Charged Residues at the Intracellular Boundary of Transmembrane Helices 2 and 3 Independently Affect Constitutive Activity of Kaposi's Sarcoma-associated Herpesvirus G Protein-coupled Receptor*

Hao H. Ho, Nimalja GaneshalingamDagger , Avia Rosenhouse-DantskerDagger , Roman OsmanDagger , and Marvin C. Gershengorn§

From the Division of Molecular Medicine, Department of Medicine, Weill Medical College and Graduate School of Medical Sciences of Cornell University, New York, New York 10021 and the Dagger  Department of Physiology and Biophysics, Mount Sinai School of Medicine, New York, New York 10029

Received for publication, August 29, 2000, and in revised form, September 29, 2000



    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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Because charged residues at the intracellular ends of transmembrane helix (TMH) 2 and TMH3 of G protein-coupled receptors (GPCRs) affect signaling, we performed mutational analysis of these residues in the constitutively signaling Kaposi's sarcoma-associated herpesvirus GPCR (KSHV-GPCR). KSHV-GPCR contains the amino acid sequence Val-Arg-Tyr rather than the Asp/Glu-Arg-Tyr ((D/E)RY) motif at the intracellular end of TMH3. Mutation of Arg-143 to Ala (R143A) or Gln (R143Q) abolished constitutive signaling whereas R143K exhibited 50% of the basal activity of KSHV-GPCR. R143A was not stimulated by agonist, whereas R143Q was stimulated by growth-related oncogene-alpha , and R143K, similar to KSHV-GPCR, was stimulated further. These findings show that Arg-143 is critical for signal generation in KSHV-GPCR. In other GPCRs, Arg in this position may act as a signaling switch by movement of its sidechain from a hydrophilic pocket in the TMH bundle to a position outside the bundle. In rhodopsin, the Arg of Glu-Arg-Tyr interacts with the adjacent Asp to constrain Arg outside the TMH bundle. V142D was 70% more active than KSHV-GPCR, suggesting that an Arg residue, which is constrained outside the bundle by interacting with Asp-142, leads to a receptor that signals more actively. Because the usually conserved Asp in the middle of TMH2 is not present in KSHV-GPCR, we tested whether Asp-83 at the intracellular end of TMH2 was involved in signaling. D83N and D83A were 110 and 190% more active than KSHV-GPCR, respectively. The double mutant D83A/V142D was 510% more active than KSHV-GPCR. That is, cosubstitutions of Asp-83 by Ala and Val-142 by Asp act synergistically to increase basal signaling. A model of KSHV-GPCR predicts that Arg-143 interacts with residues in the TMH bundle and that the sidechain of Asp-83 does not interact with Arg-143. These data are consistent with the hypothesis that Arg-143 and Asp-83 independently affect the signaling activity of KSHV-GPCR.



    INTRODUCTION
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INTRODUCTION
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Kaposi's sarcoma-associated herpesvirus (KSHV)1 (human herpesvirus 8) is a gamma -herpesvirus that has been implicated in the pathogenesis of several human diseases including Kaposi's sarcoma (KS), primary effusion lymphoma, and a subset of multicentric Castleman's disease (1, 2). A G protein-coupled receptor (KSHV-GPCR) is encoded within the genome of KSHV (3, 4). It has been shown that KSHV-GPCR exhibits constitutive signaling via the phosphoinositide-specific phospholipase C pathway (5). When expressed in mouse fibroblasts, KSHV-GPCR stimulates cell proliferation, causes transformation, and promotes angiogenesis mediated by vascular endothelial growth factor (6). Recently, expression of this viral receptor was shown to induce the formation of angioproliferative lesions in transgenic mice that were similar to the lesions of Kaposi's sarcoma (7). Because persistently activated GPCRs can function as human tumor genes (8), we suggested that the constitutive signaling activity of KSHV-GPCR may play an important role in KSHV-induced tumorigenesis (9). Understanding the details of KSHV-GPCR structure that cause constitutive signaling, therefore, may allow for the design of drugs to treat KS and primary effusion lymphoma.

In a previous report (10), we tested the hypothesis that the amino-terminal extracellular domain of KSHV-GPCR may serve as a "tethered ligand" that constitutively activates the receptor. Although we found that the amino terminus was important for high affinity binding of chemokines, we showed that the amino terminus was not important for constitutive signaling. This observation was recently confirmed (11). Therefore, other domains within KSHV-GPCR are involved in causing the receptor to signal constitutively. Rosenkilde et al. (11) identified residues at the extracellular loop/fifth transmembrane helix (TMH5) and TMH6 boundaries, which when mutated decreased agonist stimulation and residues in TMH2, which when mutated decreased basal signaling. We sought to identify additional domains within KSHV-GPCR that cause the receptor to signal constitutively. In particular, we were interested in discovering mutations that could lead to increased basal signaling so as to use computer models of these receptors to delineate the structural changes that constitute KSHV-GPCR activation.

The highly conserved amino acid sequence, Asp/Glu-Arg-Tyr ((D/E)RY), at the intracellular end of TMH3 of other GPCRs of the rhodopsin family has been shown to be important in receptor activation. It was initially shown that the charged pair of Glu-Arg was needed for rhodopsin activation because double mutants of these residues failed to activate transducin (12). With alpha 1B-adrenergic receptors, mutation of the Arg to some amino acids caused inhibition of stimulated signaling whereas mutation to Lys increased basal signaling, and mutation of Asp to Ala caused a marked increase in basal activity (13, 14). In the receptor for gonadotropin-releasing hormone, which has an Asp-Arg-Ser sequence at the intracellular end of TMH3, mutation of Arg markedly decreased agonist-stimulated activation whereas the Asp to Asn mutation was less active than the wild type (Aspright-arrowAla did not express, Ref. 15). In the CB2 cannabinoid receptor, mutation of Arg to Ala inhibited agonist-stimulated signaling, Asp to Ala abolished signaling, and Tyr to Ala inhibited signaling; there was no apparent effect on basal signaling (16). Mutation of the Arg of the DRY sequence in the oxytocin receptor caused the receptor mutant to be constitutively active (17). With the histamine H2 receptor, which is constitutively active, mutation of Asp caused increased constitutive signaling whereas mutation of Arg caused a decrease in signaling activity (18). The sequence at the putative intracellular end of TMH3 in KSHV-GPCR is Val-Arg-Tyr. It is particularly relevant, therefore, that mutation of the Asp of the DRY sequence in the chemokine receptor CXCR2 (the human receptor most homologous to KSHV-GPCR) to Val caused constitutive activation of this receptor (19).

In this study, we have performed mutational analysis of the residues at the intracellular end of TMH2 and of nonconserved Asp residues in TMH2 and TMH3 in KSHV-GPCR. We have focused primarily on the effects of these residues on constitutive signaling, because it is easier to understand the intramolecular interactions that lead to conformational changes involved in receptor activation in the absence of agonist binding. Arg-143 in KSHV-GPCR was determined to be critical for signaling. Moreover, mutation of Asp-83 caused increased basal signaling, and mutations at these two positions acted synergistically to increase constitutive signaling. A model is presented that predicts these site-specific substitutions act independently to activate KSHV-GPCR.


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Construction of KSHV-GPCR Mutants-- All KSHV-GPCR mutants were constructed by PCR using pcDNA 3.1-KSHV-GPCR as template unless otherwise stated. V142N, R143A, R143K, R143Q, Y144A, and Y144F were constructed using the following oligonucleotides: (a) 5'-TACTTGGATATCTTCAGTGTTGTGTGCGTCAGTCTAAACAGGTACCTCCTGGTGGCATATTCTACG-3'; (b) 5'-TACTTGGATATCTTCAGTGTTGTGTGCGTCAGTCTAGTGGCGTACCTCCTGGTGGCATATTCTACG-3'; (c) 5'-TACTTGGATATCTTCAGTGTTGTGTGCGTCAGTCTAGTGAAGTACCTCCTGGTGGCATATTCTACG-3'; (d) 5'-TACTTGGATATCTTCAGTGTTGTGTGCGTCAGTCTAGTGCAGTACCTCCTGGTGGCATATTCTACG-3'; (e) 5'-TACTTGGATATCTTCAGTGTTGTGTGCGTCAGTCTAGTGAGGGCCCTCCTGGTGGCATATTCTACG-3'; and (f) 5'-TACTTGGATATCTTCAGTGTTGTGTGCGTCAGTCTAGTGAGGTTCCTCCTGGTGGCATATTCTACG-3', respectively, as sense primers, and (g) 5'-CTAGTCTAGAGATCCTCCGGAGAGGCTAGATTAAATTAAGGGGGAAGGGCA-3' as the antisense primer. EcoRV and XbaI restriction sites were used to clone the PCR fragments into pcDNA 3.1-KSHV-GPCR. All the mutants were confirmed by sequencing.

For mutants V142D, D132A, and D132N, the following antisense oligonucleotides were used: (h) 5'-CAGGAGGTACCTGTCTAGACTGACGCACACAACACTGAAGAT-3'; (i) 5'-CAGGAGGTACCTCACTAGACTGACGCACACAACACTGAAGATAGCCAAGTAGACATATAAATAGTA-3'; and (j) 5'-CAGGAGGTACCTCACTAGACTGACGCACACAACACTGAAGATATTCAAGTAGACATATAAATAGTA-3', respectively, and (k) 5'-ATCCG-GCTAGC-AAGCTT-GAATTC-TCCGGA-CCACC-ATGGCGGCCGAGGATTTCCTAACCATCTTCTTA-3' as the sense primer. HindIII and KpnI restriction sites were used to clone the PCR products into pcDNA 3.1-KSHV-GPCR, and the mutants were confirmed by sequencing.

Overlapping PCRs were performed to generate D83A and D83N KSHV-GPCRs. In both constructions the same sense and antisense primers were used: (l) 5'-CAAGTG-GAATTC-TCCGGA-AGATCT-AATATT-GTTAAC-CACC-ATGGCGGCCGAGGATTTCCTAACCATCTTC-3' and (m) 5'-ACTGCTTCTTGGGCCAGGAACGCGTAG-3'. The two overlapping primers were as follows: (n) 5'-CGGGCAGGAGCGATAGCTATACTGCTCCTGGGTATCTGCCTAAAC-3' and (o) 5'-ACCCAGGAGCAGTATAGCTATCGCTCCTGCCCGCGATCGGTGCTT-3' for D83A; and (p) 5'-CGGGCAGGAGCGATAAATATACTGCTCCTGGGTATCTGCCTAAAC-3' and (q) 5'-ACCCAGGAGCAGTATATTTATCGCTCCTGCCCGCGATCGGTGCTT-3' for D83N. EcoRI and EcoRV restriction sites were used to clone the PCR products into pcDNA 3.1-KSHV-GPCR, and the mutants were confirmed by sequencing.

The double mutant D83A/D132A was generated using primer k and i as sense and antisense primer, respectively, using D83A KSHV-GPCR as the template. HindIII and KpnI restriction sites were used to clone the PCR products into pcDNA 3.1-KSHV-GPCR, and the mutants were confirmed by sequencing. D83A/V142D, D83A/R143K, and D83A/R143Q double mutants were constructed through digesting and ligating the respective single mutants using EcoRI and EcoRV restriction sites.

Inositol Phosphate Accumulation-- COS-1 cells were transfected using the DEAE-dextran method (5) with pcDNA 3.1 plasmids encoding the wild-type or mutant KSHV-GPCR. Mock transfectants were cells transfected with plasmid not encoding a receptor. Various amounts of plasmid DNA were used to attain different levels of receptor expression. Transfected cells were re-seeded into 24-well plates 24 h after transfection in Dulbecco's modified Eagle's medium with 5% Nu-Serum (Collaborative Research) and 1 µCi/ml myo-[3H]inositol (PerkinElmer Life Sciences). 48 or 72 h after transfection, the medium was removed, and cells were rinsed with Hank's balanced salt solution (HBSS) containing 10 mM HEPES, pH 7.4 (HHBSS). The cells were then incubated in HHBSS containing 10 mM LiCl in the absence or presence of growth-related oncogene alpha  (Groalpha ), which is a chemokine agonist for KSHV-GPCR (20, 21), for 2 h at 37 °C. Accumulated inositol phosphates (IPs) were measured using ion-exchange chromatography as described (22). IP accumulation was analyzed as [3H]IPs/([3H]lipids + [3H]IPs).

Competition Binding-- Cells were transfected and seeded as described above except that no myo-[3H]inositol was added. 48 h after reseeding, cells were rinsed once with cold HHBSS and then incubated in cold HHBSS supplemented with 0.5% bovine serum albumin and 10 pM 125I-labeled Groalpha (PerkinElmer Life Sciences) in the absence or presence of various concentrations of Groalpha for 4 h at 4 °C. At the end of the incubation, cells were washed twice with 1 ml of cold HHBSS containing 0.5 M NaCl and lysed with 0.5 ml of 0.4 N NaOH. Cell lysates were transferred to glass test tubes and counted in a gamma counter.

Computer Modeling-- Construction of the model of KSHV-GPCR was as follows. The helical boundaries of KSHV-GPCR were determined from a multiple alignment of the sequence of the receptor with those of the nine known chemokine receptors. The conserved residues in TMH1 (Asn-65), TMH3 (Arg-143), TMH5 (Pro-233), and TMH7 (Pro-311) were used to align the sequence with that of rhodopsin. Because TMH2, TMH4, and TMH6 of KSHV-GPCR lacked the usual conserved residues of GPCRs of the rhodopsin family, their boundaries were determined from the alignment with the other chemokine receptors in which the conserved residues are present. The assigned helical segments were superimposed on the Calpha template of the TMH bundle designed by Baldwin et al. (23).

The short loops, i.e. intracellular loops 1, 2, and 3 and extracellular loop 1 were designed as turns such that the distance between the ends of the loops was approximately equal to the distances between the helices that the loops were connecting. Extracellular loop 2 was divided into two segments. The first extracellular loop 2 segment spanned the sequence from the top of TMH4 to Cys-196, which putatively forms a disulfide bridge with Cys-118 at the top of TMH3. The second segment of extracellular loop 2 spanned the sequence from the disulfide bridge to the point the loop connected with TMH5. Each of the segments was designed as a turn. Because extracellular loop 3 is too long to design as a turn, it was constructed by homology to a sequence identified in a known structure of the protein 1EMS (Nit-Fragile Histidine Triad Fusion Protein) with 77% similarity and 41% identity. The loop has a distinct helical segment followed by a turn, and the distance between the ends of the loop agrees well with the distance between TMH6 and TMH7. The loops were connected manually and the entire system was minimized with a distance-dependent dielectric constant. The construction of the receptor was done with Insight and the structure optimizations with CHARMM 26. The chemokine receptor CXCR2 was constructed in a similar way using the aligned sequence from the multiple alignment as above.

Statistical Analysis-- Statistical analyses were performed by analysis of variance.


    RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
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To show that Arg-143 at the intracellular end of TMH3 is involved in signaling in KSHV-GPCR, Arg-143 was mutated to Ala, Gln, or Lys. The three mutant receptors exhibited binding affinities for 125I-labeled Groalpha that were within 2-fold of the affinity of KSHV-GPCR (Figs. 1A and 2B). We measured constitutive signaling activity of these receptors as ligand-independent signaling that is directly related to the level of receptors expressed transiently in COS-1 cells. Fig. 1B illustrates the results from experiments in which the basal production of inositol phosphate second messenger molecules was measured in populations of cells expressing different levels of KSHV-GPCR and mutants of Arg-143. Basal signaling was measured as the slope of the regression line of inositol phosphate production versus receptor level. Mutation of Arg-143 to either Gln or Ala abolished basal signaling (p < 0.001) whereas mutation to Lys created a receptor with 50% of the basal activity of KSHV-GPCR (p < 0.01)(Fig. 2A). Cells expressing R143A exhibited no significant increase in signaling upon addition of Groalpha whereas R143Q was stimulated by 2-fold with Groalpha , and R143K exhibited a response to Groalpha that was similar to KSHV-GPCR (Fig. 1C). These data show that Arg-143 is important for basal and stimulated signaling by KSHV-GPCR.



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Fig. 1.   Effect of mutation of Arg-143 on KSHV-GPCR binding, basal signaling, and Groalpha -stimulated signaling. Human embryonic kidney EM cells were transfected with plasmids encoding KSHV-GPCR, R143K, R143Q, or R143A. After 2 days, 125I-Groalpha binding (A), basal inositol phosphate (IP) production (B) and Groalpha -stimulated IP production (C) were measured as described under "Experimental Procedures." For binding, the points represent the mean ± S.D. of duplicate determinations in two experiments. For basal IP production, the points represent the mean ± S.D. of triplicate determinations in four experiments in which both parameters were measured in the same cell populations. For Groalpha -stimulated IP production, the bars represent the mean ± S.D. of triplicate determinations in a representative experiment.



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Fig. 2.   Comparison of the basal signaling activities and binding affinities of KSHV-GPCRs. The experiments were performed as described in the legend to Fig. 1. A, basal signaling activity is defined as the slope of the line that represents the regression analysis of inositol phosphate production versus 125I-Groalpha binding. The dotted line is basal signaling of KSHV-GPCR. B, equilibrium inhibitory constants (Ki).

We next mutated Tyr-144 to Phe or Ala. Y144F and Y144A exhibited binding affinities for 125I-labeled Groalpha (Fig. 2B), basal signaling activities (Fig. 2A), and Groalpha -stimulated signaling activities (data not shown) that were not different from KSHV-GPCR. Thus, Tyr-144 is not important for KSHV-GPCR binding and signaling.

In contrast to most GPCRs of the rhodopsin family, there is a Val before Arg-Tyr at the intracellular end of TMH3 in KSHV-GPCR. As noted above, mutation of the Asp in the DRY sequence of chemokine receptor CXCR2 to Val caused the receptor to become more constitutively active (19). With mutation of Val-142 to Asn and Asp in KSHV-GPCR, V142N exhibited an affinity that was indistinguishable from KSHV-GPCR, and V142D exhibited binding affinity for 125I-labeled Groalpha that was within 2-fold of KSHV-GPCR (Fig. 2B). V142N exhibited a basal level of signaling that was indistinguishable from KSHV-GPCR (p > 0.1, Fig. 2A). Figs. 2A and 3 illustrate that V142D is more basally active than KSHV-GPCR (p < 0.01). The basal signaling activity of V142D, however, was only minimally stimulated by Groalpha (data not shown). These findings are different from those reported by Rosenkilde et al. (11) who concluded that V142D exhibited the same basal signaling activity as KSHV-GPCR. In their analysis, however, Rosenkilde et al. (11) did not compare basal signaling to receptor expression but compared it instead to the amount of plasmid used in the transfection and assumed that the levels of receptor expression were similar. We have found that several of the more active mutant receptors were expressed at lower levels than KSHV-GPCR. Moreover, these levels varied from experiment to experiment. We, therefore, determined receptor expression in each experiment to measure basal signaling accurately.



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Fig. 3.   Effect of mutation of Val-142 and Asp-83 on basal signaling by KSHV-GPCR. The experiments were performed as described in the legend to Fig. 1. 125I-Groalpha binding and basal inositol phosphate (IP) production are plotted. The points represent the mean ± S.D. of triplicate determinations in two or three experiments in which both parameters were measured in the same cell populations.

Based on data from experiments with other GPCRs, for example, the alpha 1B-adrenerergic receptor (13, 14) and the receptor for oxytocin (17), it has been suggested that the positive side chain of the Arg of the (D/E)RY sequence may interact with a highly conserved Asp residue in the mid-portion of TMH2. There is no Asp in the usual position in TMH2 in KSHV-GPCR, but there is an Asp near the intracellular end of TMH2 at position 83. With mutation of Asp-83 to Ala and Asn, D83A and D83N exhibited affinities for 125I-labeled Groalpha that were indistinguishable from KSHV-GPCR (Fig. 2B). D83N exhibited basal signaling activity that was 110% above KSHV-GPCR (p < 0.001), and D83A exhibited activity that was 190% above KSHV-GPCR (p < 0.001)(Figs. 2A and 4). We next constructed the double mutants D83A/R143K and D83A/R143Q to determine whether these two mutations would interact to affect the phenotype of the doubly mutated receptor. The hypothesis was that if these mutations caused independent effects on basal signaling activity, then the basal activities of the double mutants would be at least the sum of the individual mutations. D83A/R143K and D83A/R143Q exhibited high affinity 125I-labeled Groalpha binding that was similar to KSHV-GPCR (Fig. 2B). D83A/R143K exhibited basal activity that was 70% greater than KSHV-GPCR (p < 0.005), and D83A/R143Q showed activity that was 30% above KSHV-GPCR (p < 0.025, Fig. 2A). These levels of signaling were equal to the addition of the effects of the individual mutations and are consistent with the idea that these substitutions caused effects that were independent of one another.



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Fig. 4.   Effect of mutation of Asp-83 and Asp-132 on basal signaling by KSHV-GPCR. The experiments were performed as described in the legend to Fig. 1. 125I-Groalpha binding and basal inositol phosphate (IP) production are plotted. The points represent the mean ± S.D. of triplicate determinations in two or three experiments in which both parameters were measured in the same cell populations.

Another negatively charged residue that could be part of a putative hydrophilic pocket in the TMH bundle is Asp-132 in TMH3 in KSHV-GPCR. With mutation of Asp-132 to Ala and Asn, D132A exhibited an affinity that was within 2-fold of KSHV-GPCR and D132N exhibited an affinity that was indistinguishable from KSHV-GPCR (Fig. 2B). D132A exhibited activity that was 60% above KSHV-GPCR (p < 0.01), and D132N exhibited basal signaling activity that was similar to KSHV-GPCR (p > 0.1)(Figs. 2A and 4). D132A was not stimulated further by Groalpha whereas D132N was stimulated by Groalpha to the same extent as KSHV-GPCR (data not shown). We constructed the double mutant D83A/D132A that exhibited similar basal signaling activity as D83A (Fig. 2A) and was not stimulated by Groalpha (data not shown). Thus, a negatively charged residue at position 132 was not as important as at position 83 in maintaining the wild-type level of basal activity. Moreover, the lack of additive effects of substituting Ala for Asp-83 and Asp-132 is consistent with the idea that these substitutions affected basal signaling via similar mechanisms (see below).

We next constructed the double mutant D83A/V142D. Although D83A/V142D exhibited the same high affinity for 125I-labeled Groalpha as KSHV-GPCR, the level of D83A/V142D expression was always lower than KSHV-GPCR when the same amounts of plasmid DNA were used for transfection. D83A/V142D exhibited basal signaling activity that was 510% greater than KSHV-GPCR (p < 0.001, Figs. 2A and 4). That is, the effect of having both mutations in the same receptor was synergistic with regard to basal signaling compared with D83A and V142D with individual mutations. This finding is consistent with the idea that these two substitutions act independently to activate the receptor (see below). The signaling activity of D83A/V142D was not further stimulated by Groalpha (data not shown). D83A/V142D was the most active KSHV-GPCR receptor mutant we have found. Because other constitutively active GPCR mutants have been shown to be less stable than native, basally inactive receptors (18, 24), it is possible that the low level of expression of D83A/V142D is caused by its decreased stability.

Lastly, to determine whether these most constitutively active receptors could be inhibited by the three chemokines found to be inverse agonists of KSHV-GPCR (21, 25-27), we measured the effects of interferon gamma -inducible protein-10, stromal-derived factor-1 and viral monocyte inflammatory protein-II. All three chemokines inhibited V142D and D83A to an extent similar to inhibition of KSHV-GPCR but none of them had a consistent effect on basal signaling by D83A/V142D (Fig. 5). We cannot provide an explanation for these differences because the mechanism by which inverse agonists inhibit KSHV-GPCR signaling is not known. It seems, however, that the ability of the inverse agonists to inhibit signaling by these receptors was inversely related to the level of constitutive activity of the receptor. Other KSHV-GPCR mutants have been found to be unresponsive to inverse agonist inhibition but these were receptors with mutations in their amino-terminal domains that caused loss of binding (10, 11).



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Fig. 5.   Effects of interferon gamma -inducible protein-10 (IP10), stromal-derived factor-1 (SDF-1) and viral monocyte inflammatory protein-II (vMIPII) on basal signaling by KSHV-GPCR, V142D, D83A, and D83A/V142D. The experiments were performed as described in the legend to Fig. 1. The inverse agonists were added 5 min before addition of LiCl at a dose of 50 nM. Basal signaling activity is defined as the slope of the line that represents the regression analysis of inositol phosphate production versus 125I-Groalpha binding. The points represent the mean ± S.D. of triplicate determinations in two experiments in which both parameters were measured in the same cell populations. Interferon gamma -inducible protein-10, stromal-derived factor-1, and viral monocyte inflammatory protein-II significantly decreased basal signaling by KSHV-GPCR (p < 0.05), V142D (p < 0.01), and D83A (p < 0.05) but not by D83A/V142D (p > 0.1).

We constructed a computer model of KSHV-GPCR to help explain our findings (Fig. 6). The model predicts that Val-142 and Arg-143 in KSHV-GPCR are at the intracellular end of TMH3. In rhodopsin (28), in which the sequence at the intracellular end of TMH3 is ERY, as well as in our model of CXCR2 (not shown) in which the sequence is DRY, the side chain of Arg-143 interacts with the negatively charged residue proximal to it. In KSHV-GPCR such an interaction is impossible because Val-142 replaces the negatively charged residue. Thus, the side chain of Arg-143 has no partner to stabilize its positive charge.



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Fig. 6.   KSHV-GPCR model showing Arg-143 and Asp-83 at the intracellular ends of transmembrane helix 3 (Hx-3) and 2 (Hx-2), respectively. The structure presented is the minimized model constructed as described under "Experimental Procedures." Hx-1 is included to show the relative orientation of Asp-83 and Arg-143.

Asp-83, which is predicted to be positioned at the intracellular end of TMH2 in KSHV-GPCR, is highly conserved in the chemokine receptor family. In other receptors of the rhodopsin family, this residue is an Asn. An examination of the model of KSHV-GPCR (Fig. 6) shows that this residue is directed inbetween TMH1 and TMH7 and is stabilized by a set of interactions with backbone N-H groups. It is also positioned close to Arg-78 in intracellular loop 1. The position and orientation of Asp-83 place it on the opposite side of TMH2 pointing away from TMH3. Thus, this residue shows no interaction with Arg-143 in TMH3. This is in full agreement with the position of the conserved Asn in TMH2 of rhodopsin as seen in its recent crystal structure (28). The model predicts that Arg-143 and Asp-83 do not interact. As described above, our experimental findings provide functional evidence that these residues do not interact also.

Because basal signaling by KSHV-GPCR is very active (5), we hypothesize that its structure is a model for the active states of GPCRs of the rhodopsin family including agonist-occupied receptors. Study of the structure-function relationship of constitutively active GPCRs (8) has the advantage of elucidating the three-dimensional structure of the active state of the receptor in the absence of a complicating ligand. This approach has been taken in a small number of instances. For example, we showed that models of the three-dimensional structure of constitutively active receptors for thyrotropin-releasing hormone (TRH) predict conformations similar to that of the TRH-occupied receptor (29). Lin et al. (30) predicted from a model of the luteinizing hormone receptor the changes in receptor structure that cause activation and used functional analysis of naturally occurring, constitutively active receptors to support their predictions. We suggest that further structure/function studies of basally active GPCRs will provide important insights into the mechanism of receptor activation.

In the study reported here, we constructed and characterized a number of mutant receptors in which charged residues in TMH2 and TMH3 were substituted to gain insight into the role of these residues in signaling by KSHV-GPCR. As discussed in the Introduction, charged residues within the (D/E)RY sequence at the intracellular end of TMH3 have been shown to play important roles in signaling in a number of GPCRs (12-19). Charged residues in other domains within GPCRs have been shown to be important for signaling also. For example, Perez and coworkers (31, 32) presented evidence that disruption of a salt-bridge between an Asp in TMH3 and a Lys in TMH7 may be involved in alpha 1b-adrenergic receptor activation. Donohue et al. (33) developed support for the idea that a salt-bridge between an Asp at the extracellular loop 1/TMH2 boundary and an Arg at the extracellular loop 3/TMH7 boundary constrained the gastrin-releasing peptide receptor in conformation that is needed for coupling to G proteins. We showed that an Arg residue in TMH6 of the TRH receptor was involved in receptor activation (34). Here we found several different phenotypes with regard to signaling properties of KSHV-GPCR mutants substituted at charged residues even though all the mutant receptors exhibited high binding affinity for Groalpha . D132N exhibited basal and Groalpha -stimulated signaling activity indistinguishable from KSHV-GPCR. R143Q had little basal activity but exhibited-fold stimulation by Groalpha that was similar to KSHV-GPCR whereas R143K had a 50% reduced basal activity but was stimulated by Groalpha to the same level as KSHV-GPCR. In contrast, R143A did not signal basally and could not be stimulated by Groalpha . A number of mutant receptors such as D83A, D83N, and D132A exhibited higher basal activity than KSHV-GPCR but were only minimally stimulated by Groalpha . Thus, some single site-specific substitutions of charged residues led to receptors that were more basally active than KSHV-GPCR. The double mutants D83A/R143K and D83A/R143Q exhibited basal signaling activity that appeared to be equal to the additive effects of the single mutations. That is, these receptors exhibited basal activities that were intermediate between those of D83A and R143K or R143Q. Perhaps the most interesting receptor phenotype was that exhibited by the double mutant D83A/V142D. This mutant had basal signaling activity that was markedly greater than either single mutant D83A or V142D (see below). Mutations in other domains of KSHV-GPCR have previously been shown to generate receptors with different phenotypes including receptors that do not bind ligands with high affinity (10, 11), receptors that exhibit higher basal signaling than KSHV-GPCR but are not stimulated by Groalpha (11) such as D83A, D83N, and D132A, and receptors that exhibit lowered basal activity but could be stimulated by agonist (11), such as R143Q and R143K. Thus, selective mutation of KSHV-GPCR can lead to different phenotypes, similar to what has been reported with other GPCRs.

The phenotype of the double mutant D83A/V142D was unexpected. Before the construction of our model, we believed that Arg-143 and Asp-83 may interact, as has been proposed for the Arg of (D/E)RY and a highly conserved Asp in TMH2 of other GPCRs (13, 15), even though Asp-83 was not in the same position in TMH2 as the highly conserved Asp. Our findings, however, are consistent with the idea that Asp-83 at the intracellular end of TMH2 and Arg-143 at the intracellular end of TMH3 are important for KSHV-GPCR signaling but act independently of one another. We draw this conclusion based in particular on the observation that the double mutant D83A/V142D exhibits a higher level of constitutive signaling than would be expected by the addition of the increased signaling exhibited by the two single mutants D83A and V142D. Indeed, if Arg-143 and Asp-83 interact in KSHV-GPCR, we would expect that the double mutant would exhibit basal signaling activity equal to that of one of the individual mutant receptors. Moreover, our model is consistent with independent effects of substituting these two residues because the model of KSHV-GPCR predicts that the sidechain of Arg-143 resides in a hydrophilic pocket formed by helices 1, 2, and 7 within the TMH bundle and the sidechain of Asp-83 faces outside the bundle in a position on the side of TMH2 away from TMH3 near intracellular loop 1. That is, these two residues are predicted to be in the wrong orientation relative to one another and too far apart to interact. We can speculate on a mechanism to explain this phenotype that is consistent with the predictions of our model and with our data. It is possible that Arg-143 resides in the TMH bundle in a partially activated receptor and that movement out of the bundle caused by agonist stimulation in KSHV-GPCR or by interaction with Asp substituted at position 142 in V142D leads to further activation. This may occur because Arg-143 out of the TMH bundle interacts with residues in intracellular loop 3 to promote higher affinity coupling to G protein. Asp-83 interacts with residues in intracellular loop 1 in a partially activated receptor and upon agonist stimulation in KSHV-GPCR or substitution by Ala in D83A this interaction is lost, and the loss of this constraint allows intracellular loop 1 to couple to G protein more effectively. The synergism occurs because when both of these changes occur in the same receptor, the coupling between receptor and G protein is markedly enhanced. These observations support the concept that a receptor can exist in multiple conformational states along a continuum from completely inactive to fully active (35).

In conclusion, we have found that charged residues, Arg-143 and Asp-83, at the intracellular ends of TMH2 and TMH3, respectively, upon mutation affect signaling by KSHV-GPCR. We suggest that these residues are directly involved in KSHV-GPCR signaling perhaps by mediating changes in receptor conformation or by interacting with the G protein. It is possible, however, that the signaling changes observed upon their mutation may be caused by indirect effects. Arg at this position, which is highly conserved in all GPCRs of the rhodopsin family, has been shown to be important in signaling in all receptors in which the residue has been studied. Asp at this position, which is found in all chemokine receptors but not in most members of the rhodopsin family, has not been studied in mammalian chemokine receptors. Substitutions that we predict affect both of these residues in D83A/V142D lead to a receptor with more than 6 times the basal signaling activity of KSHV-GPCR but which no longer responds to stimulation by agonist or to inhibition by inverse agonist. KSHV-GPCR is thought to be a pirated chemokine receptor that has mutated to serve an important, but unknown function(s) in the viral life cycle. Our findings show that additional mutation of KSHV-GPCR can create a receptor that is more basally active and not regulatable by chemokines. We suggest, therefore, that the phenotype of high basal but chemokine-regulated signaling activity are attributes of KSHV-GPCR that are important to KSHV survival.


    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ To whom correspondence should be addressed: Weill Medical College of Cornell University, 1300 York Ave., Rm. A328, New York, NY 10021. Tel.: 212-746-6275; Fax: 212-746-6289; E-mail: mcgersh@mail.med.cornell.edu.

Published, JBC Papers in Press, October 12, 2000, DOI 10.1074/jbc.M007885200


    ABBREVIATIONS

The abbreviations used are: KSHV, Kaposi's sarcoma-associated herpesvirus; GPCR, G protein-coupled receptor; TMH, transmembrane helix; PCR, polymerase chain reaction; HBSS, Hank's balanced saline solution; HHBSS, HEPES HBSS; Groalpha , growth-related oncogene-alpha ; IP, inositol phosphate.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES


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