired enzyme induction. This impaired enzyme induction accounts in part for the decreased glycolytic flux and DNA synthesis in these cells. Decreased protein synthesis also has been associated with a decreased synthesis of lymphokines which help these cells to proliferate. Numerous other intracellular age-related defects of lymphocytes also occur which may collectively play important interdependent roles in the impaired lymphocyte function of the aged. A potential general underlying mechanism of cellular senescence is proposed based on a genetic "slowing-cycle" effect of transcription, translation, and enzyme induction with immunosenescence presented as an example of an expression of these basic defects.

Carbohydrate metabolism in transforming lymphocytes from the aged

There is an age-related decline in immune capacity which has been linked to a decreased response of lymphocytes to mitogens in vitro. During transformation, lymphocytes require a marked increase in energy production and biosynthesis which is supplied primarily by glycolysis. In the elderly, the glycolytic enzymes increase significantly in transforming lymphocytes at least 24 hr later than in the young and then at significantly reduced levels. Glucose utilization is also impaired in stimulated lymphocytes from the elderly but follows the impairment of glycolysis. In stimulated cells from the young, increases in glycolytic enzyme activity levels accompany sharp increases in blastogenesis while a delayed increase in glycolytic enzyme activity in the elderly is accompanied by a delay in blastogenesis. Maximal glycolytic enzyme activity levels are significantly reduced in transformed lymphocytes from the elderly though the number of transformed cells is also significantly reduced. However, glycolytic enzyme activity levels are significantly lower in the elderly than in the young even on a per transformed cell basis. Thus, this reduction cannot be attributed to the lower number of transformed cells that are present in the elderly. This defect in the increase of glycolysis in stimulated cells from the elderly suggests an intracellular mechanism which could be related to the impaired lymphocyte stimulation in vitro in the aged.

Decreased protein synthesis of transforming lymphocytes from aged humans: relationship to impaired mitogenesis with age

Recent studies have indicated that the decline in mitogenesis during the aging process may be related to intracellular defects that become apparent when the cells are subjected to the metabolic stress of cell transformation. We provide the first report of an age-related decline in protein synthesis in human lymphocytes exposed to phytohemagglutinin. This impairment in protein synthetic capacity from aged subjects' transforming cells is apparent from 24 to 72 h of culture. By 72 h of culture the incorporation of radiolabeled leucine in stimulated cells from elderly subjects is about half that for the young. However, cells from the aged have an increased protein content in the face of decreased synthesis suggesting a degradation defect. Since protein synthesis may be necessary for the induction of key effectors which activate glycolysis (which is necessary for transformation), we sought to relate the impaired protein synthesis to the impaired glycolytic enzyme induction with age. Cycloheximide totally inhibited glycolytic enzyme induction as well as cell transformation. A defect in protein synthesis with age may interfere with new enzyme synthesis which is necessary to activate requisite pathways for mitogenesis such as glycolysis.

Delayed phytohemagglutinin-stimulated production of adenosine triphosphate by aged human lymphocytes: possible relation to mitochondrial dysfunction

The decreased immune response associated with aging may, in part, reflect intrinsic age-related biochemical alterations in lymphocytes from older animals. We measured levels of lymphocyte adenosine triphosphate (ATP) and continuous [3H]thymidine incorporation in phytohemagglutinin-stimulated lymphocytes from young and old humans, and the effects thereon of inhibitors of mitochondrial oxidative phosphorylation and protein synthesis. No difference was found in adenine nucleotide content between young and old subjects. After 24 hours of culture there was a decrease in ATP, with recovery and 2--3-fold increase at 48 hours in young cells after phytohemagglutinin stimulation. We observed a clearcut delay in older lymphocytes of the increase in ATP and [3H]thymidine incorporation following phytohemagglutinin stimulation. We found no evidence for decreased viability or diminished number of responding units in aged cultures. The evidence suggests that mitochondrial dysfunction may play a role in the immunodeficiency of aging.

Impaired glycolysis of human lymphocytes during aging

When peripheral lymphocytes from young persons are stimulated in vitro with phytohemagglutinin, an increase in the levels of all the glycolytic enzymes occurs concomitantly with blastogenesis. The specific activities of enzymes increase approximately 200%, with a greater induction of the latter half of the pathway. The increases do not represent a general enzyme induction, since nonglycolytic enzymes such as glucose 6-phosphate dehydrogenase and isocitrate dehydrogenase do not increase during transformation. Human lymphocytes from a geriatric population were also subjected to mitogen stimulation under identical conditions. The initial levels of the enzymes were essentially identical in lymphocytes from young and old subjects as were cultured controls which received no mitogen. However, during mitogen stimulation the cells from the old subjects failed to increase the glycolytic enzymes. This inability to activate glycolysis may be related to the decline in cell-mediated immunity which is known to occur with advancing age.