Rat tail artery norepinephrine release: age and effect of mitochondrial blockade

Age-dependent changes in Ca2+ homeostasis in peripheral neurones: implications for changes in function

Calcium ions represent universal second messengers within neuronal cells integrating multiple cellular functions, such as release of neurotransmitters, gene expression, proliferation, excitability, and regulation of cell death or apoptotic pathways. The magnitude, duration and shape of stimulation-evoked intracellular calcium ([Ca2+]i) transients are determined by a complex interplay of mechanisms that modulate stimulation-evoked rises in [Ca2+]i that occur with normal neuronal function. Disruption of any of these mechanisms may have implications for the function and health of peripheral neurones during the aging process. This review focuses on the impact of advancing age on the overall function of peripheral adrenergic neurones and how these changes in function may be linked to age-related changes in modulation of [Ca2+]i regulation. The data in this review suggest that normal aging in peripheral autonomic neurones is a subtle process and does not always result in dramatic deterioration in their function. We present studies that support the idea that in order to maintain cell viability peripheral neurones are able to compensate for an age-related decline in the function of at least one of the neuronal calcium-buffering systems, smooth endoplasmic reticulum calcium ATPases, by increased function of other calcium-buffering systems, namely, the mitochondria and plasmalemma calcium extrusion. Increased mitochondrial calcium uptake may represent a 'weak point' in cellular compensation as this over time may contribute to cell death. In addition, we present more recent studies on [Ca2+]i regulation in the form of the modulation of release of calcium from smooth endoplasmic reticulum calcium stores. These studies suggest that the contribution of the release of calcium from smooth endoplasmic reticulum calcium stores is altered with age through a combination of altered ryanodine receptor levels and modulation of these receptors by neuronal nitric oxide containing neurones.

Aging and calcium buffering in adrenergic neurons

The aging process at the cellular, organ and whole organism levels is in many respects a mystery. A common bias among those who study aging is that cellular homeostasis "generally falls apart". The assumption of a general deterioration in cellular homeostasis does not take into account that many individuals age quite well maintaining even robust physiological and mental functions. One facet of aging studies that has come to the forefront is the impact of age on the control of the ion messenger, calcium. Emerging evidence suggests that despite age-related declines in any one component or multiple components of the calcium buffering systems, compensatory mechanisms may be able to maintain overall calcium homeostasis. This brief review focuses specifically on the ability of peripheral neurons to maintain control of the ion messenger calcium with advancing age. In addition, the idea that the impact of age on calcium homeostasis may be more subtle due to complex and integrated mechanisms that control this ion is discussed.

Diurnal rhythms in norepinephrine and acetylcholine synthesis of sympathetic ganglia, heart and adrenals of aging rats: effect of melatonin

The effect of aging and melatonin on 24-h rhythms in tyrosine hydroxylase activity and 3H - choline conversion into 3H - acetylcholine were examined in cervical, stellate, coeliac-mesenteric and hypogastric ganglia, and in the adrenal medulla and heart of rats. Young (50 days old) and old (18 months old) rats received evening injections of 10 or 100 microg of melatonin or its vehicle for 17 days. In superior cervical, stellate and coeliac-superior mesenteric ganglia, as well as in the adrenal medulla, norepinephrine and acetylcholine synthesis attained maximal values at night (c.a. 2030-0100 h). In the hypogastric ganglion, maximal tyrosine hydroxylase activity occurred at night at both studied ages. Two maxima in acetylcholine synthesis were detected in hypogastric ganglion of young rats (c.a. 1300 h and 0100 h, respectively) while in old rats a single maximum was observed at noon. Cardiac tyrosine hydroxylase activity peaked at early night (c.a. 2200-2300 h) while cardiac acetylcholine synthesis peaked at the afternoon (c.a. 1700-1900 h). Old rats exhibited a significant decrease of rhythm amplitude and increase of mean values in tyrosine hydroxylase activity in autonomic ganglia and adrenal medulla, and abolition of tyrosine hydroxylase rhythm in the heart. Twenty-four hour rhythmicity in acetylcholine synthesis was impaired or abolished in aged rats. Treatment of old rats with 10 or 100 microg melatonin generally augmented amplitude of rhythms and reinduced the nocturnal peak of acetylcholine synthesis in the hypogastric ganglion. Only the high melatonin dose significantly augmented rhythm amplitude of tyrosine hydroxylase activity (superior cervical and coeliac-superior mesenteric ganglia) and acetylcholine synthesis (superior cervical, stellate and coeliac-superior mesenteric ganglia) in young rats. The results indicate that the activity of the central oscillator, driven to the organs in part via the autonomic nervous system, deteriorates significantly with aging and that melatonin may restore partially such a deterioration.

Impact of age on modulation of norepinephrine release from sympathetic nerves in the rat superior mesentery artery

There is an age-related increase in stimulation-evoked fractional norepinephrine release in tail arteries of Fischer 344 rats from 6-20 months of age. Previous studies have ruled out changes in the function of uptake and subsequent metabolism mechanisms, or feedback by prejunctional alpha2-adrenoceptors. The tail artery is important in thermoregulation, and there is the possibility that the previously observed increase in sympathetic nerve activity is due to age-related changes in thermoregulation as opposed to a fundamental age-related change in the regulation of sympathetic nerves. Thus, we measured stimulation-evoked norepinephrine release in another blood vessel model, the superior mesentery artery using HPLC with electrochemical detection. In this study fractional norepinephrine release was measured under three separate conditions, drug free Krebs'; in the presence of deoxycorticosterone and cocaine; in the presence of deoxycorticosterone and cocaine and the alpha2-adrenergic receptor antagonist, idazoxan. The most significant finding was that fractional norepinephrine release in mesentery arteries from 20-month-old animals was higher as compared to 6 months regardless of treatment condition. Furthermore, the elevation in norepinephrine release cannot be accounted for by changes in norepinephrine content, uptake and subsequent metabolism mechanisms or changes in basal norepinephrine release. These data from the mesentery artery model confirm and support our previous work in the rat tail artery model. In addition, the data from this study suggest the possibility that there are common mechanisms underlying the age-related increase in peripheral sympathetic nerve activity.

Adrenergic nerve smooth endoplasmic reticulum calcium buffering declines with age

Calcium buffering capacity declines with age in sympathetic nerves of rat tail artery. To test whether smooth endoplasmic reticulum (SER) calcium buffering declines with age, effects of two SER calcium-ATPase inhibitors on norepinephrine release and intracellular calcium were determined. Thapsigargin or cyclopiazonic acid caused a significant increase in stimulation-evoked norepinephrine release from 6 month tail arteries with much less effect in 20 months. In isolated superior cervical ganglion cells, the rate of rise of calcium with K+-depolarization increased only in young cells with either cyclopiazonic acid or thapsigargin, with no effect in the old. In young cells, cyclopiazonic acid significantly influenced time to peak, rate of decline, and time to basal of K+-evoked calcium transients, but had no effect in old cells. Thapsigargin caused a significant increase in rate of decline in young, but not old, cells. These differential effects suggest an age-related decline in function of SER calcium buffering mechanisms in the sympathetic nervous system causing older nerves to become more reliant on mitochondria to buffer calcium.

Intracellular calcium buffering declines in aging adrenergic nerves

Stimulation-evoked norepinephrine release from rat tail artery adrenergic nerves increased with advancing age in the Fischer-344 rat when function of norepinephrine uptake mechanisms and prejunctional alpha-2 adrenoceptors were blocked. When calcium channels were bypassed with the ionophore, ionomycin (4 microM), norepinephrine release from aged nerves (20 months) was still elevated as compared to 6-month-old nerves. Norepinephrine release stimulated by high K+ was also higher in 20-month nerves. The intracellular calcium chelator, 1,2 bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetomethylester (BAPTA/AM), was used to determine whether age-related increases in norepinephrine release could be reversed with the addition of an artificial intracellular calcium buffer. Exposure to BAPTA/AM decreased stimulation-evoked norepinephrine release in both old and young tail arteries; however, the effect was significantly greater in older arteries. When mitochondrial calcium uptake was compromised using the uncoupler of mitochondrial oxidative phosphorylation, dinitrophenol, BAPTA caused a further decrease in stimulation-evoked norepinephrine release in 20-month tail arteries with much less effect in 6-month-old nerves. These results suggest that intracellular calcium buffering is less efficient in older nerves.

Advancing age alters intracellular calcium buffering in rat adrenergic nerves

There is a marked increase with advancing age of stimulation-evoked neurotransmitter release from vascular adrenergic nerves in the rat, an effect correlated with increased levels of plasma norepinephrine. This increase in norepinephrine release could not be accounted for by an alteration in neuronal and extraneuronal uptake of norepinephrine or a decline in feedback inhibition of release by prejunctional alpha2-adrenergic receptors. Measurement of intracellular calcium in fura-2-labeled superior cervical ganglion cells revealed elevated K+-evoked calcium transients in old compared to young neurons. Blockade of mitochondrial calcium uptake with dinitrophenol resulted in increased calcium transients in old neurons only. Furthermore, following blockade of mitochondrial calcium uptake the rate of return of calcium to resting levels was reduced to a greater degree in old cells as compared to young cells. The effects of dinitrophenol in old cells were attenuated when extracellular calcium was reduced. These findings suggest that older cells are more dependent on mitochondrial calcium buffering, perhaps due to changes in ATP dependent calcium uptake. Increased calcium transients as a result of altered intracellular calcium buffering offer a reasonable explanation for our previous observation of increased stimulation evoked norepinephrine release.

Evidence for decline in intracellular calcium buffering in adrenergic nerves of aged rats

Age-related alterations in neuronal intracellular calcium regulation and neurotransmitter release have been widely reported. We have investigated the impact of age on neurotransmitter release and intracellular calcium buffering in adrenergic nerve endings of the isolated rat tail artery and on intracellular calcium in acutely dissociated cells from the superior cervical ganglion. Advancing age, from 6 to 27 months, resulted in significantly increased stimulation-evoked norepinephrine release from the isolated rat tail artery, an effect which persisted when neuronal and extraneuronal uptake were blocked with cocaine and deoxycorticosterone and presynaptic alpha adrenergic receptors were blocked with idazoxan. Alterations in extracellular calcium had significant effects on stimulation-evoked norepinephrine release, but these were much more marked in old, compared to young, arteries. Blockade of mitochondrial calcium accumulation with dinitrophenol had no significant effect on stimulation-evoked norepinephrine release from 6-month-old arteries, but in 20-month-old arteries, treatment with dinitrophenol resulted in a substantial increase in stimulation-evoked norepinephrine release. However, when extracellular calcium was increased to 5 mM in 6 month-old-arteries, then addition of dinitrophenol resulted in an increase in stimulation-evoked norepinephrine release. Measurement of intracellular calcium in acutely dissociated superior cervical ganglion cells using fura-2 revealed substantial age-related differences. Peak calcium transients in 20-month-old ganglion cells depolarized with 68 mM K+ were substantially higher than in 6-month-old cells. Together these findings support the hypothesis that in adrenergic nerves advancing age results in a disruption of intracellular calcium buffering leading to higher levels of intracellular calcium and increased transmitter release.