Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01185 (vasopressin)
 23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Myocardial ischemia results in myocardial dysfunction. Recovery may be delayed ("stunning"), or persistent if perfusion remains reduced ("hibernation") and ischemia may go on to necrosis, thus, contributing to chronic heart failure. In addition, myocardium not directly affected by ischemia may undergo adaptive processes like hypertrophy and dilatation, which may result in chronic left heart failure. This process is characterized by hemodynamic, neurohumoral, and progressive morphologic changes of the heart which are closely interrelated. Hemodynamic changes basically consist of an increase in left ventricular filling pressure and a decrease in global ejection fraction, and, in most cases years after myocardial infarction, in an increase in systemic vascular resistance and right atrial pressure. Neurohumoral changes consist of an increase in plasma catecholamines, atrial natriuretic factor and vasopressin, and in an activation of the renin-angiotensin-system. Plasma endothelin-1 was recently reported to be increased in patients with heart failure, and prognosis was related to endothelin levels. Diminished response of vessels to endothelium (EDRF/NO) dependent vasodilatation suggests impairment of vascular endothelium in heart failure. Local changes of cardiac neurohumoral systems could contribute to structural changes of the heart, e.g., systemic activation to hemodynamic changes. Structural changes of the heart are characterized by an increase in volume and thickness of surviving myocardium and an expansion of ischemic and necrotic myocardium. Molecular control of these processes which include various cell types, such as cardiomyocytes and cardiofibroblasts, are currently an issue of intense research and could result in specific therapeutic importance.
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PMID:[Transition of myocardial ischemia to heart failure]. 981 48

We investigated the effects of the prolyl endopeptidase inhibitors 1-[1-(Benzyloxycarbonyl)-L-prolyl]prolinal (Z-Pro-Prolinal) and N-benzyloxycarbonyl-thioprolyl-thioprolinal-dimethylaceta l (ZTTA) on delayed neuronal death induced by four-vessel-occlusion transient ischemia in rats. We also examined the effects of [pGlu4, Cyt6, ArgS]vasopressin (vasopressin-(4-9)) and thyrotropin-releasing hormone (TRH) on the delayed neuronal death. Furthermore, we investigated the role of vasopressin receptors in the effects of vasopressin and prolyl endopeptidase inhibitors. Z-Pro-Prolinal, vasopressin-(4-9) and TRH protected pyramidal cells in the CA1 subfield of the rat hippocampus from delayed neuronal death after 10-min ischemia. The effect of vasopressin-(4-9) was abolished by vasopressin receptor antagonists. The effect of Z-Pro-Prolinal was also abrogated by the antagonists. These results suggest that the neuroprotective effect of prolyl endopeptidase inhibitors is mediated by neuropeptides such as [Arg8]vasopressin and TRH, and indicate the involvement of vasopressin receptors in the neuroprotective effect of vasopressin-(4-9) and prolyl endopeptidase inhibitors.
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PMID:Effects of prolyl endopeptidase inhibitors and neuropeptides on delayed neuronal death in rats. 1039 93

Modern data of molecular and biological properties and physiological role of new pituitary adenylate cyclase activating polypeptide--PACAP--review. PACAP play key role in the embryogenesis of brain, in the protection of brain nerve cells from ischemia-induced death, injuring and apoptosis. New data are discussed concerned with molecular cloning and tissue distribution of receptors for PACAP, gene proPACAP expression in gastrointestinal tract, reproductive organs and nervous system. PACAP increase cytosolic free calcium and modifies the calcium-sensitive K(+)-channels, PACAP protects cultures cortical and hippocampal neurons from glutamate-induced cytotoxicity. The sleep modulation and modification of seizures activity of brain through the secretion of vasopressin or/and through NMDA receptors directly should be include in the program of PACAP "physiological continuum" of functions.
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PMID:[Pituitary adenylate cyclase activating peptide (PACAP)--its polyfunctionality in the mechanisms of brain protection]. 1042 Apr 72

Both oxytocin and vasopressin cause potent and long-lasting vasoconstriction of uterine arteries from several species, including humans, and the resulting tissue ischemia is thought to be involved in the pathogenesis of primary dysmenorrhea. We have studied the effects of oxytocin and vasopressin in isolated resistance arteries (diameter, 90-120 microm) from non-pregnant rat uteri using two potent and selective receptor antagonists, SR 49059, a selective vasopressin V1A antagonist, and atosiban, a selective oxytocin antagonist. Uterine arteries with intact endothelium were mounted in a microvessel chamber, and pressurized to 75 mm Hg to allow the development of myogenic tone. Both vasopressin and oxytocin elicited a concentration-dependent vasoconstriction with a similar maximum effect (i.e., total vessel occlusion). The EC50 was 0.44 +/- 0.02 and 25 +/- 3.1 nM for vasopressin and oxytocin, respectively. Thus, vasopressin was 57-fold more potent than oxytocin. Schild analysis indicated that SR 49059 yielded a similar pA2 value against vasopressin-induced (pA2 = 8.96 +/- 0.60) or oxytocin-induced (pA2 = 9.06 +/- 0.23) contractions, suggesting that both agonists activated the vasopressin V1A receptor. In addition, atosiban (10(-7) M), a selective antagonist of the oxytocin receptor in the rat, did not antagonize the effect of vasopressin and oxytocin, showing that the oxytocin receptor is not involved in the response. In conclusion, these results suggest that V1A receptor stimulation is responsible for the vasoconstricting effects of both vasopressin and oxytocin in small diameter resistance arteries from the rat uterus.
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PMID:Oxytocin and vasopressin constrict rat isolated uterine resistance arteries by activating vasopressin V1A receptors. 1044 88

Estrogen administration has a number of favorable cardiovascular effects, and recent evidence suggests that these include an increase in arterial distensibility. Whether this is also the case for the physiological changes in estrogen production during the menstrual cycle has never been determined, however. In 21 premenopausal healthy women, we continuously measured radial artery diameter and blood pressure by an echo-tracking device and a beat-to-beat finger device, respectively. Arterial distensibility was calculated as distensibility/blood pressure curve. The measurements were made during the follicular, ovulatory, and luteal phases of the menstrual cycle. As expected, compared with the follicular phase, plasma estradiol, follicle-stimulating hormone, luteinizing hormone, and prolactin were increased in the ovulatory phase, whereas progesterone was increased in the luteal phase, together with antidiuretic hormone. Radial artery distensibility was increased in the ovulatory and reduced in the luteal phase, the changes being independent of the small, concomitant blood pressure changes. The arterial wall stiffening seen in the luteal phase was associated with a reduction in the flow-dependent endothelial dilatation of the radial artery as assessed by the hyperemia after short-term ischemia of the hand. Thus, the natural menstrual cycle is characterized by alterations in radial artery distensibility. The mechanisms responsible for this phenomenon remain to be clarified. It is possible, however, that the greater arterial distensibility of the ovulatory phase is due to an estrogen-dependent reduction in vascular smooth muscle tone, whereas the arterial stiffening of the luteal phase depends on vascular smooth muscle contraction due to more complex hormonal phenomena, ie, an endothelial impairment due to estrogen reduction but also to an increase in progesterone and antidiuretic hormone levels.
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PMID:Fluctuations of radial artery distensibility throughout the menstrual cycle. 1044 72

Previous studies indicate that cardiogenic shock (tamponade) in swine produces selective mesenteric ischemia due to disproportionate mesenteric vasospasm mediated primarily by the renin-angiotensin axis. Here, we characterized the systemic and mesenteric hemodynamic responses to hypovolemic shock to better understand the neurohumoral mechanisms controlling this response. Varying degrees of hypovolemic shock were produced by graded levels of hemorrhage, from 12.5 to 50% of the calculated blood volume. Systemic and mesenteric pressures and blood flows were measured, and corresponding vascular resistances were calculated. The hemodynamic responses of the mesenteric vascular bed were compared with those of the systemic (nonmesenteric) vasculature. These experiments were then repeated after confirmed blockade either of the alpha-adrenergic nervous system (phenoxybenzamine), of vasopressin (Manning compound), or of the renin-angiotensin axis (enalapril). Graded levels of hemorrhage produced corresponding graded, reproducible, steady-state levels of systemic hypotension, hypoperfusion, and peripheral vasoconstriction, i.e., hemorrhagic shock. This was associated with disproportionate degrees of mesenteric ischemia due to disproportionate mesenteric vasoconstriction. The selective component of this mesenteric vasoconstrictive response was not attenuated by a-adrenergic blockade nor by vasopressin blockade but was blocked by ablation of the renin-angiotensin axis with enalapril. Like cardiogenic shock, hemorrhagic shock generates selective mesenteric ischemia by producing a disproportionate mesenteric vasospasm that is mediated primarily by the renin-angiotensin axis.
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PMID:Mesenteric vasoconstriction in response to hemorrhagic shock. 1077 14

The mesenteric hemodynamic response to circulatory shock is characteristic and profound; this vasoconstrictive response disproportionately affects both the mesenteric organs and the organism as a whole. Vasoconstriction of post-capillary mesenteric venules and veins, mediated largely by the alpha-adrenergic receptors of the sympathetic nervous system, can effect an "autotransfusion" of up to 30% of the total circulating blood volume, supporting cardiac filling pressures ("preload"), and thereby sustaining cardiac output at virtually no cost in nutrient flow to the mesenteric organs. Under conditions of decreased cardiac output caused by cardiogenic or hypovolemic shock, selective vasoconstriction of the afferent mesenteric arterioles serves to sustain total systemic vascular resistance ("afterload"), thereby maintaining systemic arterial pressure and sustaining the perfusion of non-mesenteric organs at the expense of mesenteric organ perfusion (Cannon's "flight or fight" response). This markedly disproportionate response of the mesenteric resistance vessels is largely independent of the sympathetic nervous system and variably related to vasopressin, but mediated primarily by the renin-angiotensin axis. The extreme of this response can lead to gastric stress erosions, nonocclusive mesenteric ischemia, ischemic colitis, ischemic hepatitis, ischemic cholecystitis, and/or ischemic pancreatitis. Septic shock can produce decreased or increased mesenteric perfusion, but is characterized by an increased oxygen consumption that exceeds the capacity of mesenteric oxygen delivery, resulting in net ischemia and consequent tissue injury. Mesenteric organ injury from ischemia/reperfusion due to any form of shock can lead to a triggering of systemic inflammatory response syndrome, and ultimately to multiple organ dysfunction syndrome. The mesenteric vasculature is therefore a major target and a primary determinant of the systemic response to circulatory shock.
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PMID:The mesenteric hemodynamic response to circulatory shock: an overview. 1133 91

An electron microscopic immunocytochemical study was performed in order to determine the expression pattern of endothelial nitric oxide synthase (eNOS) in rat neurohypophysis after ischemia. In basal conditions eNOS was found to be weakly expressed on the endothelial cells and on single activated neurohypophyseal mastocytes. After cerebral ischemia, the number of mast cells increased in the neurohypophysis. The eNOS immunolabelling of mast cells was strongly enhanced between 10 min and 3 h after ischemia and declined at 24 h after ischemia. eNOS labelling was also enhanced in endotethelial cells between 30 min and 3 h after ischemia. Ultrastructurally, eNOS labelling was restricted to the granules of activated mast cells and the cytoplasm of endothelial cells. This study suggests that cerebral mastocytes are an important source of eNOS in neurohypophysis during ischemia and contribute to nitric oxide production in the perivascular space.
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PMID:Induction of endothelial nitric oxide synthase in perivascular mast cells in rat neurohypophysis after ischemia. 1146 13

NC-1900, an arginine-vasopressin derivative, has been reported to enhance memory for avoidance behavior. Specifically, NC-1900 ameliorated cycloheximide-induced learning impairments in a passive avoidance test in rats. In the present study, we investigated that effects of NC-1900 on place learning in rats with selective lesions in the CA1 subfield of the hippocampal formation produced by transient forebrain ischemia. NC-1900 was administered daily (1 microg/kg, p.o.) 1 h before the place learning task. A rat was required to alternate between 2 small circular areas located diametrically opposite each other on the circumference of an open field in order to obtain intracranial electrical stimulation reward (the spatial navigation task). Rats with hippocampal lesions showed severe place learning impairments both in task performance (indicated by number of rewards obtained per a session) and in navigation performance (forming efficient trails) over the 30-day test period. Treatment with NC-1900 ameliorated deficits in the place learning exhibited by rats with the same hippocampal lesions, such that their performance reached normal levels. There were no significant differences in the ischemic hippocampal lesions, spontaneous locomotor activity, and stimulation current intensity between the treated and untreated rats. The results demonstrated that NC-1900 reduced place learning impairments produced by hippocampal lesions.
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PMID:Effects of a novel arginine-vasopressin derivative, NC-1900, on the spatial memory impairment of rats with transient forebrain ischemia. 1186 46

The effects of paraventricular nucleus (PVN) stimulation and vasopressin on gastric ischemia-reperfusion injury (GI-RI) were investigated in male SD rats of which the celiac artery was clamped for 30 min and reperfused for 1 h by removal of the clamp. The results were as follows. Both electrical and chemical stimulation of the PVN obviously attenuated the GI-RI. Bilateral electrolytic lesion of the nucleus tractus solitarius (NTS) or microinjection of AVP-V(1) receptor antagonist into the NTS could eliminate the protective effect of electrical stimulation of the PVN on GI-RI. Hypophysectomy did not influence the effect of electrical stimulation of the PVN. Both vagotomy and sympathectomy could increase the effect of stimulating PVN on GI-RI. Microinjection of arginine-vasopressin (AVP) into the PVN also attenuated the effect on GI-RI. These results suggest that the PVN and AVP participate in the regulation of GI-RI and play an important role in protection against GI-RI. This protective effect of PVN on GI-RI might be mediated by activation of AVP-ergic neurons in the PVN, which release AVP from the descending projection fibers and activate the AVP-V(1) receptors on the NTS neurons. The vagus and sympathetic nerves are involved in the efferent pathway exerting their effects on GI-RI. Hypophysis does not seem to be involved in the protective effect of PVN stimulation.
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PMID:[Protective effects of paraventricular nucleus stimulation and vasopressin on gastric ischemia-reperfusion injury in rats]. 1197 93


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