Cyclic AMP-dependent protein kinase activity and synaptosomal protein phosphorylation in the brains of aged rats

cAMP-dependent protein kinase in cerebral microvessels in aging and Alzheimer disease

The purpose of this study was to compare the effects of aging and Alzheimer disease (AD) on the important intracellular signaling enzyme cAMP-dependent protein kinase A (PKA) in cerebral microvessels. PKA activity and levels were measured in microvessels isolated from the brains of adult and aged rodents as well as from the cerebral cortices of AD and elderly control patients. The results showed that cerebral microvessels from aged rats have significantly (p < 0.01) higher PKA activity and levels when compared to cerebral microvessels from adult rats. In contrast, no significant difference was found between PKA activity or levels in cerebral microvessels from AD patients when compared to controls. These results indicate that in cerebral microvessels both PKA activity and levels increase with age but are unaffected by AD. The data suggest that protein phosphorylation in brain microvessels may be affected differentially by aging and dementia.

Changes in calcium's role as a messenger during aging in neuronal and nonneuronal cells

Alterations in calcium transport appear to be functionally significant. Treatment with drugs that promote calcium uptake partially reverse some of the age-related deficits in calcium-dependent processes. Thus, the relevance of decreased calcium coupled receptor binding is supported by the ability of 3,4-diaminopyridine to promote acetylcholine release by forebrain slices from aged mice. This drug also reduces the age-related depression in synaptosomal calcium uptake in aged rats and mice. 3,4-Diaminopyridine also reverses the age-related deficit in calcium transport, the age-related deficits in the tight rope test, and 8 arm maze performance. 3,4-Diaminopyridine is also effective in nonexcitable tissues, such as cultured skin fibroblasts; it increases the decreased cytosolic-free calcium. Depressed cell spreading of fibroblasts can be reversed by treatment of cells with the calcium ionophore A23187 which promotes calcium influx. 4-Aminopyridine, a similarly related compound, partially reverses short-term memory deficits in patients with Alzheimer's disease. Tetrahydroaminoacridine, an aminopyridine analog with anticholinesterase properties, produces clinical improvement in behavioral deficits due to Alzheimer's disease. Only recently has the aging brain become a subject of intense study. Evidently, the neurobiology of aging needs to develop its own theories to account for the unique aspects of brain aging as well as integrate them with the peripheral changes. An exciting but unexplored area of research in the aging brain concerns the coupling between calcium and the final end product, the induction of genes. Still unknown are the molecular events that set these processes in motion. In addition, whether conditions such as dietary restriction that increase longevity in certain rodents also retard age-related changes in calcium remains to be determined.

The aging brain: protein phosphorylation as a target of changes in neuronal function

There is evidence that senescence affects neurotransmission at different levels. In particular, this review summarizes the studies on age-dependent modifications in protein phosphorylation, which represents the final pathway in the action of transmitters and hormones at neuronal level. Cyclic AMP-dependent protein kinase and protein kinase C have been reported to be modified during aging in various cerebral areas; the changes may involve either enzyme activity or substrate availability. These findings can be related to the alterations in neurotransmitter function and synaptic efficiency observed in the senescent brain. The activity of the other types of protein kinases (tyrosine-, cGMP-, calcium/calmodulin-dependent) during aging needs to be explored. An emerging point is the role of protein phosphorylation in the transfer of membrane signals to the nucleus, for the activation or disactivation of specific genes responsible for long-term neuronal events. Along this view, alterations in protein kinase pathway during senescence would ultimately affect gene expression, resulting in long term modifications of cell function. The reviewed literature opens the perspective of restoring some of the deficits associated with senescence by modulating protein phosphorylation pathway.

Age-dependent changes in murine protein kinase and protease enzymes

Hormone responsiveness is mediated by signal transduction mechanisms involving second messengers, such as cAMP and Ca2+, which regulate reversible changes in the phosphorylation state of proteins. During senescence individuals frequently exhibit a diminished responsiveness to hormones. We examined changes in enzymes involved in protein phosphorylation reactions that might account for this decreased adaptiveness in old mice, and observed the following post-maturational changes: (1) cAMP-dependent protein kinase (Pk-A) specific activity decreased in spleen cytosol and in the particulate fractions of lung, spleen and liver of 24-month-old mice as compared to 2-month-old mice. Splenic cytosolic Pk-A activity decreased by 18 months of age, while particulate activity decreased by 6 months; (2) The amount of 8-N3-[32P]cAMP, a photoaffinity analog of cAMP, incorporated into Pk-A regulatory (R)-subunits from spleen and liver particulate fractions decreased, while photolabeling of R-subunit degradative products with this analog in heart and spleen cytosol increased. (3) Age-dependent increases in membrane-associated protease activities were found in all organs, along with a decrease in cytosolic lung calpain activity. These proteolytic changes may account for the enhanced R-subunit degradation and decreased Pk-A activities observed during senescence. (4) Age-dependent alterations in Ca2+/phospholipid-dependent protein kinase (Pk-C) are organ specific: lung, liver, brain, and heart demonstrate no change in Pk-C activity, while spleen exhibits decreased activity. We hypothesize that these age-dependent alterations in kinase and proteolytic activities may be in part responsible for changes in cellular response to hormonal stimulation, differentiation signals, and antigen responsiveness during senescence.

Selective decline in protein F1 phosphorylation in hippocampus of senescent rats

Certain forms of neuronal plasticity have been found to be expressed through alterations in brain protein phosphorylation, and its regulation by protein kinase activity. Of interest in this regard is the possibility that the decline in neuronal plasticity and cognitive function that occurs in advanced age may result in part from altered phosphorylation of specific proteins. As a first attempt to identify age-related changes in phosphoproteins, we assayed in vitro phosphorylation of proteins in hippocampus, cerebellum, entorhinal cortex, and frontal cortex from Fischer-344 rats of 5 months, 11 months, and 25 months of age. Compared to the middle-aged animals, the aged rats showed a selective 46% decline in phosphorylation of the 47 kDa protein (F1) in hippocampus, with no change in the phosphorylation of other proteins measured in this structure. Aged animals also showed decreased phosphorylation relative to young animals. No age-related change was observed in any protein band for the other brain areas examined. Since protein F1 is phosphorylated by protein kinase C (PKC), the cytosolic and membrane distribution of this enzyme was compared across age groups. The activity of PKC in hippocampus did not change across age. The explanation of this age-related decline in protein F1 phosphorylation is likely to be a decline in the substrate protein itself. The results are discussed in terms of protein F1's possible role in age-related decline of hippocampal synaptic plasticity.

The effect of electroconvulsive shock on brain tubulin during development and aging

Effect of electroconvulsive shock on rat brain tubulin content was studied during maturation and aging. The results show that electroconvulsive shock had no effect on soluble tubulin in different brain structures of young animals (22 days) while the same treatment produced a marked decline in adult (95 days) and aged (490-511 days) animals. The same treatment produced inhibition of 3H-leucine incorporation into tubulin and decrease of 3H-colchicine binding in the proteins of synaptosomes isolated from the centricephalic structures of all the ages examined. Tubulin biosynthesis by free polysomes was not diminished to the extent which could explain the decrease of tubulin level found in the soluble or synaptosomal fraction. Thus, our results suggest that changes in soluble tubulin content in response to electroconvulsive shock could be a reflection of changes in equilibrium: tubulin dimers--microtubules--membrane-bound tubulin.

Human brain protein phosphorylation in vitro: cyclic AMP stimulation of electrophoretically-separated substrates

In vitro phosphorylation of electrophoretically-separated brain proteins was studied in human frontal cortex obtained 3-16 h post-mortem from 13 patients ages 3 days-82 years with extensive, mild or no neuropathological involvement. In 12 of the 13 cases, cyclic AMP increased incorporation of phosphate into acid-precipitable protein. Analysis of the autoradiographic profiles of separate proteins indicated that phosphorylation of the doublet of molecular weight 86-80,000 was stimulated by cyclic AMP in certain samples. This doublet corresponded to the cyclic AMP stimulated doublet from rat frontal cortex we have termed band D-1,2 (proteins Ia and Ib of Ueda and Greengard). Of special interest was the fact that, while co-migration was observed in the other phosphoprotein bands studied, band D-1,2 of humans consistently migrated slightly less than rat protein band D-1,2. This difference was not a function of post-mortem time, subcellular fraction or buffer used in the reaction phosphorylation assay. The use of post-mortem tissue was not a contributing factor as the retardation in band D-1,2 migration was still observed when post-mortem rat brain was used for comparison. In two human post-mortem samples, there was no measureable band D-1,2 phosphorylation even in the presence of cyclic AMP. This was the case in both homogenate and crude synaptosome/mitochondrial preparations. Band F-1 (mol. wt. = 47,000) was not observed in any of the human samples studied. This is consistent with prior studies in rat which show that band F-1 phosphorylation is not detected in post-mortem brain, Band F-2 (mol. wt. 41,000) recently identified as pyruvate dehydrogenase, was lightly phosphorylated under the reaction conditions used in this study.

Changes in noradrenergic neurotransmission in rat cerebellum during aging

This study compared the electrophysiological effects of locally applied cyclic adenosine-mono-phosphate (N6cAMP) between Purkinje neurons from young (4-month) and old rats (15-months and older). Purkinje neurons from young rats were significantly more sensitive to locally applied norepinephrine and N6cAMP than neurons from old rats. GABA sensitivity between the two groups was unaltered. Our results suggest that the locus of the adrenergic subsensitivity observed in older animals may reside to a large extent at or beyond the level of cAMP generation.

Cyclic AMP-dependent protein kinase activity in human brain across age

Cyclic AMP-dependent protein kinase activity was measured in the cerebral cortex of humans 2 days to 83 years of age and in the cortex of F344 rats 3, 22, or 30 months of age. Protein kinase activity was detected in the human brain, but no age-related differences in activity were observed in the presence or absence of cyclic AMP. Age differences were also not seen in protein kinase in the rat cerebral cortex. Enzyme activities in rat and human brain were similar.