UNIPROT:P01185 - FACTA Search

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Query: UNIPROT:P01185 (vasopressin)
23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. The brain of the locust contains an extraocular photoreceptor (EOP), which provides the major synaptic excitation to the vasopressin-like immunoreactive (VPLI) interneuron of the suboesophageal ganglion. Although the precise location of the EOP remains unknown, its activity can be determined indirectly by intracellular recording from the VPLI neuron. The excitatory drive to the VPLI neuron occurs only in darkness and is absent in the light. 2. The EOP is preferentially sensitive to light of wavelength 494 +/- 7 (SD) nm (blue-green) and has an absorption spectrum characteristic of a rhodopsin-like photopigment. 3. In the presence of high divalent saline (20 mM Ca2+ and Mg2+), the VPLI neuron receives excitatory input in the light. This indicates that the excitatory input to the VPLI neuron is from a tonically active descending input, which normally is inhibited by the light-induced activation of the presynaptic EOP. 4. Stimulation of the connectives while recording the resultant excitatory postsynaptic potential (EPSP) evoked in VPLI shows that the descending input projects beyond the suboesophageal ganglion, extending as far as the metathoracic ganglion. 5. Pharmacological analysis shows that the descending input to the VPLI neuron is cholinergic: acetylcholine (ACh) strongly depolarizes the neuron and eserine, an ACh esterase inhibitor, markedly potentiates the synaptic excitation of the VPLI neuron. 6. Nicotinic and muscarinic receptor antagonists show that the excitation of VPLI consists of two pharmacologically discrete components. Nicotinic ACh receptors mediate a fast depolarization, whereas muscarinic ACh receptors evoke a more sustained depolarization. Accordingly, both a fast and slow depolarization can be evoked selectively in VPLI by direct application of either nicotine or muscarine. 7. Voltage-clamp analysis shows that the fast EPSP evoked current is similar to that produced by nicotine in that it decreases linearly with membrane depolarization. The current associated with the sustained depolarization is similar to that evoked by muscarine, increasing nonlinearly with membrane depolarization. 8. Activity of the descending input, or application of muscarine, lowers the spike-initiation threshold of the VPLI neuron, thereby increasing its excitability. 9. It is concluded that the presence of two ACh receptor subtypes act synergistically to allow continuous activity of the VPLI neuron for sustained periods (i.e., throughout the hours of darkness).
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PMID:Pharmacological analysis of the cholinergic input to the locust VPLI neuron from an extraocular photoreceptor system. 789 95

The antidiuretic hormone arginine vasopressin (AVP) receptors are G protein-coupled and have been divided into at least three types: V1a (vascular/hepatic) and V1b (anterior pituitary) receptors, which act through phosphatidylinositol hydrolysis to mobilize intracellular Ca2+; and V2 (kidney) receptor, which is coupled to adenylate cyclase. Recently V1a and V2 receptor cDNAs were cloned. These cDNAs encode proteins with seven putative transmembrane domains and a similar structure to rhodopsin and other G protein-coupled receptors. Micro-localization of mRNA coding for V1a and V2 receptors was carried out in the rat kidney using a reverse transcription and polymerase chain reaction. Large signals for V1a receptor PCR product were detected in glomerulus, cortical collecting duct (CCD), outer medullary collecting duct (OMCD), inner medullary collecting duct (IMCD), and arcuate artery. Large signals for V2 receptor PCR product were detected in CCD, OMCD, and IMCD. 72-hour dehydration caused decrease of V2 receptor mRNA, but no change in V1a receptor mRNA in rat IMCD. These data show that mRNA coding for the two AVP receptor subtypes are distributed differently along the nephron and renal vascular system, and that these mRNAs are regulated differently in response to the dehydrated state. Recently, two reports of a mutation in the vasopressin V2 receptor gene in a kindred with X-rinked nephrogenic diabetes insipidus are published. These studies demonstrated that point mutation of V2 receptor gene causes the nephrogenic diabetes insipidus. Understanding the nature of defective diabetes insipidus may ultimately lead to improved therapy.
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PMID:[Recent advances in vasopressin receptors and signal transduction system]. 825 35

G proteins couple receptors for many hormones and neurotransmitters to effectors that regulate second messenger metabolism. G protein-coupled receptors comprise a superfamily with the common structural feature of a single polypeptide with seven membrane-spanning domains. G proteins themselves are heterotrimers with an alpha subunit that binds guanine nucleotides. In the basal state, G proteins tightly bind GDP; receptor activation allows exchange of bound GDP for GTP that activates the G protein and causes it to modulate effector activity. An intrinsic GTPase activity hydrolyzes bound GTP to GDP thereby deactivating the G protein. The effects (cholera, whooping cough) of bacterial toxins that target G proteins for covalent modification signal the potential importance of G protein dysfunction as a cause of human disease. Conceptually, G protein dysfunction could involve gain or loss of function. For Gs, examples of both types have already been defined. Mutations in G protein-coupled receptors have also been identified in several human diseases. Germline loss of function mutations in rhodopsin, cone opsins, the V2 vasopressin receptor, ACTH receptor, and calcium-sensing receptor are responsible for retinitis pigmentosa, color blindness, nephrogenic diabetes insipidus, familial ACTH resistance, and familial hypocalciuric hypercalcemia, respectively. Missense mutations that cause constitutive receptor activation have been identified in the TSH and LH receptors.
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PMID:Defects in G protein-coupled signal transduction in human disease. 881 89

The V2 vasopressin renal receptor (V2R), which controls antidiuresis in mammals, is a member of the large family of heptahelical transmembrane (7TM) G protein-coupled receptors (GPCRs). Using the automated GPCR modeling facility available via Internet (http:/(/)expasy.hcuge.ch/swissmod/SWISS-MODEL.+ ++html) for construction of the 7TM domain in accord with the bovine rhodopsin (RD) footprint, and the SYBYL software for addition of the intra- and extracellular domains, the human V2R was modeled. The structure was further refined and its conformational variability tested by the use of a version of the Constrained Simulated Annealing (CSA) protocol developed in this laboratory. An inspection of the resulting structure reveals that the V2R (likewise any GPCR modeled this way) is much thicker and accordingly forms a more spacious TM cavity than most of the hitherto modeled GPCR constructs do, typically based on the structure of bacteriorhodopsin (BRD). Moreover, in this model the 7TM helices are arranged differently than they are in any BRD-based model. Thus, the topology and geometry of the TM cavity, potentially capable of receiving ligands, is in this model quite different than it is in the earlier models. In the subsequent step, two ligands, the native [arginine8]vasopressin (AVP) and the selective agonist [D-arginine8]vasopressin (DAVP) were inserted, each in two topologically non-equivalent ways, into the TM cavity and the resulting structures were equilibrated and their conformational variabilities tested using CSA as above. The best docking was selected and justified upon consideration of ligand-receptor interactions and structure-activity data. Finally, the amino acid residues were indicated, mainly in TM helices 3-7, as potentially important in both AVP and DAVP docking. Among those Cys112, Val115-Lys116, Gln119, Met123 in helix 3; Glu174 in helix 4; Val206, Ala210, Val213-Phe214 in helix 5; Trp284, Phe287-Phe288, Gln291 in helix 6; and Phe307, Leu310, Ala314 and Asn317 in helix 7 appeared to be the most important ones. Many of these residues are invariant for either the GPCR superfamily or the neurophyseal (vasopressin V2R, V1aR and V1bR and oxytocin OR) subfamily of receptors. Moreover, some of the equivalent residues in V1aR have already been found critical for the ligand affinity.
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PMID:Molecular modeling of the human vasopressin V2 receptor/agonist complex. 974 70

The aim of the current study is to investigate whether homology models of G-Protein-Coupled Receptors (GPCRs) that are based on bovine rhodopsin are reliable enough to be used for virtual screening of chemical databases. Starting from the recently described 2.8 A-resolution X-ray structure of bovine rhodopsin, homology models of an "antagonist-bound" form of three human GPCRs (dopamine D3 receptor, muscarinic M1 receptor, vasopressin V1a receptor) were constructed. The homology models were used to screen three-dimensional databases using three different docking programs (Dock, FlexX, Gold) in combination with seven scoring functions (ChemScore, Dock, FlexX, Fresno, Gold, Pmf, Score). Rhodopsin-based homology models turned out to be suitable, indeed, for virtual screening since known antagonists seeded in the test databases could be distinguished from randomly chosen molecules. However, such models are not accurate enough for retrieving known agonists. To generate receptor models better suited for agonist screening, we developed a new knowledge- and pharmacophore-based modeling procedure that might partly simulate the conformational changes occurring in the active site during receptor activation. Receptor coordinates generated by this new procedure are now suitable for agonist screening. We thus propose two alternative strategies for the virtual screening of GPCR ligands, relying on a different set of receptor coordinates (antagonist-bound and agonist-bound states).
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PMID:Protein-based virtual screening of chemical databases. II. Are homology models of G-Protein Coupled Receptors suitable targets? 1247 95

Vasopressin (VP) receptors belong to the widespread G protein-coupled receptor family. The crucial role of VP receptor intracellular loops in the coupling with the heterotrimeric G proteins was previously demonstrated by construction of a vasopressin receptor chimera. Yet, no fine structural data are available concerning the receptor molecular determinants involved in their interactions with G proteins. In this study, we synthesized both a linear and a cyclic form of the second intracellular loop (i2) of the human V(1a) vasopressin receptor isoform that is important for the interaction between the alphaq/alpha11 G protein and the receptor. These two peptides are biologically active. They specifically inhibit vasopressin binding to the V(1a) receptor, suggesting that the corresponding endogenous peptides contribute to the structure of the vasopressin binding site via intra- or intermolecular interactions with the core of the V(1a) receptor. The i2 peptide structures were determined by (1)H NMR. Both exhibit a helix and helical elements in their N- and C-terminal parts, respectively, separated by a turn imposed by a proline residue. More interestingly, the central Pro-Leu motif conserved in many GPCRs and thought to be important for coupling to G proteins can adopt different conformations. The "U" shape structure of the i2 loop is compatible with its anchoring to transmembrane domains III and IV and is very similar to the shape of bovine rhodopsin i2. Altogether, these data contribute to a better understanding of the structure of a not yet crystallized GPCR using the mimetic peptide approach.
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PMID:Active peptidic mimics of the second intracellular loop of the V(1A) vasopressin receptor are structurally related to the second intracellular rhodopsin loop: a combined 1H NMR and biochemical study. 1284 69

In mammals, the vasopressin V(1b) receptor (V(1b)-R) is known to regulate ACTH secretion and, more recently, stress and anxiety. The characterization of the molecular determinant responsible for its pharmacological selectivity was made possible by the recent discovery of the first V(1b) antagonist, SSR149415. Based upon the structure of the crystallized bovine rhodopsin, we established a three-dimensional molecular model of interaction between the human V(1b)-R (hV(1b)-R) and SSR149415. Four amino acids located in distinct transmembrane helices (fourth, fifth, and seventh) were found potentially responsible for the hV(1b)-R selectivity. To validate these assumptions, we selectively replaced the leucine 181, methionine 220, alanine 334, and serine 338 residues of hV(1a)-R by their corresponding amino acids present in the hV(1b)-R (phenylalanine 164, threonine 203, methionine 324, and asparagine 328, respectively). Four mutants, which all exhibited nanomolar affinities for vasopressin and good coupling to phospholipase C pathway, were generated. hV(1a) receptors mutated at position 220 and 334 exhibited striking increase in affinity for SSR149415 both in binding and phospholipase C assays at variance with the hV(1a)-R modified at position 181 or 338. In conclusion, this study provides the first structural features concerning the hV(1b)-R and highlights the role of few specific residues in its pharmacological selectivity.
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PMID:Key amino acids located within the transmembrane domains 5 and 7 account for the pharmacological specificity of the human V1b vasopressin receptor. 1528 36

The neurohypophyseal hormone oxytocin (CYIQNCPLG-NH(2), OT) is involved in the control of labor, secretion of milk and many social and behavioral functions via interaction with its receptors (OTR) located in the uterus, mammary glands and peripheral tissues, respectively. In this paper we propose the interactions responsible for OT binding and selectivity to OTR versus vasopressin ([F3,R8]OT, AVP) receptors: V1aR and V2R, all three belonging to the Class A G protein-coupled receptors (GPCRs). Three-dimensional models of the activated receptors were constructed using a multiple sequence alignment and the activated rhodopsin-transducin (MII-Gt) prototype [Slusarz and Ciarkowski, 2004] as a template. The 1 ns unconstrained molecular dynamics (MD) of three pairs of receptor-OT complexes (two complexes per each receptor) immersed in the fully hydrated 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine (POPC) lipid bilayer was conducted in the AMBER 7.0 force field. The relaxed models of ligand-receptor complexes were used to identify the putative binding sites of OT. The stabilizing interactions with conserved Gln residues in all complexes were identified. The nonconserved hydrophobic residues were proposed as responsible for OTR-OT selectivity and ligand recognition. These results provide guidelines for experimental site-directed mutagenesis and if confirmed, they may be helpful in designing new selective OT analogs with both agonistic or antagonistic properties.
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PMID:Molecular dynamics simulation of human neurohypophyseal hormone receptors complexed with oxytocin-modeling of an activated state. 1611 99

Vasopressin (CYFQNCPRG-NH(2), AVP) is a semicyclic endogenous peptide, which exerts a variety of biological effects in mammals. The main physiological roles of AVP are the regulation of water balance and the control of blood pressure and adrenocorticotropin hormone (ACTH) secretion, mediated via three different subtypes of vasopressin receptors: V1a, V1b and V2 receptors (V1aR, V1bR and V2R, respectively). They are the members of the class A, G-protein-coupled receptors (GPCRs). AVP also modulates several behavioral and social functions. In this study, the interactions responsible for AVP binding to vasopressin V1a and V2 receptors versus the closely related oxytocin ([I3,L8]AVP, OT) receptor (OTR) have been investigated. Three-dimensional models of the activated receptors were constructed using multiple sequence alignment, followed by homology modeling using the complex of activated rhodopsin with Gt(alpha) C-terminal peptide of transducin MII-Gt(338-350) prototype as a template. AVP was docked into the receptor-G(alpha) systems. The three lowest-energy pairs of receptor-AVP-G(alpha) (two complexes per each receptor) were selected. The 1-ns unconstrained molecular dynamics (MD) of complexes embedded into the fully hydrated 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine (POPC) lipid bilayer was conducted in the AMBER 7.0 force field. Six relaxed receptor-AVP-G(alpha) models were obtained. The residues responsible for AVP binding to vasopressin receptors have been identified and a different mechanism of AVP binding to V2R than to V1aR has been proposed.
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PMID:Analysis of interactions responsible for vasopressin binding to human neurohypophyseal hormone receptors-molecular dynamics study of the activated receptor-vasopressin-G(alpha) systems. 1611

The V2 vasopressin receptor, a member of the rhodopsin subfamily of GPCRs, mediates arginine vasopressin control of water reabsorption in the kidney by activating Gs. Requirement of the third intracellular loop of the V2R for G(s) activation was identified by introducing V2R segments into the Gq coupled V1aR [Liu, J. and Wess, J. (1996) J. Biol. Chem. 271, 8772-8778]; the same approach recognized glutamate 231 and glutamine 225 at the amino terminus of loop 3i as being needed for signal transduction. Site-directed mutagenesis of the V2R confirmed their observations. Recently, we found that a positively charged amino acid at codon 268 is essential for V2R expression, although a double-mutant bearing lysine at position 231 and glutamic acid at position 268 was expressed at higher levels than the wild type V2R and displayed unchanged ligand-binding affinity. Ligand-induced internalization and phosphorylation of the double-mutant receptor was indistinguishable from that observed with the wild type protein but signaling activity was greatly diminished. The data suggested these two amino acids might interact with each other and might play a role in promoting GDP/GTP exchange.
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PMID:A role for K268 in V2R folding. 1611 24

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