Stalk-dependent and Stalk-independent Signaling by the Adhesion G Protein-coupled Receptors GPR56 (ADGRG1) and BAI1 (ADGRB1)*

The adhesion G protein-coupled receptors (aGPCRs) are a large yet poorly understood family of seven-transmembrane proteins. A defining characteristic of the aGPCR family is the conserved GAIN domain, which has autoproteolytic activity and can cleave the receptors near the first transmembrane domain. Several aGPCRs, including ADGRB1 (BAI1 or B1) and ADGRG1 (GPR56 or G1), have been found to exhibit significantly increased constitutive activity when truncated to mimic GAIN domain cleavage (ΔNT). Recent reports have suggested that the new N-terminal stalk, which is revealed by GAIN domain cleavage, can directly activate aGPCRs as a tethered agonist. We tested this hypothesis in studies on two distinct aGPCRs, B1 and G1, by engineering mutant receptors lacking the entire NT including the stalk (B1- and G1-SL, with “SL” indicating “stalkless”). These receptors were evaluated in a battery of signaling assays and compared with full-length wild-type and cleavage-mimicking (ΔNT) forms of the two receptors. We found that B1-SL, in multiple assays, exhibited robust signaling activity, suggesting that the membrane-proximal stalk region is not necessary for its activation. For G1, however, the results were mixed, with the SL mutant exhibiting robust activity in several signaling assays (including TGFα shedding, activation of NFAT luciferase, and β-arrestin recruitment) but reduced activity relative to ΔNT in a distinct assay (activation of SRF luciferase). These data support a model in which the activation of certain pathways downstream of aGPCRs is stalk-dependent, whereas signaling to other pathways is stalk-independent.

Despite their essential roles, the aGPCRs are poorly understood, with most members still considered orphan receptors with no known ligands. These receptors are characterized by large, multi-domain N termini that mediate cell-to-cell and cell-to-extracellular matrix interactions. Nearly all aGPCRs have an N-terminal juxtamembrane GPCR Autoproteolysis-Inducing (GAIN) domain, which can cleave the receptor into two non-covalently associated protomers (4). N-terminal cleavage is thought to be a critical activation step because a number of groups have reported that aGPCR truncated mutants that mimic post-cleavage receptors exhibit enhanced constitutive activity; these include BAI1/ADGRB1 (5), BAI2/ ADGRB2 (6), GPR133/ADGRD1 (7), CD97/ADGRE5 (8), GPR110/ADGRF1 (9), GPR56/ADGRG1 (9, 10), GPR64/ ADGRG2 (11,12), GPR126/ADGRG6 (13) and VLGR1/ ADGRV1 (14). These data prompted the proposal of a disinhibition model of aGPCR activation. In this model, the N-terminal fragment (NTF) inhibits the constitutive signaling ability of the 7TM protomer (also known as the C-terminal fragment or CTF) until the NTF is engaged by a large extracellular ligand, which results in a conformational change and/or removal of the NTF to relieve inhibition and unleash maximal receptor activity (15).
The disinhibition model is a general model that leaves open the mechanistic question of precisely how aGPCR NTF regions inhibit receptor signaling. At least two more mechanistically specific models have been discussed, one in which the NTF acts as a tethered antagonist to suppress signaling by the CTF and another model in which the NTF lacks antagonist activity per se but instead masks a cryptic agonist that becomes unveiled upon cleavage and removal of the NTF (Fig. 1) (2). Several recent reports have provided evidence in support of the cryptic agonist model (7,9,11). Liebscher and colleagues found that peptides mimicking the remaining post-cleavage NT stalk (also known as the "stachel") can activate GPR126/ADGRG6, GPR133/ ADGRD1 and GPR64/ADGRG2 (7,11). Similarly, Stoveken et al. demonstrated that GPR110/ADGRF1 and GPR56/ADGRG1 can also be activated by stalk-mimetic peptides (9). These findings have raised the question of whether signaling by all aGPCRs is dependent upon agonistic sequences in the receptor N-terminal stalk regions.
In the studies described here, we performed a series of tests of the cryptic agonist model for two distinct aGPCRs: GPR56/ ADGRG1, hereafter referred to as "G1," and BAI1/ADGRB1, hereafter referred to as "B1." G1 is one of the most intensivelystudied aGPCRs because mutations in this receptor cause a brain developmental disorder in humans (16). B1 is also a receptor of great physiological interest because it has been shown to play a critical role in regulating macrophage phagocytosis (17), muscle development (18) and synaptic plasticity in the brain (19 -21).
To explore the importance of the stalk regions of these two aGPCRs for receptor signaling, we took two approaches. First, since the cryptic agonist model is largely dependent on GAIN domain cleavage, we engineered a cleavage-deficient form of G1 by mutating the catalytic threonine (Thr-383) to alanine, and additionally assessed signaling by full-length B1, which is naturally cleavage-deficient in HEK cells (4). Second, we created mutant forms of G1 and B1 that lack almost the entire NT, including the stalk region. According to the cryptic agonist model, these deletions should render the receptors completely inactive due to a lack of the tethered agonist that is necessary for receptor activation. Since most if not all GPCRs can couple to multiple downstream pathways that may be differentially activated by distinct receptor active conformations (22), the signaling activities of the G1 and B1 stalkless mutants were assessed in a battery of different assays to provide a panoramic view of the importance of the stalk regions for receptor signaling.
FLAG-␤arrestin2 was purchased from Addgene, the RGS domain of p115RhoGEF (RGSp115) was a gift from Tohru Kozasa (Univ. of Illinois Chicago), and HA-ubiquitin was kindly provided by Keqiang Ye (Emory University). These constructs have been described previously (5). Internal EE-tagged G␣ 13 was acquired from the cDNA Resource Center (cdna.org).
Western Blot-Protein samples were reduced and denatured in Laemmli buffer, loaded into 4 -20% Tris-Glycine gels (Bio-Rad) for SDS-PAGE, and then transferred to nitrocellulose membranes (Bio-Rad). Blots were blocked with 5% milk (in 50 mM NaCl, 10 mM HEPES, pH 7.3 with 1% Tween-20 (Sigma)) and incubated with primary antibodies for 1 h at room temperature or overnight at 4°C. The B1 C-terminal antibody was a gift from Dr. Erwin Van Meir and has been described previously (5). The anti-GPR56 C-terminal antibody was developed by Orbigen, Inc. via injection of rabbits with a peptide (CSNSD-SARLPISSGSTSSSRI) derived from the GPR56 C terminus, and has been characterized previously (10). The biotinylated anti-GPR56 N-terminal antibody was purchased from R&D Systems. Rat anti-HA (Roche), mouse HRP-conjugated anti-FLAG (Sigma), and mouse anti-Glu Glu (Abcam) antibodies were used to detect epitope-tagged proteins. HRP-conjugated secondary antibodies were purchased from GE Healthcare and antibody labeling of specific bands was visualized using Thermo Scientific SuperSignal West solutions.
Cell Surface Biotinylation-HEK-293T cells were transfected with 2 g of DNA (empty vector or receptor). At 24-h posttransfection, cells were placed on ice and washed with ice-cold PBSϩCa 2ϩ three times. Cells were then incubated with 10 mM Sulfo-NHS-Biotin (Thermo Scientific) in PBSϩCa 2ϩ on ice for 30 min and then washed three more times with PBSϩCa 2ϩ ϩ 100 mM glycine. Cells were resuspended in 250 l of lysis buffer (1% Triton X-100, 25 mM HEPES, 150 mM NaCl, 10 mM MgCl 2 , 1 mM EDTA, protease inhibitor mixture (Roche Diagnostics), and 2% glycerol) and lysed by slowly rotating on a spinning wheel for 30 min at 4°C. Cell debris was cleared by centrifugation, and soluble cell lysates were incubated with 50 l of streptavidin agarose beads (Thermo Scientific) for 1 h at 4°C. Beads were washed three times with lysis buffer and resuspended in 60 l of Laemmli buffer. Biotinylated proteins were detected via Western blot, as described above.
␤-Arrestin Binding Assay-HEK-293T cells were transfected with a total of 6 g of DNA (empty vector, receptor, FLAG-␤Arr2 or HA-␤Arr2). The next day, cells were washed with cold PBSϩCa 2ϩ and lysed in harvest buffer (150 mM NaCl, 25 mM HEPES pH 7.3, 1 mM EDTA, 10 mM MgCl 2 , 1% Triton X-100, Roche EDTA-free complete protease inhibitor mixture tablet). Lysates were rotated at 4°C for 45 min to solubilize integral membrane proteins and membranes were cleared by centrifugation (15 min at 17,000 ϫ g, 4°C). Solubilizates were added to magnetic anti-FLAG beads (Sigma) or anti-HA agarose beads (Sigma) and rotated at 4°C for 1 h. Beads were A, according to this model, the unstimulated receptor is inactive due to the masking of an agonistic region of the stalk by the NTF. B, following ligand binding to the NTF, the NTF is released from the seven-transmembrane CTF to unveil a new N-terminal stalk, which then stimulates G protein-dependent signaling activity.
washed 3ϫ in harvest buffer and proteins were eluted in Laemmli buffer at 37°C for 10 -15 min and loaded in 4 -20% Tris-glycine gels for SDS-PAGE and Western blotting. Western blot bands were quantified using Image Studio software (Licor, Lincoln, NE). For purposes of quantification, results from experiments using alternate B1⌬NT (929 -1584) and B1-SL (941-1584) constructs were pooled as the results were indistinguishable.
G Protein Co-immunoprecipitation-HEK-293T cells were transfected with 1 g of EE-tagged G␣ 13 and 1-4 g of receptor DNA). EE-tagged G proteins were immunoprecipitated with anti-EE antibody (1:200, Abcam) and protein A/G beads (Thermo) as described above. Beads were washed 3ϫ, and proteins were eluted in 2ϫ Laemmli buffer.
Ubiquitination Assays-HEK-293T cells were plated and transfected as described above with 3 g of receptor and 1 g of HA-ubiquitin DNA. Four hours after transfection, cells were treated with 100 nM MG-132 (Tocris) to inhibit the proteasome overnight. The following day, cells were washed and harvested as described above. Cleared lysates were incubated with anti-HA agarose beads (Sigma) for 1 h, washed, and eluted in Laemmli buffer.
Luciferase Reporter Assays-HEK-293T cells were seeded in 96-well plates 20 -24 h prior to transfection. Each well was transfected with 50 ng of firefly reporter, 1 ng of Renilla luciferase, and 10 ng of receptor or mock DNA. All reporter constructs (NFAT: pGL4.30, SRF: pGL4.34, Renilla pRLSV40) were acquired from Promega (Madison, WI). 24 -48 h later Dual-Glo luciferase assays (Promega) were performed according to the manufacturer's protocol and plates were read on either a Biotek Synergy 3 or BMG Omega plate reader. Results were calculated for each assay by determining the luminescence ratio of firefly:Renilla luciferase counts, normalized to empty vector (EV) transfected wells. Error bars for all EV-transfected condi-tions were represented as the standard errors of the normalized raw value means.
AP-TGF␣-shedding Assays-HEK-293T cells were seeded in 96-well plates 20 -24 h prior to transfection. Each well was transfected with 50 ng of AP-TGF␣ plasmid (kindly provided by Shigeki Higashiyama, Ehime University) and 10 ng of receptor or mock DNA. Twenty-four hours later, the plate was incubated with p-nitrophenyl phosphate (New England BioLabs) and read on either a Biotek Synergy 3 or BMG Omega plate reader as per the protocol described by Inoue et al. (23).

Cleavage-deficient Receptors Retain Signaling Activity-To
test the cryptic agonist model of aGPCR activation, we performed parallel studies on two distinct aGPCRs: GPR56/ ADGRG1 ("G1") and BAI1/ADGRB1 ("B1"). According to the cryptic agonist model, signaling activity depends upon efficient GAIN domain cleavage followed by dissociation of the N-terminal fragment (NTF) to unveil the agonistic peptide found on the remaining N-terminal stalk of the 7TM protomer (the C-terminal fragment or CTF). Thus, we tested whether GAIN domain cleavage was indeed necessary for G1 and B1 basal constitutive activity.
As G1 is efficiently cleaved in transfected HEK-293T cells (10), we introduced a point mutation to the G1 GAIN domain at the site of cleavage (T383A) to create a cleavage-deficient version of the receptor ( Fig. 2A). Human G1 mutations (C346S and W349S) that abrogate GAIN domain cleavage have been shown to result in the devastating neurological condition bilateral frontoparietal polymicrogyria, which led to speculation that autoproteolysis may be necessary for proper aGPCR function (24,25). However, more recent crystallographic studies provided insights as to how GAIN domain cleavage can be abro- gated without inducing misfolding of the GAIN domain (4). Using a cell surface biotinylation approach, we found that indeed G1-T383A (T383A) traffics to the plasma membrane, albeit at a somewhat reduced level compared with the wild-type receptor (Fig. 2B). To validate whether T383A is indeed cleavage-deficient, we probed for expression of the mutant receptor in Western blots using both CT-and NT-specific antibodies (Fig. 2C). The left panel of Fig. 2C displays the expression patterns of the wild-type and T383A receptors using a C-terminal specific antibody. For wild-type G1, there is a prominent band at ϳ45 kDa which represents the monomeric, cleaved 7TM protomer. As expected, the T383A mutant lacks the ϳ45 kDa band and instead displays a prominent band at ϳ75 kDa which is the predicted molecular weight of full-length, uncleaved G1. Higher order bands for either the wild-type or T383A receptors are likely to be unresolved, oligomeric complexes. The righthand panel of Fig. 2C displays the expression patterns of both receptors as detected by an N-terminal specific antibody. Here bands are found at ϳ70 kDa and ϳ75 kDa for the wild-type receptor and T383A, respectively. The ϳ75 kDa band of T383A is both C-terminally and N-terminally reactive, providing strong evidence that the point mutation does indeed abrogate cleavage to result in a single, uncleaved protein.
We next assessed the basal constitutive activity of the T383A mutant using two distinct downstream readouts: TGF␣ shedding and activation of SRF luciferase. G1 has previously been reported to couple to G␣ 12/13 (9,10,26), and GPCRs that activate G␣ q -or G␣ 12/13 -mediated pathways stimulate the ectodomain shedding of TGF␣ from the plasma membrane, with the amount of TGF␣ released into the conditioned media serving as a proxy for receptor activity (23). We observed that wild-type G1 and the T383A mutant displayed an equal level of activity in the TGF␣ shedding assay (Fig. 2D). Next, we compared the activities of wild-type G1 and T383A in a serum response factor (SRF)-luciferase reporter assay, another well-described readout for G␣ 12/13 -coupled receptors that has previously been shown to be activated by G1 (27). In agreement with our TGF␣ shedding data, the T383A mutant mediated an approximately equal level of signaling activity to wild-type G1 in the SRF-luciferase assay (Fig. 2E). Regarding B1, this receptor is not efficiently cleaved in HEK-293T cells, as evidenced by Ͼ99% of the protein consistently appearing between 150 -250 kDa in Western blots (5). Nonetheless, full-length, uncleaved B1 exhibits substantial constitutive G protein-dependent signaling activity, as shown in previously published studies (5) and also shown below. Taken together, these data provide evidence that GAIN domain cleavage is not necessary for activity, at least for G1 and B1.
Receptors Lacking the Entire N Terminus Retain Activity in a Battery of Signaling Assays-It is plausible that an agonistic peptide region of the stalk could still be important for activation of aGPCR signaling even in the absence of GAIN autoproteolysis, as cleavage-independent conformational changes that expose the cryptic agonist could conceivably be responsible for receptor activity. Therefore, to definitively answer the question of whether the stalk does indeed contain a requisite agonist for G1 and B1 signaling, we created mutant versions of the receptors that lack the entire NT (including the stalk) such that they begin very close to the start of the predicted first transmembrane domain (Fig. 3, A and C). These stalkless ("SL") mutant receptors expressed and were trafficked to the plasma membrane at levels comparable to ⌬NT versions of G1 and B1 (Fig.  3, B and D), revealing that removal of the stalk region did not result in impairments in receptor expression or trafficking.
It has previously been reported that deletion of the NT up to the site of GAIN cleavage results in significant increases in the constitutive activity of aGPCRs, including G1 and B1 (5,9,10). According to the cryptic agonist model, further NT deletions that remove some or all of the stalk region should render the receptors inactive. To assess the activities of G1-SL and B1-SL, we utilized a battery of signaling assays. In the TGF␣ shedding  Ͼ 0.05). The results were different, though, in the SRF-luciferase assay, in which G1⌬NT exhibited robust activity but G1-SL did not (Fig. 4B: main effect of receptor F (4, 25) ϭ 16.97, p Ͻ 0.0001, post hoc EV versus G1-SL p Ͼ 0.05). Given these contrasting results, we measured receptor activity using a third signaling output: transcription of the nuclear factor of activated T-cells (NFAT), a readout that has been shown to be downstream of some G␣ 12/13 -coupled receptors (27,28) including G1 (27). We found that G1⌬NT signals strongly in the NFAT-luciferase assay but the full-length receptor does not (Fig. 4C: one-way ANOVA, main effect of receptor F (3, 12) ϭ 20.52, p Ͻ 0.0001). Interestingly, we found that G1-SL also strongly activated the NFAT pathway, achieving an extent of activation comparable to G1⌬NT (Fig. 4C: G1⌬NT p Ͻ 0.001, G1-SL p Ͻ 0.01). This signaling was sensitive to inhibition by the RGS domain of p115RhoGEF (29) (Fig.  5A, one-sample t test, G1⌬NT p ϭ 0.0063, G1-SL p ϭ 0.0080 compared with 0.0) and the broad-spectrum G ␤␥ inhibitor gallein (30) (Fig. 5B: one-sample t test, G1⌬NT p ϭ 0.0034, G1-SL p ϭ 0.0017 compared with 0.0), demonstrating that it is mediated predominantly by heterotrimeric G proteins.
Similar to our findings with G1, this signaling activity from B1 was significantly inhibited by co-transfection with the RGS domain of p115RhoGEF (Fig. 5C: one-sample t test, B1⌬NT p ϭ 0.0032, B1-SL p ϭ 0.0005 compared with 0.0) and also inhibited by overnight treatment (50 M) with gallein ( Fig. 5D: one-sample t test, B1⌬NT p ϭ 0.0064, B1-SL p ϭ 0.0025 compared with 0.0) demonstrating that this signaling activity is dependent on heterotrimeric G proteins. . G1-SL exhibits differential levels of signaling activity in distinct assays whereas B1-SL is consistently active. G1-SL exhibited significant signaling activity in the TGF␣-shedding (A) and NFAT luciferase (C) assays but was found to not be significantly active in the SRF-luciferase assay (B). However, B1-SL was significantly active at comparable levels to B1⌬NT in all three assays (D: TGF␣-shedding, E: SRF-luc, F: NFAT-luc) demonstrating the dispensability of the B1 post-cleavage stalk. All experiments performed in HEK cells. TGF␣, SRF-luc, and NFAT-luc results are from 4 -6 independent experiments (Ϯ S.E. shown, *, p Ͻ 0.05; **, p Ͻ 0.01; ***, p Ͻ 0.001; ****, p Ͻ 0.0001 versus cells transfected with empty vector, denoted by EV). Finally, to further assess the abilities of the SL mutants to couple to heterotrimeric G proteins, we performed co-immunoprecipitation experiments with each receptor and co-transfected EE-tagged G␣ 13 . In these experiments, the tagged G protein was immunoprecipitated and Western blots were performed to detect any co-immunoprecipitated receptor. For both G1 and B1, we found that the truncated ⌬NT and SL forms strongly and significantly co-immunoprecipitated with G␣ 13 but the full-length forms of the receptors did not (Fig. 6A: G1 one-way ANOVA F (2, 6) ϭ 10.49, p Ͻ 0.05, post-hoc test versus full-length G1, G1⌬NT p Ͻ 0.05; G1-SL p Ͻ 0.05. Fig. 6B, B1: one way ANOVA main effect of receptor, Holm-Sidak multiple comparisons B1⌬NT p Ͻ 0.05, B1-SL p Ͻ 0.01 versus B1).

Discussion
Substantial recent progress has been made in understanding the mechanisms of aGPCR activation. These mechanisms are important to understand, given the association of these receptors with several human diseases and the potential value of these receptors as drug targets (1). Specifically, it has been found for a number of aGPCRs that truncation of the receptor N termini up to the point of predicted GAIN domain cleavage leads to increased constitutive activity (5)(6)(7)(8)(9)(10)(11)(12)(13)(14). These observations led to the proposal of the disinhibition model of aGPCR activation, which posits that the NTF exerts an inhibitory constraint on signaling by the CTF, with this inhibitory constraint being removed following engagement of the NTF with a large extracellular ligand that results in either dissociation of the NTF from the CTF and/or a conformational change that reduces NTF-mediated inhibition (15). Subsequently, more mechanistically specific variations of the disinhibition model have been proposed, including the cryptic agonist model (7,9,11), wherein GAIN domain cleavage and NTF dissociation result in the unveiling of a cryptic agonist peptide on the post-  cleavage stalk of the CTF in a manner analogous to proteaseactivated receptors (33).
In the studies described above, we tested the cryptic agonist model directly in parallel experiments on two distinct aGPCRs by deleting the stalk regions and broadly assessing receptor activity using a variety of downstream outputs. Our results provide evidence that the stalk region is not a requisite agonist for these two aGPCRs, as we observed that deleting the stalk does not affect signaling to most pathways measured. In the case of ADGRB1/BAI1 ("B1"), removal of the stalk region made no difference whatsoever for any assessment of receptor activity. In fact, we found B1-SL to be significantly more active in the NFAT luciferase assay than B1⌬NT, which suggests that the stalk may actually attenuate the full signaling ability of this receptor. In contrast, studies on ADGRG1/GPR56 ("G1") resulted in mixed findings, with removal of the stalk region largely abrogating the receptor's ability to stimulate SRF luciferase but having little effect on the other readouts examined. Additionally, both B1-and G1-SL retained the ability to robustly co-immunoprecipitate with G␣ 13 . Based on these findings, we propose that aGPCRs can mediate both stalk-dependent and stalk-independent signaling, with the relative contribution of the stalk to receptor activity varying substantially between different receptors as well as between different outputs examined.
A recent study by Stoveken et al. (2015) suggested that the NT stalk of G1 is necessary for signaling activity (9). This study reported signaling data from SRE luciferase experiments in transfected cells and GTP loading experiments in a reconstitution system. Our data reported here are in agreement with the findings of Stoveken et al., as we found that the activity of G1-SL was sharply reduced compared with G1⌬NT in the SRF luciferase assay, which is very similar to the SRE luciferase assay. However, in other assays in which we assessed G1 activity (TGF␣ shedding, NFAT luciferase, ␤-arrestin recruitment and receptor ubiquitination), we found G1-SL to be in an active conformation and capable of mediating receptor signaling to a similar extent as G1⌬NT. These results suggest that the stalk region of G1 is necessary for certain aspects of receptor signaling activity but dispensable for others.
There have been prior indications that the cryptic agonist model may represent an incomplete description of aGPCR activation. For example, studies on the Caenorhabditis elegans aGPCR lat-1 demonstrated that mutations blocking cleavage of the receptor's GAIN domain exerted no effect on the in vivo function of the receptor (34). These in vivo data find a parallel in the in vitro findings reported here regarding the non-cleaving G1-T383A mutant, which we found to exhibit no change in signaling activity relative to wild-type G1. Similarly, a recent report from Peeters et al. demonstrated that non-cleavable versions of GPR64/ADGRG2 can still activate downstream signaling (12). According to the cryptic agonist model, GAIN-mediated cleavage should be essential for exposure of the agonistic peptide sequence on the stalk region. Thus, observations that the activity of at least some aGPCRs is not modulated by GAIN cleavage obviously run counter to this model. Moreover, there is convincing evidence that some aGPCRs do not undergo GAIN-mediated cleavage (35), an observation that needs to be taken into account in general models of aGPCR activation.
Another challenge faced by the cryptic agonist model is the uncertainty surrounding how aGPCR NTF regions become dissociated from their cognate 7TM regions. In the cryptic agonist model, it is envisioned that the N-terminal portion of a cleaved GAIN domain can be released from the receptor's stalk region in a regulated manner, thereby exposing the agonistic stalk peptide sequence (7,9,11 (2), it is uncertain whether dissociated GAIN domains leave the stalk behind or take the stalk with them. Interestingly, studies on ADGRL1/ CIRL/latrophilin-1 provided evidence that the release of this receptor NTF region is dependent on two proteolytic steps, with GAIN domain cleavage followed by a second cleavage event that cleaves the receptor's stalk region to release the GAIN domain and stalk together (36). According to the cryptic agonist model, the resultant 7TM region of such a twicecleaved aGPCR would be devoid of signaling activity, as the stalk region containing the agonistic peptide would have been lost with the second cleavage event. However, our studies presented here on stalkless versions of G1 and B1 demonstrate that stalkless receptors can still exert significant downstream signaling, albeit signaling that is altered in some cases (as in the case of G1) relative to receptors that possess an intact stalk.
Further work will be needed to elucidate the differences in signaling intermediates that presumably exist between the stalk-dependent versus stalk-independent signaling activities observed in our studies. As shown above, the activation of NFAT luciferase by G1 and B1 was significantly blocked by the G␤␥ inhibitor gallein and also blocked to a similar extent by the RGS domain of p115RhoGEF, which would be expected to attenuate signaling by G␣ 12/13 as well as any G␤␥ subunits released from activated G␣ 12/13 . Insofar as the SRF luciferase assay represents a more pure readout of G␣ 12/13 action, the differential change in activity observed for G1-SL in the SRF versus NFAT luciferase assays may represent a difference in the relative importance of G␣ 12/13versus G␤␥-dependent pathways (37). Yet another possibility is that ␤-arrestins may contribute to G1 and B1 signaling, with the presence of the stalk having little effect on ␤-arrestin-mediated signaling. Indeed, we found that the ⌬NT and SL versions of G1 and B1 both exhibited strong interactions with ␤-arrestin2. However, the specific contributions of the various G protein subunits and ␤-arrestins to signaling by G1, B1, and other adhesion GPCRs will require further investigation to truly assess whether the stalk regions might confer bias toward certain receptor-initiated pathways and away from others (38).
Understanding the natural mechanism(s) of aGPCR activation is a critical step toward facilitating drug development efforts aimed at these receptors. For example, the elucidation of agonistic peptide sequences on the N-terminal stalks of certain aGPCRs (7,9,11) has provided insights that may lead to the development of peptidomimetic small molecules with agonistic activity at these receptors. Similarly, the findings reported here that cryptic agonist sequences on aGPCR stalks do not account for the entirety of aGPCR signaling are important because these observations suggest an additional antagonistic effect of tethered GAIN domains on aGPCR activity beyond the simple masking of the stalk region. Therefore, we propose an allosteric antagonist model of aGPCR activation (Fig. 9), in which the NTF can antagonize receptor activity in two distinct ways: (i) by masking the stalk region and (ii) by directly antagonizing the inherent stalk-independent constitutive activity of the 7TM region. The word "allosteric" in this context is meant to convey that the NTF presumably does not block agonist binding in the manner of a competitive antagonist, but rather constrains receptor activity in an allosteric fashion. This model is consistent with the data presented here as well as in previous studies (7,9,11) and furthermore is consistent with the possibility that aGPCRs may still signal even if they are not cleaved at the GAIN domain or lose their stalk following GAIN cleavage.
Further insights into the structural determinants of the antagonistic relationship between aGPCR NTF and 7TM regions may help to facilitate discovery of distinct classes of small-molecule aGPCR modulators that either block or potentiate NTF-mediated suppression of aGPCR 7TM signaling. Additionally, a model in which aGPCRs can mediate both stalkdependent and stalk-independent signaling has clear implications for the future development of biased agonists targeting these receptors (38). In many cases, it is therapeutically desirable to target some but not all pathways downstream of a given receptor. Thus, it will be of interest going forward to study the various members of the aGPCR family on a receptor-by-receptor basis in order to understand the structural determinants of receptor coupling to different downstream signaling pathways to facilitate the discovery of biased ligands possessing therapeutic potential.
Author Contributions-A. K., R. H. P., and R. A. H. designed the experiments and wrote the manuscript. AK performed the experiments focused on ADGRG1 as well as the TGF␣ shedding assays focused on ADGRB1. R. H. P. and Z. N. T. performed all other experiments focused on ADGRB1. A. K., R. H. P., and R. A. H. analyzed the data and created the figures. All authors made intellectual contributions to the paper and take responsibility for the data.