Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UNIPROT:P01185 (
vasopressin
)
23,126
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Classically, neuropeptide release occurs from axon terminals to influence post-synaptic neurons. However, it has become increasingly clear that many neurons in the central nervous system also release neuropeptide from their somata and dendrites. This somato-dendritic neuropeptide release can have many functions, amongst which is feedback modulation of activity. In addition, most central neurons also co-express other neurotransmitters/neuromodulators alongside their principal neurotransmitter, yet the function of these co-expressed factors is largely unknown. With regard to the function of somato-dendritic neuropeptide release, hypothalamic
vasopressin
neurons are amongst the best understood neurons in the central nervous system. Vasopressin neurons co-express a number of other neuropeptides including
apelin
, dynorphin and galanin as well as the purine, adenosine triphosphate. In addition to factors co-released during exocytosis,
vasopressin
neurons also generate nitric oxide. Each of these factors has been demonstrated to influence the activity of
vasopressin
neurons. For at least some of these factors, modulation of the activity of
vasopressin
neurons is activity dependent; suggesting that autocrine feedback regulation of activity might be an important role for somato-dendritic release of neuromodulators across the central nervous system.
...
PMID:Multi-factorial somato-dendritic regulation of phasic spike discharge in vasopressin neurons. 1865 85
This review concentrates on the characteristics and functionality of endocrine neurons in the hypothalamo-neurohypophysial system, coexpressing two peptides,
vasopressin
and
apelin
. Vasopressin is synthesized in the soma of magnocellular neurons, then packaged in granules with its respective receptors. In these neurons,
apelin
is generated from a larger precursor proapelin and is detected in vesicles, some of them colocalize with
vasopressin
, for others there is a marked segregation of
apelin
and
vasopressin
immunoreactivity along the hypothalamo-hypophyseal axons. Furthermore,
apelin
receptors, like V1a-type and V1b-type
vasopressin
receptors, are synthesized by magnocellular
vasopressin
neurons. In lactating rodents,
apelin
given intracerebroventricularly inhibited the phasic electrical activity of
vasopressin
neurons, reduced plasma
vasopressin
levels and increased aqueous diuresis, showing that
apelin
acts as a potent diuretic neuropeptide, counteracting
vasopressin
actions through inhibition of
vasopressin
neuron activity and
vasopressin
release. Moreover, in response to potent physiological stimuli known to evoke increased phasic activity of
vasopressin
neurons (hyper-osmolarity like during dehydration), both the soma dendrites and neurohypophysial terminals loose their dense staining quality, and
vasopressin
is released by (i) dendrites in the extracellular space to optimize the characteristic phasic activity necessary to a sustained release of
vasopressin
and (ii) by terminals in blood circulation where
vasopressin
then ensures its main endocrine actions at kidney level (antidiuretic effect). Conversely,
apelin
accumulates in these neurons rather than being released into the bloodstream and probably into the nuclei. Thus, decreases in the local supply of
apelin
to magnocellular
vasopressin
cell bodies may facilitate the expression by
vasopressin
neurons of an optimized phasic activity, by decreasing the inhibitory actions of
apelin
on these neurons. Antagonistic regulation of
apelin
and
vasopressin
has a biological purpose, making it possible to maintain the water balance of the organism by preventing additional water loss via kidneys. This reveals a new physiological concept of dual and opposite functional potentiality for endocrine neurons coexpressing different neuropeptides in separate vesicles: depending on the degree of their electrical activation/inhibition, neurons release selectively the very coexpressed peptides that will ensure its accurate endocrine functions in perfect accordance with the hormonal demand.
...
PMID:Opposite potentiality of hypothalamic coexpressed neuropeptides, apelin and vasopressin in maintaining body-fluid homeostasis. 1865 9
Apelin
, a novel peptide originally isolated from bovine stomach tissue extracts, is widely but selectively distributed throughout the nervous system. Vasopressin and oxytocin are synthesized in the magnocellular neurons of the hypothalamic supraoptic nucleus (SON) and paraventricular nucleus, which are
apelin
-rich regions in the central nervous system. We made extracellular electrophysiological recordings from the transpharyngeally exposed SON of urethane-anaesthetized rats to assess the role of
apelin
in the control of the firing activity of identified magnocellular
vasopressin
and oxytocin neurons in vivo.
Apelin-13
administration onto SON neurons via microdialysis revealed cell-specific responses;
apelin
-13 increased the firing rates of
vasopressin
cells but had no effect on the firing rate of oxytocin neurons. A direct excitatory effect of
apelin
-13 on
vasopressin
cell activity is also supported by our in vitro studies showing depolarization of membrane potential and increase in action potential firing. To assess the effects of
apelin
-13 on somatodendritic peptide release, we used in vitro release studies from SON explants in combination with highly sensitive and specific RIA.
Apelin-13
decreases basal (by 78%; P < 0.05; n = 6) and potassium-stimulated (by 57%; P < 0.05; n = 6)
vasopressin
release but had no effect on somatodendritic oxytocin release. Taken together, our data suggest a local autocrine feedback action of
apelin
on magnocellular
vasopressin
neurons. Furthermore, these data show a marked dissociation between axonal and dendritic
vasopressin
release with a decrease in somatodendritic release but an increase in electrical activity at the cell bodies, indicating that release from these two compartments can be regulated wholly independently.
...
PMID:The effects of apelin on the electrical activity of hypothalamic magnocellular vasopressin and oxytocin neurons and somatodendritic Peptide release. 1870 33
The intention of this review is to emphasize the current knowledge about the extent and importance of the substances co-localized with magnocellular arginine vasopressin (AVP) and oxytocin (OXY) as potential candidates for the gradual clarification of their actual role in the regulation of hydromineral homeostasis. Maintenance of the body hydromineral balance depends on the coordinated action of principal biologically active compounds, AVP and OXY, synthesized in the hypothalamic supraoptic and paraventricular nuclei. However, on the regulation of water-salt balance, other substances, co-localized with the principal neuropetides, participate. These can be classified as (1) peptides co-localized with AVP or OXY with unambiguous osmotic function, including angiotensin II,
apelin
, corticotropin releasing hormone, and galanin and (2) peptides co-localized with AVP or OXY with an unknown role in osmotic regulation, including cholecystokinin, chromogranin/secretogranin, dynorphin, endothelin-1, enkephalin, ferritin protein, interleukin 6, kininogen, neurokinin B, neuropeptide Y, vasoactive intestinal peptide, pituitary adenylate cyclase-activating polypeptide, TAFA5 protein, thyrotropin releasing hormone, tyrosine hydroxylase, and urocortin. In this brief review, also the responses of these substances to different hyperosmotic and hypoosmotic challenges are pointed out. Based on the literature data published recently, the functional implication of the majority of co-localized substances is still better understood in non-osmotic than osmotic functional circuits. Brattleboro strain of rats that does not express functional
vasopressin
was also included in this review. These animals suffer from chronic hypernatremia and hyperosmolality, accompanied by sustained increase in OXY mRNA in PVN and SON and OXY levels in plasma. They represent an important model of animals with constantly sustained osmolality, which in the future, will be utilizable for revealing the physiological importance of biologically active substances co-expressed with AVP and OXY, involved in the regulation of plasma osmolality.
...
PMID:Response of substances co-expressed in hypothalamic magnocellular neurons to osmotic challenges in normal and Brattleboro rats. 1877 90
We have employed microarray technology using Affymetrix 230 2.0 genome chips to initially catalog the transcriptome of the subfornical organ (SFO) under control conditions and to also evaluate the changes (common and differential) in gene expression induced by the challenges of fluid and food deprivation. We have identified a total of 17,293 genes tagged as present in one of our three experimental conditions, transcripts, which were then used as the basis for further filtering and statistical analysis. In total, the expression of 46 genes was changed in the SFO following dehydration compared with control animals (22 upregulated and 24 downregulated), with the largest change being the greater than fivefold increase in brain-derived neurotrophic factor (BDNF) expression, while significant changes in the expression of the calcium-sensing (upregulated) and
apelin
(downregulated) receptors were also reported. In contrast, food deprivation caused greater than twofold changes in a total of 687 transcripts (222 upregulated and 465 downregulated), including significant reductions in
vasopressin
, oxytocin, promelanin concentrating hormone, cocaine amphetamine-related transcript (CART), and the endothelin type B receptor, as well as increases in the expression of the GABA(B) receptor. Of these regulated transcripts, we identified 37 that are commonly regulated by fasting and dehydration, nine that were uniquely regulated by dehydration, and 650 that are uniquely regulated by fasting. We also found five transcripts that were differentially regulated by fasting and dehydration including BDNF and CART. In these studies we have for the first time described the transcriptome of the rat SFO and have in addition identified genes, the expression of which is significantly modified by either water or food deprivation.
...
PMID:Microarray analysis of the transcriptome of the subfornical organ in the rat: regulation by fluid and food deprivation. 1883 82
During disease states, the endocrine axes exhibit different levels of activity according to the severity of illness. These various alterations have been widely investigated. Indeed, evidence indicates that the anterior pituitary is dysfunctional in these states, especially when multiple organ dysfunction syndrome is present, impacting both adrenal and thyroid glands, but also secretion of estrogen, growth hormone, insulin-like growth factor-1, and prolactin. In a majority of these cases, substitutive treatment is not obviously beneficial, inappropriate secretions being considered as adaptive responses to stressful events. The hypothalamic-pituitaryadrenal axis appears to play the most important role in the regulation of inflammation during septic shock. Many factors modulate this axis. Some are well known. Others, such as
vasopressin
and
apelin
, are newly ascribed. Therapeutic issues in critically ill patients still remain controversial and are ardently debated, especially with regard to the needs and practical use of corticosteroids in septic shock. This article focuses on actual knowledge, mechanisms, definitions, and therapeutic recommendations, as well as on areas of uncertainty relative to adrenal gland insufficiency in septic shock.
...
PMID:Adrenal insufficiency in septic shock. 1918 78
The apelinergic system has a widespread expression in the central nervous system (CNS) including the paraventricular nucleus, supraoptic nucleus and median eminence, and isolated cells of the anterior lobe of the pituitary. This pattern of expression in hypothalamic nuclei known to contain corticotrophin-releasing factor (CRF) and
vasopressin
(AVP) and to co-ordinate endocrine responses to stress has generated interest in a role for
apelin
in the modulation of stress, perhaps via the regulation of hormone release from the pituitary. In this study, to determine whether
apelin
has a central role in the regulation of CRF and AVP neurones, we investigated the effect of i.c.v. administration of pGlu-
apelin
-13 on neuroendocrine function in male mice pre-treated with the CRF receptor antagonist, alpha-helical CRF(9-41), and in mice-lacking functional AVP V1b receptors (V1bR KO). Administration of pGlu-
apelin
-13 (1 mg/kg i.c.v.) resulted in significant increases in plasma ACTH and corticosterone (CORT), which were significantly reduced by pre-treatment with alpha-helical CRF(9-41), indicating the involvement of a CRF-dependent mechanism. Additionally, pGlu-
apelin
-13-mediated increases in both plasma ACTH and CORT were significantly attenuated in V1bR KO animals when compared with wild-type controls, indicating a role for the vasopressinergic system in the regulation of the effects of
apelin
on neuroendocrine function. Together, these data confirm that the in vivo effects of
apelin
on hypothalamic-pituitary-adrenal neuroendocrine function appear to be mediated through both CRF- and AVP-dependent mechanisms.
...
PMID:The effects of apelin on hypothalamic-pituitary-adrenal axis neuroendocrine function are mediated through corticotrophin-releasing factor- and vasopressin-dependent mechanisms. 1939 47
Apelin
is a recently identified peptide which plays an important role in cardiovascular function and in water metabolism.
Apelin
and its receptor APJ (
apelin
system) are involved in zebra fish and xenopus cardiovascular development.
Apelin
is a pro-angiogenic factor.
Apelin
is a potent cardiac inotropic agent and exerts a vasodilatory effect in arterial and venous territories.
Apelin
decreases
vasopressin
production and its plasma level is conversely related to plasma
vasopressin
. Several effects of the
apelin
system counteract those of the renin angiotensin system. It may represent a new and promising therapeutic opportunity for the treatment of cardiovascular diseases.
...
PMID:[Effect of apelin in cardiovascular system and water metabolism]. 1980 3
Apelin
plays a prominent role in body fluid and cardiovascular homeostasis. To explore further upstream the role played by this peptide, nonpeptidic agonists and antagonists of the apelin receptor are required. To identify such compounds that do not exist to date, we used an original fluorescence resonance energy transfer-based assay to screen a G-protein-coupled receptor-focused library of fluorescent compounds on the human EGFP-tagged apelin receptor. This led to isolated E339-3D6 that displayed a 90 nM affinity and behaved as a partial agonist with regard to cAMP production and as a full agonist with regard to apelin receptor internalization. Finally, E339-3D6 induced vasorelaxation of rat aorta precontracted with noradrenaline and potently inhibited systemic
vasopressin
release in water-deprived mice when intracerebroventricularly injected. This compound represents the first nonpeptidic agonist of the apelin receptor, the optimization of which will allow development of a new generation of vasodilator and aquaretic agents.
...
PMID:Identification and pharmacological properties of E339-3D6, the first nonpeptidic apelin receptor agonist. 2004 May 17
The discovery of
apelin
, an endogenous ligand of the orphan APJ receptor, constitutes an important advance in both fundamental research and clinical medicine. Experimental data have shown that
apelin
has a diuretic effect via its central and renal actions: by inhibiting the phasic activity of vasopressinergic neurons and systemic secretion of
vasopressin
and its direct effect on the renal microcirculation and probably tubular function. Besides its diuretic action, when injected into the blood stream,
apelin
decreases blood pressure and increases the contractile force of the myocardium while decreasing pre- and post-load, actions opposing those of
vasopressin
and angiotensin II. Taken together, these data show that this new circulating vasoactive (neuro)peptide could play a crucial role in maintaining water and electrolyte balance and cardiovascular functions. Finally, a systemic injection of
apelin
in insulin-resistant mice decreases glycemia and enhances glucose uptake in skeletal muscle and adipose tissue, contributing to homeostatic control of blood glucose. Clinically, the development of non-peptide analogs of the apelin receptor could provide new therapeutic tools potentially useful for the treatment of heart failure, states of water and/or electrolyte retention, and type 2 diabetes mellitus.
...
PMID:[Contribution of apelin to water balance, blood glucose control, and cardiovascular functions]. 2041 60
<< Previous
1
2
3
4
Next >>
