Identification of Amino Acid Residues That Direct Differential Ligand Selectivity of Mammalian and Nonmammalian V1a Type Receptors for Arginine Vasopressin and Vasotocin: INSIGHTS INTO MOLECULAR COEVOLUTION OF V1a TYPE RECEPTORS AND THEIR LIGANDS

doi:10.1074/jbc.M408909200

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Identification of Amino Acid Residues That Direct Differential Ligand Selectivity of Mammalian and Nonmammalian V1a Type Receptors for Arginine Vasopressin and Vasotocin

INSIGHTS INTO MOLECULAR COEVOLUTION OF V1a TYPE RECEPTORS AND THEIR LIGANDS^*

Sujata Acharjee ${ddagger}$ , Jean-Luc Do-Rego $§$ , Da Young Oh ${ddagger}$ , Ryun Sup Ahn ${ddagger}$ , Han Choe¶, Hubert Vaudry $§$ , Kyungjin Kim||, Jae Young Seong ${ddagger}$ **, and Hyuk Bang Kwon ${ddagger}$ ${ddagger}$ ${ddagger}$

From the Hormone Research Center, School of Biological Sciences and Technology, Chonnam National University, Gwangju 500-757, Republic of Korea, the European Institute for Peptide Research (IFRMP 23), Laboratory of Cellular and Molecular Neuroendocrinology, INSERM U413, University of Rouen, 76821 Mont-Saint-Aignan, France, the ^¶Department of Physiology, Ulsan University College of Medicine, Songpagoo Poongnapdong 388-1, Seoul 138-736, Republic of Korea, and the ^||School of Biological Sciences, Seoul National University, Seoul 151-742, Republic of Korea

Received for publication, August 4, 2004 , and in revised form, September 8, 2004.

ABSTRACT

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Arginine vasotocin (VT) is the ortholog in all nonmammalianvertebrates of arginine vasopressin (AVP) in mammals. We havepreviously cloned an amphibian V1atype vasotocin receptor (VT1R)that exhibited higher sensitivity for VT than AVP, while themammalian V1a type receptor (V1aR) responded better to AVP thanVT. In the present study, we identified the amino acid residuesthat confer differential ligand selectivity for AVP and VT betweenrat V1aR and bullfrog VT1R (bfVT1R). A chimeric rat V1aR havingtransmembrane domain (TMD) VI to the carboxyl-terminal tail(C-tail) of bfVT1R showed a reverse ligand preference for AVPand VT, whereas a chimeric VT1R with TMD VI to the C-tail ofrat V1aR showed a great increase in sensitivity for AVP. A singlemutation (Ile^315(6.53) to Thr) in TMD VI of V1aR increased thesensitivity for VT, while a single mutation (Phe^313(6.51) toTyr or Pro^334(7.33) to Thr) reduced sensitivity toward AVP.Interestingly the triple mutation (Phe^313(6.51) to Tyr, Ile^6.53to Thr, and Pro^7.33 to Thr) of V1aR increased sensitivity toVT but greatly reduced sensitivity to AVP, behaving like bfVT1R.Further, like V1aR, a double mutant (Tyr^306(6.51) to Phe andThr^327(7.33) to Pro) of bfVT1R showed an increased sensitivityto AVP. These results suggest that Phe/Tyr^6.51, Ile/Thr^6.53,and Pro/Thr^7.33 are responsible for the differential ligandselectivity between rat V1aR and bfVT1R. This information regardingthe molecular interaction of VT/AVP with their receptors mayhave important implications for the development of novel AVPanalogs.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Arginine vasopressin (AVP)^¹ is a cyclic nonapeptide that exertsa variety of biological effects in mammals. The primary roleof AVP involves the regulation of water and solute excretionfrom the kidney (1, 2). The other physiological functions ofAVP include control of blood pressure, platelet aggregation,liver glycogenolysis and neoglucogenesis, adrenocorticotropinrelease from the adenohypophysis, and aldosterone secretionfrom the adrenal gland (3–6). AVP is also implicated ininterneuronal communication in the central nervous system andmodulates several behavioral functions such as feeding, memory,thermoregulation, and the control of adaptive, social, and sexualprocesses (7, 8).

Vasotocin (VT; [Ile³]AVP) is the AVP counterpart in most nonmammalianvertebrates including lungfishes, amphibians, reptiles, andbirds. In amphibians, VT is expressed in both hypothalamic andextrahypothalamic cell bodies (9), indicating that VT acts bothas a neurohormone and neurotransmitter as reported for AVP inmammals. At the periphery, VT regulates osmotic and electrolytebalance (10, 11) and steroid secretion from frog adrenocorticalcells (12, 13). In the central nervous system, VT functionsas a neuromodulator to control reproductive behavior in amphibians(14, 15).

In mammals, the actions of AVP are mediated through three differentAVP receptors: V1aR, V1bR, and V2R (16). All these receptorsubtypes belong to the G protein-coupled receptor superfamilybut differ in their tissue distribution, their relative affinityfor synthetic analogs, and their signaling mechanisms (17, 18).All three types of receptors are expressed in the central nervoussystem (19). However, at the periphery, V1aR is mainly expressedin vascular smooth muscle cells and hepatocytes (20), whereasV1bR is exclusively located in pituitary corticotrophs (21,22), and V2R occurs in the kidney (23). Upon ligand stimulation,V1aR and V1bR trigger the phospholipase C/protein kinase C signalingpathway, while V2R activates the adenylyl cyclase/protein kinaseA pathway (24, 18).

We have recently isolated and characterized a V1aR-type vasotocinreceptor (VT1R) in the frogs Rana catesbeiana and Rana esculenta(25). Frog VT1R exhibits the highest sequence identity (58%)with mammalian V1aR among the AVP receptor subtypes and preferentiallycouples to the phospholipase C/protein kinase C signaling pathwayas does V1aR. Frog VT1R shows a high sensitivity to VT but avery poor sensitivity to AVP. It is of interest to note thatV1aR exhibits relatively high sensitivity to both AVP and VT,although AVP is slightly more potent than VT. Mutational studiescoupled with computational modeling have demonstrated that theVT/AVP binding sites are localized within a narrow cleft delimitedby most of the transmembrane regions, 15 Å deep from theextracellular surface of rat V1aR, and that these binding sitesmay be common to V1bR, V2R, and VTR as these receptors showhigh conservation of residues responsible for ligand binding(26). Several other studies were also performed to investigatethe agonist and antagonist binding sites in V1aR (27–31).However, little is known about the molecular changes of VT1Rto V1aR that lead to the high sensitivity of V1aR to AVP. Inthe present study, using a well defined chimeric receptor approachand site-directed mutagenesis (32, 33), we attempted to determinethe amino acid residues in rat V1aR and bullfrog VT1R (bfVT1R)that account for selective ligand sensitivity to AVP and VT.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Peptides—Synthetic peptides including AVP, oxytocin (OT),VT, mesotocin (MT), the V1 agonist [Phe²,Orn⁸]OT, the V2 agonist[deamino-Cys¹,Val⁴,D-Arg⁸]-AVP, the V1a antagonist [d(CH₂)₅¹,Tyr(Me)²]AVP,the V2 antagonist [d(CH₂)₅¹, D-Ile²,Ile⁴]AVP, and the OT antagonist[d(CH₂)₅¹,Tyr(Me)²,Thr⁴,Orn⁸,des-Gly-NH₂⁹]VT were purchasedfrom Bachem (Bubendorf, Switzerland). The OT agonist [Thr⁴,Gly⁷]OTwas purchased from Sigma.

Plasmids—The pcDNA3 expression vector was purchased fromInvitrogen. The pCMV ${beta}$ -Gal vector was obtained from Clontech.The c-fos-luc vector, containing the -711 $~$ +45 sequence of thehuman c-fos promoter constructed in the pFLASH vector, was akind gift from Dr. R. Prywes, Columbia University. The full-lengthbfVT1R cDNA was cloned into the pcDNA3 expression vector atthe EcoRI and XhoI enzyme sites as mentioned earlier (25). Therat V1aR cDNA was amplified through PCR from rat liver tissueand inserted at the EcoRI and XhoI sites of the pcDNA3.

Constructions of Chimeras and Mutants—For domain swappingbetween bfVT1R and rat V1aR, individual cDNA fragments of interestwere amplified through PCR by using Vent polymerase (New EnglandBiolabs, Beverly, MA) and two specific primers, one correspondingto the 5' or the 3' end of the receptor cDNAs and another correspondingto the region of overlap between the two receptors. The twofragments, one from bfVTR1 and the other from rat V1aR, weresubjected to a second round of PCR to generate the chimericcDNA. All the chimeric constructs were cloned into the pcDNA3expression vector at the EcoRI and XhoI sites. The single anddouble mutants were constructed by PCR-based site-directed mutagenesisand then cloned into pcDNA3. The DNA sequences of the chimerasand mutants were analyzed by the dideoxy chain termination methodusing the DNA Sequencing kit (U.S. Biochemical Corp., Cleveland,OH) to confirm the accuracy of the constructions.

Cell Transfection and Luciferase Assays—CV-1 cells weremaintained in Dulbecco's modified Eagle's medium in the presenceof 10% fetal bovine serum. For luciferase assays, cells wereplated in 24-well plates 1 day before transfection and transfectedwith SuperFect reagent (Qiagen, Chatsworth, CA) according tothe manufacturer's instructions. Approximately 48 h after transfection,cells were treated with the respective ligands for 6 h. Forc-fos promoter-driven luciferase assay, cells were maintainedin serum-free Dulbecco's modified Eagle's medium 16–18h before treatment with the ligand as described previously (32).Cells were harvested 6 h after ligand treatment, and luciferaseactivity in cell extracts was determined using a luciferaseassay system according to the standard method in a Lumat LB9501luminometer (EB & G Berthold, Germany). The luciferase valueswere normalized by the ${beta}$ -galactosidase values. Transfection experimentswere performed in duplicate and repeated at least three times.

Molecular Modeling—The rat V1aR was built by MODELLER6v2 (34) based on the crystal structure of the bovine rhodopsin(35) as a template. AVP was docked into the putative bindingsite of the rat V1aR constrained by previously known interactions.The models for rat V1aR/VT, triple V1aR/AVP mutant, and tripleV1aR/VT mutant were built by mutating corresponding residuesin the rat V1aR/AVP model, and the models went through energyminimization and molecular dynamics annealing simulations inthe MODELLER program. The final geometry was confirmed by PROCHECK(36). The contacts between ligands and receptors were analyzedusing Ligplot (37). The figures of the models were drawn usingVisual Molecular Dynamics (38).

Data Analysis—Data were expressed as mean ± S.E.of three independent experiments. Data analysis was performedusing nonlinear regression, and data were expressed using sigmoiddose-response curves. Agonist or antagonist concentrations inducinghalf-maximal stimulation (EC₅₀) or half-maximal inhibition (IC₅₀)and maximal fold increase (E_max) were calculated using GraphPadPRISM2 software (GraphPad, San Diego, CA). Statistical analysiswas performed by one-way analysis of variance followed by Bonferronitest. Data were considered significant if p < 0.05.

RESULTS

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Fragment of TMDs VI to VII Confers Differential Ligand Selectivity—Differentialligand selectivity of rat V1aR and bfVT1R was examined usinga c-fos promoter-driven luciferase assay (25, 39). Rat V1aRhad higher sensitivity toward AVP than VT as revealed by EC₅₀value (Fig. 1A and Table I). The bfVT1R showed a high sensitivityto VT but very low sensitivity toward AVP (Fig. 1B and Table I).VT differs from AVP by a single amino acid at position 3(Phe for AVP and Ile for VT). Thus, it is likely that some criticalamino acids responsible for interacting with Phe³ of AVP orIle³ of VT are differentially arranged between V1aR and bfVT1R.As an initial step toward identifying selectivity-conferringregions, large segments of TMDs, intracellular loops (ICLs),and extracellular loops (ECLs) were swapped between rat V1aRand bfVT1R, and a series of reciprocal chimeras were constructed(Table I). The first set of chimeric receptors is composed ofthe amino-terminal fragment of bfVT1R in rat V1aR and vice versa(V1aR/VT1R_(N) and VT1R/V1aR_(N)). The second set includes theregion from the amino terminus to half of ICL2 of one receptorfollowed by the sequence of the other receptor (V1aR/VT1R_(N-ICL2)and VT1R/V1aR_(N-ICL2)). The third set contains a substitutionof the TMD VI to the carboxyl-terminal tail (C-tail) of onereceptor with the other (V1aR/VT1R_(TMD6-C) and VT1R/V1aR_(TMD6-C)).The EC₅₀ values of AVP and VT for the different chimeric receptorsare indicated in Table I. Replacement of the amino-terminaldomain of rat V1aR by that of bfVT1R (V1aR/VT1R_(N)) led to adecrease in sensitivity to both AVP and VT. However, no significantchanges in ligand sensitivity were observed in the reciprocalchimera, VT1R/V1aR_(N). The V1aR/VT1R_(N-ICL2) chimera showeda reduced sensitivity to both AVP and VT, while the VT1R/V1aR_(N-ICL2)chimera showed an increased sensitivity to VT. InterestinglyV1aR/VT1R_(TMD6-C) showed a great decrease in sensitivity toAVP but a marked increase in sensitivity to VT, resulting ina reverse ligand selectivity (Table I and Fig. 2A). The oppositeVT1R/V1aR_(TMD6-C) chimera showed a great increase in sensitivityto AVP but a modest increase in sensitivity to VT (Table I andFig. 2B). This result indicates that the residues determiningligand selectivity lie mainly in the sequences between TMDsVI and C-tail.

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FIG. 1.
Ligand selectivity of rat V1aR and bfVT1R. A and B, plasmids containing rat V1aR (A) or bfVT1R (B) cDNA were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP ( ${circ}$ )orVT( ${square}$ ) for 6 h, and luciferase activity was determined.

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TABLE I
AVP and VT selectivities of chimeric receptors The plasmids containing the wild-type and chimeric receptors were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP or VT for 6 h, and luciferase activity was determined.

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FIG. 2.
Comparison of ligand selectivities of chimeric V1aR and VTR. A and B, plasmids containing the V1aR/VT1R_(TMD6-C) (A) or VT1R/V1aR_(TMD6-C) (B) cDNA were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP ( ${circ}$ ) or VT ( ${square}$ ) to the V1aR/VT1R_(TMD6-C) (A) or VT1R/V1aR_(TMD6-C) (B) chimeric receptor for 6 h, and luciferase activity was determined. The dose-response activity was compared with that of the wild type rat V1aR (dashed lines, • for AVP and ${blacksquare}$ for VT). chi, chimera; wt, wild type.

To further dissect the subdomains responsible for the ligandselectivity, three additional bfVT1R chimeras were constructed:VT1R with a fragment from ECL-3 to C-tail of rat V1aR (VT1R/V1aR_(ECL3-C)),VT1R with TMD VII to C-tail of rat V1aR (VT1R/V1aR_(TMD7-C)),and VT1R with the C-tail of rat V1aR (VT1R/V1aR_(C)) (Table II).Compared with VT1R/V1aR_(TMD6-C), VT1R/V1aR_(ECL3-C) exhibiteda lowered sensitivity to AVP. VT1R/V1aR_(TMD7-C) showed a significantlydecreased sensitivity to AVP. Moreover VT1R/V1aR_(C) revealeda marked decrease in sensitivity to AVP such that it had anEC₅₀ value for AVP similar to that of wild type bfVT1R. Theseresults strongly suggest that the fragment between TMD VI toTMD VII is crucial for the ligand selectivity of mammalian andnonmammalian V1a-type receptors to AVP and VT.

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TABLE II
AVP and VT selectivities of VT1R chimeric receptors The plasmids containing the VT1R chimeric receptors were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP or VT for 6 h, and luciferase activity was determined.

Identification of Individual Amino Acids Important for DeterminingLigand Selectivity—To further identify the molecular determinantsunderlying such a differential ligand selectivity, the aminoacid sequences of TMD VI to TMD VII within V1a-type receptorswere analyzed (Fig. 3). As it has been demonstrated previouslythat nonapeptide hormones bind into a cleft 15 Å deepdefined by the upper halves of TMDs (26), these regions wereexamined more carefully. In addition, the sequence of chickenVT1R was also considered as it shows a relatively high sensitivityto AVP among nonmammalian VT1Rs (40).

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FIG. 3.
Amino acid sequence comparison of TMD VI, ECL-3, and TMD VII of V1a-like receptor in mammalian and nonmammalian species. The sequences of TMD VI, ECL-3, and TMD VII of the mammalian V1aR and nonmammalian VT1R have been aligned. The amino acid residues that were mutated in the TMD VI and TMD VII of rat V1aR and bfVT1R are indicated as boxes.

Three individual amino acid residues Phe^313(6.51), Ile^315(6.53),and Pro^334(7.33) in the rat V1aR were chosen and mutated tothose in bfVT1R. Phe^307(6.51) in the hV1aR is known to be importantfor the interaction with antagonists but not agonists (41).However, mutation of Phe^6.51 $->$ Tyr in rat V1aR led to a drasticdecrease in the AVP sensitivity, while the sensitivity for VTremained unchanged (Fig. 4, A and B, and Table III). Mutationof Ile^6.53 to Thr in rat V1aR did not significantly alter sensitivityfor AVP but increased sensitivity for VT (Fig. 4, A and B, andTable III). This mutation increased receptor efficacy for bothVT and AVP (Fig. 4, A and B, and Table III). Interestingly thePro^7.33 $->$ Thr mutation led to a significant decrease in sensitivityto AVP, but this mutation did not alter sensitivity to VT (Fig.4, A and B, and Table III). Based on these results we constructeda triple rat V1aR mutant (F6.51Y/I6.53T/P7.33T) to further explorethe combined effect of these amino acids. This F6.51Y/I6.53T/P7.33Tmutant showed approximately a 1000-fold reduced sensitivityfor AVP, while it had a similar sensitivity for VT comparedwith the wild type receptor (Fig. 4C). This result is consistentwith that obtained with the V1aR/VT1R_(TMD6-C) chimera that showeda drastic decrease (about 1000-fold) in AVP sensitivity.

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FIG. 4.
Ligand selectivities of mutant rat V1aR. A and B, plasmids containing the mutant receptor cDNA were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP (A) or VT (B) to F6.51Y mutant ( ${triangleup}$ ), I6.53T mutant (•), and P7.33T mutant ( ${diamond}$ ) for 6 h, and luciferase activity was determined and compared with the wild type V1aR ( ${circ}$ ). C, cells transfected with the triple rat V1aR (F6.51Y/I6.53T/P7.33T) mutant were treated with graded concentrations of AVP ( ${circ}$ ) and VT ( ${square}$ ). wt, wild type.

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TABLE III
AVP and VT selectivities of mutant V1a and VT1 receptors The plasmids containing the mutant V1a and VT1R receptors were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP or VT for 6 h, and luciferase activity was determined. ND, not determined; wt, wild type.

In bfVT1R, individual reciprocal amino acids, Tyr^306(6.51),Thr^308(6.53), and Thr^327(7.33), were replaced by those of ratV1aR. The Tyr^6.51 $->$ Phe mutation resulted in a slight increasein AVP sensitivity. The Thr^6.53 $->$ Ile mutation led to a significantdecrease in both VT and AVP sensitivity. Interestingly the Thr^7.33 $->$ Pro mutation resulted in a significant increase in sensitivityto AVP (Fig. 5, A and B, and Table III). Three other mutantswere constructed to determine the relative importance of theThr^304(6.49), Asn^320(7.26), and Ile^322(7.28) residues in bfVTR.The Thr^6.49 $->$ Ala mutation led to an impairment of receptor activity(data not shown). The Asn^320(7.26) $->$ Ile and the Ile^322(7.28) $->$ Thr mutations in ECL-3 had no effect in AVP sensitivity (Table III).As we observed increased ligand sensitivity for AVP inthe Y6.51F and T7.33P mutants, we generated the double mutantY6.51F/T7.33P. This double mutant showed a 100-fold increasein AVP sensitivity and a 10-fold increase in VT sensitivity(Fig. 5C). This is also comparable with that of the chimericVT1R/V1a_(TMD6-C) receptor. To examine the effect of Thr^308(6.53)together with the Y6.51F and T7.33P mutations we constructeda triple bfVT1R mutant (Y6.51F/T6.53I/T7.33P). This mutant didnot display significant change in AVP and VT sensitivity comparedwith the double bfVT1R mutant Y6.51F/T7.33P. Taken together,these results suggest that Ile/Thr^6.53 in TMD VI is involvedin VT selectivity, whereas the Phe/Tyr^6.51 in TMD VI and Pro/Thr^7.33in TMD VII are important for the interaction with AVP.

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FIG. 5.
Ligand selectivities of the mutant bfVT1R. A and B, plasmids containing the mutant receptor cDNA were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. Forty-eight hours after transfection, cells were treated with graded concentrations of AVP (A) or VT (B) to Y6.51F mutant ( ${triangleup}$ ), T6.53I mutant (•), and T7.33P mutant ( ${diamond}$ ) for 6 h, and luciferase activity was determined and compared with the wild type bfVT1R ( ${square}$ ). C, cells transfected with the double bfVT1R (Y6.51F/T7.33P) mutant were treated with graded concentration of AVP ( ${circ}$ ) and VT ( ${square}$ ). wt, wild type.

Ligand Sensitivity of Mutant Receptors for Agonists and Antagonists—Tofurther elucidate the role of the Phe/Tyr^6.51, Ile/Thr^6.53,and Pro/Thr^7.33 residues in differential ligand sensitivity,the sensitivity of wild type and mutant receptors for agonistsand antagonists was also examined. First we studied the effectsof the natural ligands OT and MT that act as partial agonistson V1aR and bfVT1R. The triple rat V1aR mutant F6.51Y/I6.53T/P7.33Tshowed reduced sensitivity to OT compared with wild type ratV1aR, but its sensitivity to MT remained unchanged (Fig. 6Aand Table IV). On the other hand, the double bfVT1R mutant Y6.51F/T7.33Pshowed remarkably high sensitivity to OT and relatively highersensitivity to MT compared with wild type bfVT1R (Fig. 6B andTable IV). Next we examined the relative activities of mammalianAVP/OT agonists and antagonists. The V1 agonist [Phe²,Orn⁸]OTand the V2 agonist [deamino-Cys¹,Val⁴,D-Arg⁸]AVP activated wildtype rat V1aR with similar potency, while the OT agonist [Thr⁴,Gly⁷]OTfailed to activate rat V1aR in agreement with our previous result(25). In contrast to rat V1aR, only [Phe²,Orn⁸]OT was potentto activate bfVT1R. Interestingly, like bfVT1R, the triple ratV1aR mutant F6.51Y/6.53T/P7.33T responded only to [Phe²,Orn⁸]OT(Fig. 6C and Table IV). Agonist selectivity of the double bfVT1Rmutant Y6.51F/T7.33P was very similar to that of wild type bfVT1R(Fig. 6D and Table IV).

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FIG. 6.
Comparison of agonist and antagonist binding profiles of triple rat V1aR mutant (A, C, and E) and double bfVT1R (B, D, and F) mutant with the wild type receptors. The effects of natural nonapeptides, nonapeptide agonists, and antagonists on the triple rat V1aR (F6.51Y/I6.53T/P7.33T) mutant (A, C, and E) and the double bfVT1R (Y6.51F/T7.33P) mutant (B, D, and F) were determined. The plasmids containing the triple rat V1aR (F6.51Y/I6.53T/P7.33T) mutant and the double bfVT1R (Y6.51F/T7.33P) mutant cDNA were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. A and B, after 48 h, cells transfected with the triple rat V1aR (F6.51Y/I6.53T/P7.33T) mutant (A) or the double bfVT1R (Y6.51F/T7.33P) mutant cDNA (B) were treated with different concentrations of natural ligand OT ( ${blacksquare}$ ) and MT ( ${blacktriangleup}$ ) for 6 h, and luciferase activity was determined and compared with the respective wild type receptors (OT, ${square}$ ; MT, ${triangleup}$ ). C and D, after 48 h, cells transfected with the triple rat V1aR (F6.51Y/I6.53T/P7.33T) mutant (C) or the double bfVT1R (Y6.51F/T7.33P) mutant cDNA (D) were treated with graded concentrations of V1 agonist [Phe²,Orn⁸]OT ( ${blacktriangleup}$ ), V2 agonist [deamino-Cys¹,Val⁴,D-Arg⁸]-AVP (•), or OT agonist [Thr⁴,Gly⁷]OT ( ${blacksquare}$ ) for 6 h, and luciferase activity was determined and compared with the respective wild type receptors (V1 agonist, ${triangleup}$ ; V2 agonist, ${circ}$ ; and OT agonist, ${square}$ ). E and F, after 48 h, cells transfected with the triple rat V1aR (F6.51Y/I6.53T/P7.33T) mutant (E) or the double bfVT1R (Y6.51F/T7.33P) mutant cDNA (F) were treated with graded concentrations of V1a antagonist [d(CH₂)₅¹,Tyr(Me)²]AVP ( ${blacktriangledown}$ ), V2 antagonist [d(CH₂)₅¹,D-Ile²,Ile⁴]AVP (x), or OT antagonist [d(CH₂)₅¹,Tyr(Me)²,Thr⁴,Orn⁸,des-Gly-NH₂⁹]VT ( ${diamondsuit}$ ) in the presence of 10 nM VT for 6 h, and luciferase activity was determined and compared with the respective wild type receptors (V1a antagonist, ${triangledown}$ ; V2 antagonist, +; and OT antagonist, ${triangleup}$ ). mt, mutant; wt, wild type; anta, antagonist.

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TABLE IV
Agonist and antagonist binding profiles of V1a and VT1 mutant receptors The plasmids containing the triple rat V1aR (F^6.51Y/I^6.53T/P^7.33T) mutant and the double bfVT1R (Y^6.51F/T^7.33P) mutant cDNA were cotransfected with the c-fos-luc reporter vector into CV-1 cells along with ${beta}$ -galactosidase as an internal control. After forty-eight hours, cells transfected with the triple rat V1aR (F^6.51Y/I^6.53T/P^7.33T) mutant or the double bfVT1R (Y^6.51F/T^7.33P) mutant cDNA were treated with different concentrations of natural ligand, agonists, and antagonists for 6 h, and luciferase activity was determined and compared with the respective wild type receptors. Antagonists were treated in the presence of 10 nM VT. ND, not determined; wt, wild type.

The V1a antagonist [d(CH₂)₅¹,Tyr(Me)²]AVP selectively suppressedAVP-induced rat V1aR activity, while the V2 antagonist [d(CH₂)₅¹,D-Ile²,Ile⁴]AVPand the OT antagonist [d(CH₂)₅¹,Tyr(Me)²,Thr⁴,Orn⁸,des-Gly-NH₂⁹]VTfailed to inhibit the V1aR activity. All three antagonists failedto inhibit VT-induced wild type VT1R activity. Interestinglythe V1a and OT antagonists partially suppressed VT-induced triplerat V1aR mutant (F6.51Y/I6.53T/P7.33T) activity (Fig. 6E andTable IV). For the double bfVT1R mutant (Y6.51F/T7.33P), only[d(CH₂)₅¹,Tyr(Me)²]AVP could partially suppress the receptoractivity (Fig. 6F and Table IV).

Molecular Modeling—We constructed three-dimensional modelsof wild type rat V1aR (Fig. 7, A and C) and triple rat V1aRmutant (F6.51Y/I6.53T/P7.33T) (Fig. 7, B and D) based on thecrystal structure of the bovine rhodopsin and docked with AVPand VT. TMDs I to V are shown by gray cylinders, whereas TMDVI and VII are represented by yellow ribbons. The side chainsof residues Phe^6.51, Ile^6.53, and Pro^7.33 of the receptor andthe third amino acid residue of AVP or VT are shown as balland stick models in the following colors: carbon atoms in cyan,oxygen atoms in red, nitrogen atoms in blue, and sulfur atomsin yellow. Our model showed essential interactions that havebeen suggested previously (26–28). Tyr² of AVP was foundto have hydrophobic interactions with the Trp^310(6.48) and Phe^313(6.51)residues located in TMD VI of wild type rat V1aR as describedpreviously (26). It has been suggested that the Arg⁸ residueof VT/AVP may interact with the Tyr^115(2.68) residue in ECL1of human V1aR (27). In rat V1aR, Tyr^2.68 has been replaced bySer. Our model depicts that Arg⁸ forms a hydrophobic interactionwith Ser^2.68 (data not shown). In addition, the carboxyl-terminaltripeptide Pro⁷-Arg⁸-Gly⁹ interacts with the patch of Leu^42(1.23)to Arg^46(1.27), which is a key determinant in AVP binding (28).As AVP and VT differ by a single amino acid at position 3, Phe³of AVP or Ile³ of VT are likely responsible for differentialligand selectivity. In this model, Phe³ of AVP was found tohave a close contact with Phe^6.51, Phe^6.52, and Gln^6.55 locatedin TMD VI (Fig. 7A). In the triple V1aR mutant (F6.51Y/I6.53T/P7.33T),mutation of Phe^6.51 to Tyr led to a loss of interaction withPhe³ of AVP (Fig. 7C). The amino acids in rat V1aR interactingwith VT were essentially the same as those interacting withAVP except for Ile³ of VT that was found to form hydrophobicinteractions with Val^219(5.39) in TMD V and Ile^6.53 and Gln^6.55in TMD VI (Fig. 7B). However, replacement of Ile^6.53 with Thrin the triple rat V1aR mutant led to loss of interaction withIle^6.53. Ile³ moved downward and had a hydrophobic interactionwith Phe^6.52 that is placed between Phe^6.51 and Thr^6.53 (Fig.7D).

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FIG. 7.
Molecular models for the interaction of AVP with wild type rat V1aR (A), VT with wild type rat V1aR (B), AVP with the triple rat V1aR (Y6.51F/T6.53I/T7.33P) mutant (C), and VT with the triple rat V1aR mutant (D). The ligands AVP/VT are drawn as tubes in green. The secondary structures of the V1aR from amino terminus to TMD V are drawn as cartoon diagrams in gray. TMD VI to carboxyl terminus is represented as ribbon diagrams in yellow. The side chains of important amino acids of the ligand (Phe/Ile³) and the V1aR (Phe/Tyr^313(6.51), Ile/Thr^315(6.53), and Pro/Thr^334(7.33)) are shown as ball and stick models in the following colors: carbon atoms in cyan, oxygen atoms in red, nitrogen atoms in blue, and sulfur atoms in yellow. Disulfide bonds between Cys¹²⁴ and Cys²⁰⁵ of the receptor and Cys¹ and Cys⁶ of the ligand are shown in the model.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

The present study has demonstrated that replacement of threeamino acids (Phe^6.51, Ile^6.53, and Pro^7.33) in rat V1aR withthose found in bfVT1R leads to an altered AVP/VT selectivity.Reciprocally substitution of the equivalent residues in bfVT1Rby those of rat V1aR (Y6.51F/T7.33P) provoked a remarkable increasein AVP sensitivity. As AVP and VT differ from each other bya single amino acid at position 3 (Phe for AVP and Ile for VT),the Phe³ residue of AVP is proposed to directly or indirectlyinteract with Phe^6.51 and Pro^7.33. Thus, it can be postulatedthat Phe^6.51 of rat V1aR interacts with Phe³ of AVP probablythrough an aromatic-aromatic interaction (42). It is of interestto note that the Phe^6.51 residue is also highly conserved inthe receptors for biogenic amines and that it plays a key rolein interaction with the catechol ring of the ligand (43). Indeedour modeling study indicates that the Phe³ residue of AVP isinvolved in hydrophobic interaction with Phe^6.51 of wild typeV1aR, while the Ile³ residue of VT forms a hydrophobic interactionwith Ile^6.53. It has been reported previously that mutationof Phe^6.51 to a non-aromatic amino acid (Leu or Val) in humanV1aR does not significantly affect the agonist binding affinity(41). However, the mutation of Phe^6.51 to Tyr in rat V1aR causesa substantial decrease in AVP sensitivity. Thus, the polar natureof the Tyr residue may interfere with the interaction with AVP.Since AVP has a constrained conformation due to the presenceof a disulfide bond between Cys¹ and Cys⁶, it is possible thatthe presence of Tyr at position 6.51 might perturb the optimalpositioning of AVP in the binding pocket. In the triple V1aRmutant, substitution of Phe^6.51 with Tyr would lead to a lossin the interaction with Phe³ of AVP, which may weaken ligandreceptor interaction. On the other hand, mutating Ile^6.53 toThr places Phe^6.52 ahead in the ligand binding crevice, resultingin a potent hydrophobic interaction between Phe^6.52 and Ile³of VT.

Pro^7.33 seems to facilitate a favorable conformation for AVPdocking as the mutation of Tyr^6.51 to Phe alone in bfVT1R wasnot sufficient to increase AVP sensitivity. A double bfVT1Rmutant where Tyr^6.51 and Thr^7.33 were mutated to Phe and Pro,respectively, displayed a marked increase in AVP sensitivity.This suggests that the Pro kink in TMD VII alters the apparentposition of TMD VI in the binding pocket, thereby exposing Phe^6.51in the ligand binding pocket, which becomes more accessiblefor AVP. It has been demonstrated that activation of rhodopsinresults in a rigid body movement of TMDs III and VI (44). Themotion of TMD VI is also a feature of the ${beta}$ ₂-adrenergic receptor(45). Thus, it can be postulated that TMD VI of V1aR undergoesdisplacement following AVP binding, which is affected in theabsence of the Pro kink. Such a conformation is also favoredby the other natural nonapeptides like VT, OT, and MT as shownby the increased sensitivities of VT, OT, and MT for the bfVT1Rdouble mutant Y6.51F/T7.33P.

In the other nonmammalian V1a-type receptors that also showreduced sensitivity for AVP, Phe^6.51 is highly conserved, althoughthese receptors lack Pro in TMD VII that is otherwise well conservedin the mammalian V1aR. The mammalian V1b, V2, and OT receptorsalso contain a conserved Pro residue either in ECL3 or TMD VII.Phe^6.51 is highly conserved in all members of the AVP/OT receptorfamily. Chicken VT1R shows higher sensitivity for AVP than thefrog VT1R and fish VT1R that contain a Pro residue in ECL3.These observations also provide evidence that the AVP bindingpocket is common in all other members of the AVP/OT receptorfamily. While Phe^6.51 and Pro^7.33 are important for the AVPselectivity of rat V1aR, Ile^6.53 appears to be involved in theselectivity of VT as the mutation of rat V1aR (Ile^6.53 to Thr)increased the sensitivity to VT, while a single mutation ofbfVT1R (Thr^6.53 to Ile) decreased VT sensitivity. It is noteworthythat, compared with the double mutant (Y6.51F/T7.33P), sucha decrease in VT sensitivity was not observed in the triplebfVT1R mutant Y6.51F/T6.53I/T7.33P, indicating that the increasein VT sensitivity by the Y6.51F and T7.33P mutations may compromisethe effect of Thr^6.53 to Ile mutation.

The molecular interaction of ligand and receptor was furtherexamined using AVP/OT agonists and antagonists. The triple ratV1aR mutant F6.51Y/I6.53T/P7.33T and the double bfVT1R mutantY6.51F/T7.33P displayed an altered agonist and antagonist sensitivitycompared with the wild type receptors. The triple rat V1aR mutantF6.51Y/6.53T/P7.33T was completely non-responsive to [deamino-Cys¹,Val⁴,D-Arg⁸]-AVP,although wild type V1aR was activated by [deamino-Cys¹,Val⁴,D-Arg⁸]-AVP (Table IV and Fig. 6C). [d(CH₂)₅¹,Tyr(Me)]AVP wasless potent in suppressing the triple rat V1aR mutant F6.51Y/6.53T/P7.33Tactivity than wild type V1aR, while [d(CH₂)₅¹,Tyr(Me)²,Thr⁴,Orn⁸,des-Gly-NH₂⁹]VTwas more potent in suppressing the activity of the mutant receptor(Table IV and Fig. 6, E and F). [d(CH₂)₅¹,Tyr(Me)²]AVP slightlyreduced the activity of the double bfVT1R mutant Y6.51F/T7.33P,while it failed to suppress the activity of wild type VT1R.It may be due to the fact that [deamino-Cys¹,Val⁴,D-Arg⁸]-AVPand [d(CH₂)₅¹,Tyr(Me)²]AVP possess Phe³. Phe^6.51, a potentialinteraction site with Phe³ of [deamino-Cys¹,Val⁴,D-Arg⁸]-AVPwas abolished in the rat V1aR mutant. The failure of [deamino-Cys¹,Val⁴,D-Arg⁸]-AVPto activate the double VT1R mutant Y6.51F/T7.33P, despite havingPhe^6.51 and Pro^7.33, might be due to the fact that the otherresidues necessary for interacting with [deamino-Cys¹,Val⁴,D-Arg⁸]-AVPare absent in bfVT1R. [d(CH₂)₅¹,Tyr(Me)²]AVP is structurallyvery similar to AVP except for the first and second residues.Thus, it appears that the Phe³ residue of [d(CH₂)₅¹,Tyr(Me)²]AVPis likely to interact with Phe^6.51 of rat V1aR and that theabsence of Phe^6.51 in the mutant led to a decrease in the potencyof the antagonist in suppressing the mutant receptor activity.Conversely the presence of a Phe residue in place of Tyr^6.51in the double bfVT1R mutant favors [d(CH₂)₅¹,Tyr(Me)²]AVP binding,which therefore suppresses the mutant receptor activity morepotently than the wild type. These results suggest that differentagonists select different spectra of conformations and thatdifferent agonists produce different receptor active states(46–48).

The present study also provides some clues toward receptor-ligandcoevolution of the AVP/OT family. Thus, our results indicatethat the evolution of the V1a-like receptor might have precededthat of the ligands as the AVP sensitivity is higher in birds(35) than in amphibians (this study). During evolution, V1aRacquired an ability to respond to AVP with a high sensitivity.Change of VT to AVP is also important not only for achievinga high potency to V1aR but also for lesser potency to the OTreceptor. It is of interest to note that mammalian OT receptorsexhibit a relatively high sensitivity toward VT but low sensitivityto AVP (25). Thus, the change in the peptide sequence from VTto AVP allows circumventing the interference of AVP with OTactivity such as milk ejection or uterine contraction in mammals.It should also be considered that the double bfVT1R mutant Y6.51F/T7.33Pexhibited a better sensitivity to OT than the wild type, whilethe triple rat V1aR mutant F6.51Y/I6.53T/P7.33T showed reducedsensitivity to OT compared with the wild type. This findingindicates that evolutionary changes in amino acids at positions6.51, 6.53, and 7.33 did not contribute to lesser OT selectivityof V1aR.

In conclusion, we have identified three amino acid residues(Phe/Tyr^6.51, Ile/Thr^6.53, and Pro/Thr^7.33) in the rat V1aRand bfVT1R that may be critical for ligand selectivity for AVPand VT. This study provides important information on the molecularinteraction of VT/AVP with their receptors, which should proveuseful for the development of novel AVP analogs. Further thisstudy provides a clue to understanding the molecular coevolutionof AVP/OT-related peptides and their receptor family.

FOOTNOTES

^* This work was supported by Korea Research Foundation Grant No.KRF-2002-070-C007 (to H. B. K.), by Brain Research Center ofthe 21st Century Frontier Research Program Grant M103KV01000403K2201 00410 (to J. Y. S.), and by the Science and TechnologyAmicable Research exchange program (to H. B. K., J. Y. S., andH. V.). The costs of publication of this article were defrayedin part by the payment of page charges. This article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate this fact.

^** To whom correspondence may be addressed. Tel.: 82-62-530-1399; Fax: 82-62-530-0500; E-mail: jyseong{at}jnu.ac.kr. ${ddagger}$ ${ddagger}$ To whom correspondence may be addressed. Tel.: 82-62--530-3391; Fax: 82-62-530-0500; E-mail: kwonhb{at}jnu.ac.kr.

¹ The abbreviations used are: AVP, arginine vasopressin; VT, vasotocin;OT, oxytocin; MT, mesotocin; bfVT1R, bullfrog vasotocin receptortype-1; V1aR, rat arginine vasopressin receptor 1a subtype;TMD, transmembrane domain; ICL, intracellular loop; ECL, extracellularloop; C-tail, carboxyl-terminal tail.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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