Temperature effects on the activity, shape, and storage of platelets from 13-lined ground squirrels.

The objective of this study is to determine how a hibernating mammal avoids the formation of blood clots under periods of low blood flow. A microfluidic vascular injury model was performed to differentiate the effects of temperature and shear rate on platelet adhesion to collagen. Human and ground squirrel whole blood was incubated at 15 or 37 °C and then passed through a microfluidic chamber over a 250-µm strip of type I fibrillar collagen at that temperature and the shear rates of 50 or 300 s-1 to simulate torpid and aroused conditions, respectively. At 15 °C, both human and ground squirrel platelets showed a 90-95% decrease in accumulation on collagen independent of shear rate. At 37 °C, human platelet accumulation reduced by 50% at 50 s-1 compared to 300 s-1, while ground squirrel platelet accumulation dropped by 80%. When compared to platelets from non-hibernating animals, platelets from animals collected after arousal from torpor showed a 60% decrease in binding at 37 °C and 300 s-1, but a 2.5-fold increase in binding at 15 °C and 50 s-1. vWF binding in platelets from hibernating ground squirrels was decreased by 50% relative to non-hibernating platelets. The source of the plasma that platelets were stored in did not affect the results indicating that the decreased vWF binding was a property of the platelets. Upon chilling, ground squirrel platelets increase microtubule assembly leading to the formation of long rods. This shape change is concurrent with sequestration of platelets in the liver and not the spleen. In conclusion, it appears that ground squirrel platelets are sequestered in the liver during torpor and have reduced binding capacity for plasma vWF and lower accumulation on collagen at low shear rates and after storage at cold temperatures, while still being activated by external agonists. These adaptations would protect the animals from spontaneous thrombus formation during torpor but allow them to restore normal platelet function upon arousal.

Sympathetic neurogenic Ca2+ signalling in rat arteries: ATP, noradrenaline and neuropeptide Y.

The sympathetic nervous system (SNS) plays an essential role in the control of total peripheral vascular resistance by controlling the contraction of small arteries. The SNS also exerts long-term trophic influences in health and disease; SNS hyperactivity accompanies most forms of human essential hypertension, obesity and heart failure. At their junctions with smooth muscle cells, the peri-arterial sympathetic nerves release ATP, noradrenaline (NA) and neuropeptide Y (NPY) onto smooth muscle cells. Confocal Ca(2+) imaging studies reveal that ATP and NA each produce unique types of postjunctional Ca(2+) signals and consequent smooth muscle cell contractions. Neurally released ATP activates postjunctional P2X(1) receptors to produce local, non-propagating Ca(2+) transients, termed 'junctional Ca(2+) transients', or 'jCaTs'. Neurally released NA binds to alpha(1)-adrenoceptors and can activate Ca(2+) waves or more uniform global changes in [Ca(2+)]. Neurally released NPY does not appear to produce Ca(2+) transients directly, but significantly modulates NA-induced Ca(2+) signalling. The neural release of ATP and NA, as judged by postjunctional Ca(2+) signals, electrical recording of excitatory junction potentials and carbon fibre amperometry to measure NA, varies markedly with the pattern of nerve activity. This probably reflects both pre- and postjunctional mechanisms, which are not yet fully understood. These phenomena, together with different temporal patterns of sympathetic nerve activity in different regional circulations, are probably an important mechanistic basis of the important selective regulation of regional vascular resistance and blood flow by the sympathetic nervous system.

Sympathetically evoked Ca2+ signaling in arterial smooth muscle.

The sympathetic nervous system plays an essential role in the control of total peripheral vascular resistance and blood flow, by controlling the contraction of small arteries. Perivascular sympathetic nerves release ATP, norepinephrine (NE) and neuropeptide Y. This review summarizes our knowledge of the intracellular Ca2+ signals that are activated by ATP and NE, acting respectively on P2X1 and alpha1-adrenoceptors in arterial smooth muscle. Each neurotransmitter produces a unique type of post-synaptic Ca2+ signal and associated contraction. The neural release of ATP and NE is thought to vary markedly with the pattern of nerve activity, probably reflecting both pre- and post-synaptic mechanisms. Finally, we show that Ca2+ signaling during neurogenic contractions activated by trains of sympathetic nerve fiber action potentials are in fact significantly different from that elicited by simple bath application of exogenous neurotransmitters to isolated arteries (a common experimental technique), and end by identifying important questions remaining in our understanding of sympathetic neurotransmission and the physiological regulation of contraction of small arteries.

P2X1 receptors mediate sympathetic postjunctional Ca2+ transients in mesenteric small arteries.

Brief, spatially localized Ca(2+) transients occur in the smooth muscle adjacent to perivascular nerves of small arteries during neurogenic contractions. We named these "junctional Ca(2+) transients" (jCaTs) and postulated that they arose from Ca(2+) entering smooth muscle cells through P2X(1) receptors activated by neurally released ATP. Nevertheless, the lack of potent, subtype-selective P2X-receptor antagonists made determining the exact molecular identity of the channels difficult. Here we used small, pressurized mesenteric arteries from P2X(1)-receptor-deficient mice (KO) to test the hypothesis that jCaTs arise from Ca(2+) entering the smooth muscle cell via P2X(1) receptors. In wild-type (WT) arteries, confocal microscopy of fluo-4 fluorescence during electrical field stimulation (EFS) of perivascular sympathetic nerves revealed jCaTs in the smooth muscle cells adjacent to the perivascular nerves, similar to those reported previously in rat arteries, and alpha-latrotoxin (2.5 nM) markedly increased the frequency of "spontaneous" jCaTs. In the KO arteries, however, neither EFS nor alpha-latrotoxin elicited any jCaTs. A potent P2X-receptor agonist, alpha,beta-methylene ATP (10.0 microM), elicited strong contractions and increased intracellular Ca(2+) concentration in WT arteries but elicited neither in KO arteries. A biphasic vasoconstriction in response to EFS was observed in WT arteries. In KO arteries, however, the initial rapid, transient component of the biphasic vasoconstriction was absent. The data support the hypothesis that jCaTs represent Ca(2+) that enters the smooth muscle cells through P2X(1) receptors activated by neurally released ATP and that this Ca(2+) is involved in the initial rapid component of the sympathetic neurogenic contraction.

Different roles of ryanodine receptors and inositol (1,4,5)-trisphosphate receptors in adrenergically stimulated contractions of small arteries.

The functions of ryanodine receptors (RyRs) and inositol (1,4,5)-trisphosphate receptors [Ins(1,4,5)P(3)Rs] in adrenergically activated contractions of pressurized rat mesenteric small arteries were investigated. Caffeine (20 mM) but not phenylephrine (PE; 10 microM) facilitated the depletion of smooth muscle sarcoplasmic reticulum (SR) Ca(2+) stores by ryanodine (40 microM). In ryanodine-treated SR-depleted arteries, 1) Ca(2+) sparks were absent, 2) low concentrations of PE failed to elicit either vasoconstriction or normal asynchronous propagating Ca(2+) waves, and 3) high [PE] induced abnormally slow oscillatory contractions (vasomotion) and synchronous Ca(2+) oscillations. In ryanodine-treated SR-depleted arteries denuded of endothelium, high [PE] induced steady contraction and steady elevation of intracellular [Ca(2+)]. In contrast, 2-aminoethyl diphenylborate (2-APB), a putative blocker of Ins(1,4,5)P(3)Rs, produced opposite effects to ryanodine: 1) Ca(2+) sparks were present; 2) Ca(2+) waves were absent; 3) caffeine-releasable Ca(2+) stores were intact; and 4) PE, even at high concentrations on endothelial-denuded arteries, failed to elicit contraction, asynchronous Ca(2+) waves, or synchronous Ca(2+) oscillations or maintained elevated [Ca(2+)]. We conclude that 1) Ins(1,4,5)P(3)Rs are essential for adrenergically induced asynchronous Ca(2+) waves and the associated steady vasoconstriction, 2) RyRs are not appreciably opened during adrenergic activation (because PE did not facilitate the development of the effects of ryanodine), and 3) Ins(1,4,5)P(3)Rs are not essential for Ca(2+) sparks. This provides an explanation of the fact that adrenergic stimulation decreases the frequency of Ca(2+) sparks (previously reported) while simultaneously increasing the frequency of asynchronous propagating Ca(2+) waves; different SR Ca(2+)-release channels are involved.

Purinergic and adrenergic Ca2+ transients during neurogenic contractions of rat mesenteric small arteries.

Contraction of small arteries is regulated by the sympathetic nervous system, but the Ca2+ transients during neurally stimulated contraction of intact small arteries have not yet been recorded. We loaded rat mesenteric small arteries with the fluorescent Ca2+ indicator fluo-4 and mounted them in a myograph that permitted simultaneous (i) high-speed confocal imaging of fluorescence from individual smooth muscle cells, (ii) electrical stimulation of perivascular nerves, and (iii) recording of isometric tension. Sympathetic neuromuscular transmission was achieved by electrical field stimulation (EFS) (frequency, 10 Hz; pulse voltage, 40 V; pulse duration, 0.2 ms) in the presence of capsaicin and scopolamine (to inhibit 'sensory' and cholinergic nerves, respectively). During the first 20 s of EFS, force rose to a small peak and then declined. During this time, junctional Ca2+ transients (jCaTs) were present at relatively high frequency. We have previously attributed jCaTs to influx of Ca2+ through post-junctional P2X receptors activated by ATP. Propagating asynchronous Ca2+ waves, previously associated with bath-applied alpha1-adrenoceptor agonists, were not initially present. During the next 2.5 min of EFS, force rose slowly, and asynchronous propagating Ca2+ waves appeared. The selective alpha1-adrenoceptor antagonist prazosin abolished both the slowly developing contraction and the Ca2+ waves, but reduced the initial transient contraction by only ~25 %. During 3 min of EFS in prazosin, the frequency of jCaTs declined markedly; at sites at which at least one jCaT occurred, the average probability of a jCaT was 0.008 +/- 0.002 pulse-1 in the first 20 s and 0.0007 +/- 0.0002 pulse-1 in the last 20 s. We suggest that (i) ATP released from sympathetic varicosities activates the initial, transient, contraction and the activator Ca2+ is derived largely from jCaTs, and (ii) sympathetically released noradrenaline (NA) activates the later, major contraction through mechanisms involving alpha1-adrenoceptors and which are associated with propagating Ca2+ waves.

Evoked and spontaneous purinergic junctional Ca2+ transients (jCaTs) in rat small arteries.

Confocal microscopy of fluo-4 fluorescence in pressurized rat mesenteric small arteries subjected to low-frequency electrical field stimulation revealed Ca2+ transients in perivascular nerves and novel, spatially localized Ca2+ transients in adjacent smooth muscle cells. These muscle Ca2+ transients occur with a very brief latency to the stimulus pulse (most <3 ms). They are wider (approximately 5 micro m) and last longer (t(1/2), 145 ms) than Ca2+ sparks. They are abolished by the purinergic receptor (P2X) antagonist suramin, but they are totally unaffected by the alpha1 adrenoceptor antagonist prazosin or by capsaicin (which inhibits the function of perivascular sensory nerves). We conclude that these novel Ca2+ transients represent Ca2+ entering smooth muscle cells through P2X receptors activated by ATP released from sympathetic nerves, and we therefore call them "junctional Ca2+ transients" or jCaTs. As expected from spontaneous neurotransmitter release, jCaTs also occur spontaneously, with characteristics identical to evoked jCaTs. Visualization of sympathetic neurotransmission shows that purinergic components dominate at low frequencies of sympathetic nerve fiber activation.