Antibodies conjugated to bioactive compounds allow targeted delivery of therapeutics to cell types of choice based on that antibody’s specificity. Here we develop a new type of conjugate that consists of a nanobody and a peptidic ligand for a G protein-coupled receptor (GPCR), fused via their C-termini. We address activation of parathyroid hormone receptor-1 (PTHR1) and improve the signaling activity and specificity of otherwise poorly active N-terminal peptide fragments of PTH by conjugating them to nanobodies (VHHs) that recognize PTHR1. These C-to-C conjugates show biological activity superior to that of the parent fragment peptide in vitro. In an exploratory experiment in mice, a VHH-PTH peptide conjugate showed biological activity, whereas the corresponding free peptide did not. The lead conjugate also possesses selectivity for PTHR1 superior to that of PTH(1-34). This design approach, dubbed “conjugation of ligands and antibodies for membrane proteins” (CLAMP), can yield ligands with high potency and specificity.
Antibodies bind tightly and specifically to their targets, even in highly complex environments. This property of antibodies has been used to deliver bioactive compounds to sites of interest, both for diagnostic and therapeutic applications1. For example, conjugates between antibodies and cytotoxic drugs (antibody-drug conjugates or ADCs) can selectively kill cancer cells that display the antibody’s target2. The success of ADCs often depends on the internalization of the conjugate through endocytosis, followed by release of the cytotoxic payload. Far fewer studies have made use of antibodies to deliver bioactive compounds with sites of action at the cell surface. The conjugation of a ligand for a surface receptor to an antibody that recognizes that same receptor should increase the effective concentration of the ligand and so increase its potency and specificity, provided appropriate spatial constraints are maintained. Ideally, this method could be used with an antibody that directly targets the receptor of interest to enable application without the need for genetic modification of the target cells or organism. The G protein-coupled receptor (GPCR) family of proteins is an attractive class of targets to pursue using this approach.
Molecules that target GPCRs represent more than 25% of all approved drugs3. Antibodies and the variable fragments of camelid heavy chain-only antibodies (VHHs or nanobodies) have found increasing use for modulating GPCR signaling4,5. GPCRs and their ligands display a considerable degree of degeneracy. Several natural ligands bind to more than a single GPCR and many GPCRs can bind more than one ligand6,7. The parathyroid hormone receptors constitute one such example: a bioactive N-terminal fragment of parathyroid hormone (PTH, residues 1–34), used under the name teriparatide to treat osteoporosis, potently activates both type-1 and type-2 PTH-receptors (PTHR1/PTHR2)8. PTHR1/2 are part of the class B of GPCRs which are naturally activated by large (>25 residue) peptides9. Despite intense industry interest, no small molecule agonists of B-family GPCRs with potencies comparable to the natural ligands have been described. To address PTHR signaling and selectivity, we prepared conjugates of fragments of PTH and VHHs. VHHs are appealing building blocks for these conjugates, as they are the smallest antibody fragments that retain the ability to bind antigens. They can be produced in high yield recombinantly10. The site of antigen recognition on VHHs is near the N-terminus11,12 and the interaction of PTHR1 and PTHR2 with their ligands requires a free N-terminus on the latter8,13,14. Using a chemo-enzymatic approach we therefore made C-to-C-terminal fusions of PTH fragments and VHHs15 to avoid any N-terminal obstructions. These chimeric molecules, dubbed: conjugates of ligands and antibodies for membrane proteins or CLAMPs, target either wild-type or engineered receptor variants (Fig. 1). The optimized CLAMPs display biological activities in vitro and in vivo that are superior to those of the PTH fragments from which they were derived. When otherwise weakly active PTH fragments are incorporated into these conjugates, they can be made exquisitely selective for activation of only those receptors engaged by the VHH. This stands in marked contrast to the lack of selectivity shown by PTH(1-34)8. These findings suggest that CLAMPs should be broadly applicable for the design of ligands with unique and useful properties.
Receptor constructs and conjugates used for targeting
PTH(1-34) interacts with PTHR1 via a two-site mechanism of interaction (Fig. 1a, b)8,16. The association between the extracellular domain of PTHR1 and residues 15–34 of PTH provides the bulk of the binding energy and specificity for this interaction. The association between the transmembrane domain of PTHR1 and residues 1–14 of PTH induces a conformational change in the receptor, which initiates intracellular signaling cascades. This mode of interaction, supported by a large amount of structure-activity relationship data, has been confirmed recently by crystallography and cryo-electron microscopy of PTHR1-ligand complexes (Fig. 1a)13,14.
To mimic receptor association exhibited by PTH(1-34), we used either wild-type PTHR1 or PTHR1 variants modified to carry an epitope in the extracellular domain recognized by a VHH of choice. While there is no structural information for any VHH bound to PTHR1, we envisioned a mode of interaction between the receptor and VHH-PTH conjugates like that depicted in Fig. 1c. The portion of PTHR1 encoded by exon 2 is not resolved in structural studies (Fig. 1d)13,14,17, is not important for ligand binding18, and in past work has been targeted as a site for receptor modification18,19. We generated a construct that encodes a PTHR1 variant in which a 14-residue fragment from exon 2 was replaced with a 14-residue epitope tag from the intracellular protein UBC6e (PTHR16E, Fig. 1d)20. We also used a receptor construct in which a pH-sensitive green fluorescent protein variant (GFP) was inserted into the portion of the receptor encoded by exon 2 (PTHR1GFP in Supplementary Fig. 1)19. Another version of PTHR1 in which yellow fluorescent protein (YFP) replaces the entire N-terminal extracellular domain (PTHR1YFPΔECD, Fig. 1e)21, was also used.
To target these receptors, we constructed conjugates comprised of N-terminal fragments of PTH and VHHs (Fig. 1). We used VHHs that recognize green or yellow fluorescent proteins (VHHGFP)22, a 14-mer peptide fragment from the intracellular protein UBC6e (VHH6E)20, or PTHR1 itself (VHHPTHR)23. We expressed C-terminally His-tagged VHHs in bacteria in a form amenable to subsequent site-specific functionalization at the C-terminus, using sortase A-mediated labeling (sortagging)24,25. To these purified VHHs we attached either a triglycine-modified fluorophore for cytofluorimetry or a peptide with azide and biotin moieties for biorthogonal chemistry and conjugate tracking, respectively (Fig. 2).
We determined whether VHHs would bind to their intended targets on live cells by flow cytometry (Fig. 3a). We stained HEK293 cell lines stably transfected with the PTHR1 variants described above, rat PTHR1 (rPTHR1)26, or PTHR2. rPTHR1 has been studied extensively and is identical to murine PTHR1 (mPTHR1) in the extracellular domain outside of exon 2. VHHs that bind to rPTHR1 should also bind to mPTHR1 and be useful for studies in mice. Each of the VHHs stained cell lines as expected, with the exception of the VHHGFP-PTHR1GFP pair, as discussed in Supplementary Fig. 1. VHHPTHR bound all constructs that retained the PTHR1 ECD, including rat PTHR1, but not PTHR1YFPΔECD. This places the binding site of VHHPTHR in the PTHR1 extracellular domain (ECD). Only VHHGFP stained cells that express PTHR1YFPΔECD, consistent with its ability to bind YFP22. None of the VHHs tested stained the cell line that expresses PTHR227. To estimate the affinity of the selected VHH for their targets we used flow cytometry to measure binding. The staining of PTHR1YFPΔECD by VHHGFP and PTHR16E by VHH6E exhibited half-maximal staining at <10 nM, whereas the staining of cells expressing each of the PTHR1 receptor constructs that retained the ECD reached half-maximal staining at 100–200 nM (Supplementary Fig. 4). The precise half-maximal staining concentrations for VHHPTHR are unknown because the intensity of staining (MFI) did not plateau at the highest concentrations tested and binding strength was estimated from other experiments.
We used microscopy to complement flow cytometry and visualized distribution of either PTHR1 or PTHR16E following engagement by PTH(1-20), functionalized with fluorescein, and either VHHPTHR or VHH6E tagged with tetramethylrhodamine (Fig. 3b, Supplementary Fig. 5). Imaging of cells fixed immediately after staining on ice shows colocalization of VHH and PTH at the cell surface. Following a 15-min incubation at room temperature, we observed punctate and colocalized fluorescent signals, corresponding to endocytosed receptor-PTH-VHH complexes28. Cells not transfected with PTHR1 showed weak staining (Supplementary Fig. 5). These data indicate that the indicated VHHs and PTH(1-20) can simultaneously engage the receptor.
PTHR1 peptide ligands and conjugation to antibody fragments
To test whether delivery of PTH fragments to their site of action by conjugation to VHHs affects their signaling activity, we synthesized N-terminal fragments of PTH (Fig. 2, Table 1, Supplementary Fig. 6). These fragments were prepared as C-terminal amides by conventional solid-phase peptide synthesis, and purified. Their identities were confirmed by mass spectrometry (Fig. 2, Supplementary Fig. 2). Most of these peptides contained several of the modifications found in the M-PTH series of PTH peptides, including the non-standard residue aminoisobutyric acid (Aib) at position 3, which enhances the biological activity of these short PTH fragments (Fig. 2)29. Each of these peptides contained a C-terminal cysteine (Cys). Using Cys-maleimide chemistry we appended a dibenzylcyclooctyne (DBCO) handle (Supplementary Fig. 2) to enable an azide-alkyne conjugation between the C-termini of an azide-functionalized VHH and a DBCO-modified synthetic peptide. Of note, the resulting triazole linkage is not susceptible to cleavage by reduction, unlike the disulfide linkages used in other conjugates. The composition of the conjugates was confirmed by mass spectrometry (Fig. 2, Supplementary Fig. 3). For comparison, we also prepared conjugates in which a PTH(1-14) analog with an N-terminal triglycine extension (G3-PTH(1-14)) was conjugated to VHHs using sortagging, resulting in a conjugate with the more conventional C-N configuration (Supplementary Fig. 7).
We then assessed the capacity of these peptides and conjugates to stimulate the production of cyclic adenosine monophosphate (cAMP), a second messenger molecule produced upon PTHR1 activation, using HEK293 cells expressing a PTHR variant targeted by the relevant VHH and a luciferase-based cAMP-responsive reporter30. Progressive truncation of C-terminal residues from PTH(1-34) caused a marked loss in the potency on wild-type PTHR1 and other PTHR1 variants with intact ECDs (Table 1, Supplementary Fig. 6). Addition of a triglycine appendage at the N-terminus of PTH(1-14) caused a reduction in potency, relative to PTH(1-14) with a free N-terminal amine (Supplementary Fig. 7), in line with precedent31. Conjugates in which G3-PTH(1-14) was ligated to the VHH C-terminus using sortase were completely inactive, emphasizing the importance of a free N-terminus for PTH and its fragments (Supplementary Fig. 7). In contrast, conjugates formed by C-to-C-terminal fusion were active (Table 1, Supplementary Fig. 6).
The conjugation of PTH fragments lacking residues 15–34, known to be important for ECD binding, to VHHs that bound to the targeted receptor showed a strong increase in potency (Table 1). For example, VHHGFP-PTH(1-10) is 7800-fold more potent than PTH(1-10) on PTHR1YFPΔECD. The potency of VHHGFP-PTH(1-10) at PTHR1YFPΔECD (EC50 ~ 0.5 nM) is especially notable given that PTH(1-34), an analog with properties similar to naturally occurring PTH, is relatively weakly active (EC50 > 500 nM) on this receptor. VHHPTHR conjugation also increases the potency of PTH(1-11) and PTH(1-14) at PTHR1, PTHR1GFP, and PTHR16E, in line with results from VHH binding experiments (Supplementary Fig. 4). As an example, VHHPTHR-PTH(1-14) is 57-fold more potent than PTH(1-14) on cells that express wild-type PTHR1. Even VHHs that showed weak staining of the relevant cell lines in cytofluorimetry, like that of VHHGFP on PTHRGFP-expressing cells, still enhanced the signaling activity of N-terminal fragments like PTH(1-11) (Supplementary Fig. 1). Signaling duration, as assessed using a previously validated method27,29,32, is also prolonged for the shorter PTH fragments when conjugated to the appropriately specific VHH (Supplementary Fig. 8). The kinetics of cAMP signaling induced by some VHH-PTH fragments resemble that seen with PTH(1-34) (Supplementary Fig. 8). The ability of a ligand to induce prolonged signaling at PTHR1 is correlated with continued signaling upon internalization into endosomal compartments, PTH(1-34) serving as a prime example29. The prolonged signaling of VHH-PTH conjugates relative to the corresponding free peptides suggests that the added affinity provided by VHH binding may enable endosomal signaling.
In contrast to the increase in signaling activity provided by the conjugation of PTH fragments to receptor-binding VHHs, conjugation of active PTH fragments with irrelevant VHHs is detrimental to activity on the intact PTHR1. For example, even at the highest concentrations tested, conjugates of VHH6E and VHHGFP with PTH(1-11) and PTH(1-14) are inactive on wild-type human PTHR1, even though the peptides themselves are quite active (Table 1, Supplementary Fig. 6). This loss of activity is caused at least in part by a loss in receptor binding for PTH fragments conjugated to irrelevant VHHs (Supplementary Fig. 9). VHH6E-PTH(1-14) fails to bind hPTHR1 expressing cells, whereas VHHPTHR-PTH(1-14) binds more tightly than VHHPTHR alone. The impact of irrelevant VHH conjugation is not explained by variation in signaling activity caused by installation of the ‘click’ handles (Supplementary Fig. 10). Furthermore, the length of the VHH-PTH linker is not a strong determinant of conjugate signaling activity or specificity: incorporation of a PEG3 linker has minimal impact (Supplementary Fig. 10). The enhanced signaling activity provided by VHH conjugation is not seen with PTHR1 ligands that bind through both ECD and transmembrane domain interactions: conjugation of PTH(1-34) with VHHs yields active compounds, regardless of whether the target of the VHH is present on the cell line tested (Supplementary Fig. 11). VHHPTHR-PTH(1-14) activated PTHR1YFPΔECD, even though the VHH does not bind to this receptor (Table 1).
Among the GPCR superfamily, family B GPCRs have relatively large ECDs. To assess whether the CLAMP approach might also be useful for GPCRs with smaller ECDs, we targeted a variant of PTHR1 in which the entire ECD is replaced by the 6E epitope tag (QADQEAKELARQIS, Supplementary Fig. 12)20. Application of VHH6E-PTH(1-11) activated PTHR1-delNT-6E more effectively than PTH(1-11) (Supplementary Fig. 12b). In control experiments, PTHR1-delNT (no 6E tag) was not activated by VHH6E-PTH(1-11) (Supplementary Fig. 12c).
Activated GPCRs can signal through more than one intracellular pathway, at the cell surface or from cell-internal compartments. There is interest in identifying ligands that are functionally selective in signaling through one pathway over another (biased agonists)33. PTHR1 signals through multiple pathways, including Gs/protein kinase A (PKA)/cAMP, Gq/phospholipase C (PLC)/Ca2+, and β-arrestin/ERK34. We tested whether selected VHH-PTH conjugates engaged these pathways. VHHPTHR-PTH(1-14) but not VHHPTHR-PTH(1-11) stimulated signaling though the Gq/PLC/Ca2+ signaling pathway in cells that express PTHR1 (Supplementary Fig. 13). VHHPTHR-PTH(1-11) appears to be selective for Gs/PKA/cAMP signaling, although assessing Gq signaling at higher conjugate concentrations than currently possible or using different assay formats might yet reveal weak activity. PTHR1 signaling through the Gq is more sensitive to structural modifications and alterations in affinity than signaling through the Gs pathway8,34, in line with these findings. We also determined whether VHHPTHR-PTH(1-14) could induce PTHR1 to recruit β-arrestin. PTH(1-34) and VHHPTHR-PTH(1-14) (Supplementary Fig. 14a, d), but not VHHPTHR alone (Supplementary Fig. 14e), stimulated the relocalization of cytoplasmically disposed YFP-tagged β-arrestin into distinct puncta. Colocalization of a fluorophore-tagged PTH(1-34) with YFP-β-arrestin in puncta supported the specificity of arrestin recruitment to the agonist-occupied PTHR1 (Supplementary Fig. 14c). In a separate experiment, cells that express YFP-β-arrestin, transfected with a PTHR1 construct containing an HA-epitope tag in exon 2 (PTHR1-HA), were treated with VHHPTHR-PTH(1-14). This resulted in punctate YFP signals that colocalized with PTHR1-HA (Supplementary Fig. 15a–c). Many of the puncta observed in cells treated with PTH(1-34) or VHHPTHR-PTH(1-14) were observed near the nucleus (Supplementary Figs. 14, 15), consistent with ligand-induced internalization. No colocalized puncta were observed in cells treated with VHHPTHR, and HA-staining appeared restricted to the cell surface (Supplementary Fig. 15d–f). We further examined ligand-induced internalization through the use of cells expressing PTHR1-GFP, in which the GFP variant is pH-sensitive. Since the spectral properties of this GFP variant change as a function of pH19, the movement of the receptor from the cell surface into the acidic endolysosomal compartment can be followed by monitoring the change in wavelength of emitted fluorescence after addition of ligand (Supplementary Fig. 16). In this assay, VHHPTHR-PTH(1-14) behaves similarly to PTH(1-34), an agonist known to induce PTHR1 internalization34, providing further evidence that VHHPTHR-PTH(1-14) induces internalization. Overall, VHHPTHR-PTH(1-14) behaves similarly to PTH(1-34) in each of these cell-based assays tested.
The selectivity of PTH fragments for tagged receptors imparted through conjugation to VHHs led us to test whether similarly enhanced selectivity could be achieved between two naturally occurring subtypes of PTHR. PTH(1-34) tightly binds and activates both PTHR1 and PTHR28. VHHPTHR binds to PTHR1 but not PTHR2 (Fig. 3). VHHPTHR-PTH conjugates should therefore activate PTHR1 but not PTHR2. We focused on conjugates of PTH(1-14), as this fragment also activated PTHR1 and PTHR2 (Fig. 4). The VHHPTHR-PTH(1-14) conjugate activated PTHR1 more potently than any other compound tested in this study (EC50~0.07 nM), whereas it was completely inactive at PTHR2 at 330 nM (>4500-fold selectivity for PTHR1, Fig. 4). This contrasts with the observed lack of selectivity of PTH(1-34) (5-fold selectivity for PTHR1; here and in past work8).
In vivo activity
We tested whether the potent biological activity observed for VHH-PTH conjugates in cell-based assays would extend to an in vivo setting. We used the VHHPTHR-PTH(1-14) conjugate in these experiments because it was more potent than VHHPTHR-PTH(1-11). VHHPTHR potentiated PTH(1-11) signaling activity for the rat PTHR1 (Supplementary Fig. 17). Since VHHPTHR bound rat PTHR1 (Fig. 3) we were confident that it would also bind mouse PTHR1, as these receptors are 99% identical in their extracellular domain. To measure in vivo activity, we injected mice subcutaneously with equimolar amounts of either PTH(1-34), M-PTH(1-14), VHHPTHR-PTH(1-14), or saline. Doses were chosen based on precedent for the treatment of mice with PTH(1-34) to stimulate acute calcemic responses29,32. PTH(1-34) induced a strong increase in blood ionized calcium levels, which peaks 1-2 h after injection and returns to baseline thereafter, whereas free M-PTH(1-14) exhibits little if any activity in this assay, in line with past findings29. Our experiment showed that VHHPTHR-PTH(1-14) stimulated a spike in blood calcium that peaked two hours after injection (Fig. 5). The conjugation of PTH(1-14) with VHHPTHR therefore potentiates biological activity both in cell-based assays and in vivo.
Antibodies as part of conventional antibody-drug conjugates deliver cytotoxic compounds that typically target intracellular proteins1,2. Less explored is the use of antibodies to deliver ligands for surface receptors such as GPCRs. This is likely due to complications in preparing homogenous and bioactive conjugates of antibodies and ligands that rely on antibody binding to potentiate engagement of receptor by the ligand. Immunocytokines (conjugates of cytokines and antibodies) are an exception35. Immunocytokines have progressed to the clinic, but not without toxicity, suggesting an inadequacy in targeting35. In one case, even the identity of the targeting antibody of the immunocytokine was irrelevant for its in vivo efficacy36. Mutations in cytokines, introduced to improve the selectivity of immunocytokines, can dampen the affinity for their receptors37,38. Immunocytokine-based approaches differ from the CLAMP platform in that they rely on genetic fusions (and genetically encoded residues) and the use of full-size cytokine domains, as opposed to the small peptide fragments with non-natural residues used here.
In one precedent for targeting GPCRs with antibody-ligand fusions, VHHGFP equipped with a SNAP-tag was linked to a photoactivatable ligand for the GPCR mGluR239. This fusion was then used to activate a GFP-tagged receptor upon photoactivation of the ligand. The response induced by a saturating concentration of the photoactivatable VHH-ligand conjugate was ~40% of that induced by a saturating dose of natural ligand and required the use of a receptor-GFP fusion39. This strategy precludes the use of genetically unmodified cells or animals. In another example, full-length anti-PCSK9 antibodies fused at the N-terminus of the heavy or light chain with analogs of the glucagon-like peptide 1 (GLP-1) were produced40. However, most of the fusions tested were expressed in low yield, isolated with inactivating truncations in the GLP-1 fragment, unstable in solution, or were degraded rapidly in vivo, demonstrating the difficulties encountered when expressing fusion proteins comprised of full-length antibodies and ligands of interest40.
Despite several screening campaigns, no VHHs that directly activate GPCRs have been identified as of yet5. We prepared a library of C-to-C terminal fusions of VHHs and synthetic PTH peptides. The use of C-to-C fusions is supported by the lack of activity of the corresponding N-to-C fusions (Supplementary Fig. 7). It is possible that the genetic fusion of PTH peptides to the N-terminus of VHHs might be accommodated with retention of both VHH binding and PTH activity. This would require a unique genetic construct and optimization of expression for each fusion. We avoid these drawbacks through our chemoenzymatic approach. A further benefit of our synthetic strategy compared to a purely genetic approach is the ease of incorporation of non-natural residues such as Aib into the peptide portion of the conjugate to improve proteolytic stability40. Several conjugates stimulated cAMP responses with potencies similar to that of PTH(1-34) (Table 1). Even PTH(1-9), which fails to activate PTHR1 unless tethered directly to the receptor’s N-terminus via genetic fusion41, showed activity when conjugated to a VHH (Table 1). VHH-mediated delivery of ligands should enable identification of weak ligands that might otherwise be dismissed as completely inactive. Similar observations were made in evaluating conjugates consisting of peptide fragments derived from the N- and C-termini of corticotrophin releasing factor-1, which were weakly active or inactive alone, but once assembled via click chemistry, several conjugates were potent agonists42.
Agonist activity for VHH-PTH conjugates was completely dependent on binding of the VHH to the receptor being targeted: a mismatch between specificity of the VHH and the receptor construct led to a loss in conjugate activity. We identified a conjugate, VHHPTHR-PTH(1-14), with very potent signaling activity in cell-based assays (Table 1), with biological activity in mice (Fig. 5), and with selectivity for PTHR1 over PTHR2 that far surpasses the selectivity of PTH(1-34), the prototypical PTHR1 agonist (Fig. 4) used clinically. PTHR1 mediates the biological activity of PTH in treating osteoporosis, whereas the function of PTHR2 is more obscure. Tools to selectively target PTHR1, and subtypes of GPCRs in other families, will be useful for dissecting the biological function of receptors for which potent and selective ligands are scarce. Success in targeting PTHR1 over PTHR2 sets the stage for designing ligands that specifically activate other receptors with overlapping specificities6,7.
The ability to deliver ligands to specific subtypes of receptors, or to receptors engineered to contain an antibody-recognized tag, should allow the creation of (modular) versions of designed receptors exclusively activated by designer drugs (DREADDs)43. Previously described DREADDs for GPCRs were identified through modification of the ligand binding site of naturally occurring GPCRs, so that the modified receptors respond to a designer small molecule but not the ligand of the prototype receptor. These designer molecules selectively activate the designer receptor but not any endogenously expressed alternative44,45. A similar approach has been deployed to produce an orthogonal receptor-ligand pair for interleukin-246. Our finding that VHHGFP-PTH(1-11) potently activates PTHR1YFPΔECD (EC50 ~ 0.15 nM) but is inactive at wild-type PTHR1, suggests a path toward using VHH-tag recognition as a way to convert a GPCR of choice into a DREADD. One aspect of GPCR pharmacology that has not been faithfully reproduced in some DREADD constructs is that of ligand binding kinetics47. For some receptors, such as PTHR1, the duration of ligand binding and the signaling induced as a consequence can dictate the type of physiological response evoked. The duration of the cAMP response elicited by PTHR1 activation is correlated with the strength and duration of the calcemic response in vivo29,48. Several of the VHH-PTH conjugates tested here induce cAMP signaling that is prolonged relative to the free peptide and similar to that of PTH(1-34) (Supplementary Fig. 8), suggesting that the affinity provided by VHH binding can be used as an independent means to adjust ligand binding and signaling kinetics.
In conclusion, we show that the conjugation of otherwise suboptimal PTHR1 agonist peptides to VHHs that target the intended receptor provides a substantial increase in agonist potency and receptor selectivity. The ability to modulate receptor affinity while not modifying the structure of the agonist used to activate signaling should enable a further dissection of connections between ligand affinity, receptor signaling kinetics, and ligand bias49. Preliminary analyses suggest that VHH-ligand conjugates can be designed that possess signaling properties that diverge from that of the natural ligands (Table 1, Supplementary Fig. 13). The CLAMP platform should be amenable to targeting other GPCRs, especially those with large peptide ligands that bind to their receptors via a two-site mechanism, such as family B GPCRs and chemokine receptors. Efforts are underway to expand this platform to other GPCR-ligand systems. The applicability of this platform will expand as VHHs that bind to new targets on the cell surface are discovered5.
HEK293 cell lines (ATCC) were cultured in DMEM medium supplemented with 10% (v/v) fetal bovine serum and penicillin/streptomycin. Cell lines were routinely tested for mycoplasma infection. LC/MS was performed on a Waters Xevo Q-Tof system equipped with HPLC-C8 columns. Mass spectra were obtained using Q-Tof mass spectrometry with a positive ionization mode. Masses for VHHs and conjugates were calculated via analysis of multiply charged ions using the MaxEnt feature on MassLynx software. Protein and peptide concentrations were calculated using absorption at 280 nm for VHHs and peptides with tryptophan (Trp) residues. For peptides without Trp, the amount of peptide was quantified gravimetrically assuming that the weighed mass consisted of 50% peptide (w/w). Antibody used for staining PTHR1-HA (anti-HA-AF594) was purchased from Biologend (BioLegend #901511) and used at a final concentration of 20 nM. Transfections of HEK293 were performed using Lipofectamine2000 using manufacturer instructions.
Plasmids and DNA
HEK293-derived cell lines stably expressing human PTHR1 (GP2.3), rat PTHR1 (GR35), PTHR1GFP (GPG10), and PTHR1YFPΔECD (GD5Y) along with a cAMP-responsive luciferase variant have been previously reported19,21,26. A HEK293 cell line stably expressing β-Arrestin2-YFP (GBR24) was constructed similarly50. PTHR16E was produced using the Q5 Site-directed mutagenesis kit (NEB) and used to prepare a stably transfected HEK293-derived cell line. Annotated sequence data for all PTHR1 constructs are found in Supplementary Fig. 19. Aligned sequences of VHHs used in this study are shown in Supplementary Fig. 20.
Peptides were prepared using conventional solid-phase synthesis methods with Fmoc-protection of backbone amines. Synthesis was performed on Rink-amide linker resin to yield C-terminal amides. Backbone deprotection was performed via treatment with piperidine in dimethylformamide (DMF, 20% vol/vol) for 15 min at room temperature. Coupling was performed using Fmoc-protected amino acids (4 equivalents), N,N,N′,N′-Tetramethyl-O-(1H-benzotriazol-1-yl)uronium hexafluorophosphate (HBTU, 4 equivalents), and diisopropylethylamine (DIPEA, 8 equivalents) in DMF for 45 min at room temperature. Fmoc-Lys(biotin)-OH and Fmoc-Lys(azide)-OH were from used from commercial sources without alteration of the synthetic methods described above. Following completion of synthesis, the resin was dried and deprotection was carried out using a solution of 92.5% trifluoroacetic acid, 5% H2O, and 2.5% TIPS. Peptides were precipitated into diethyl ether, pelleted by centrifugation, dried under a stream of air, purified using reversed-phase C18 HPLC using a water-acetonitrile gradient, and lyophilized. The identity and approximate purity of peptides was confirmed by LC/MS (Supplementary Fig. 1). Purified products were dissolved in water (10 mM stock concentration) and stored at −20 °C.
Purified peptides with C-terminal cysteines were subjected to a reaction with a 2-fold molar excess of either DBCO-maleimide (Click Chemistry Tools) or DBCO-PEG3-maleimide (ConjuProbe) (Supplementary Fig. 10) in solvent with 50% (v/v) dimethylsulfoxide (DMSO) and 50 mM pH 7.4 phosphate buffer and purified by reversed-phase C18 HPLC. The identity of peptides was confirmed by LC/MS (Supplementary Fig. 2). Purified products were dissolved in DMSO (1 mM stock concentration) and stored at −20 °C.
Protein expression and purification
The production and purification of VHHGFP (named VHH-enhancer) and VHH6E (named VHH05) has been described previously20,22. The sequence for VHHPTHR was acquired from the literature (named 22A3)23. Although several VHHs that bound PTHR1 were reported, we chose 22A3 as it was reported to have the highest affinity23. Briefly, VHHs were expressed using the pHEN6 vector. Plasmids coding for PelB-VHH-LPETGG-His6 were transformed into WK6 E. coli using heat shock. Transfected WK6 E. coli were grown in Luria Bertani broth under ampicillin selection at 37 °C until an optical density at 600 nm between 0.6 and 0.8 was reached. Protein expression was induced by the addition of 1 mM IPTG and cells were grown at 30 °C overnight. The bacteria were pelleted by centrifugation and resuspended in TES buffer (50 mM Tris, 650 μM EDTA, 2 M sucrose, 15 mL buffer per liter of culture) to prepare for osmotic shock. After incubating for 2 h at 4 °C, 75 ml distilled H2O was added, and the bacterial suspension was incubated overnight at 4 °C. The bacteria were again pelleted and VHHs were purified from the supernatant by Ni-NTA bead batch purification, followed by buffer exchange. Sortase-A pentamutant was expressed and purified as previously described3.
Suspensions of cells in PBS were stained for 1 h on ice in the presence of indicated concentrations of VHH probes functionalized with Alexafluor647. Cells were pelleted by centrifugation and washed with PBS prior to analysis by flow cytometry (BD Accuri C6). To select intact cells gating was performed on forward scatter/side scatter profiles for analysis (see Supplementary Fig. 4 for an example of the gating strategy). Data were analyzed using FlowJo version 7.6. The median fluorescent intensity (MFI) of stained cells was used to generate VHH binding dose response curves (Supplementary Fig. 4). For curves that did not reach plateau at the highest concentrations tested, curves were constrained by setting the maximal plateau value equal to that seen when staining that cell line with other VHHs that did achieve a plateau.
Sortase-mediated labeling (sortagging)
VHHs were labeled using sortase A pentamutant25. Briefly, VHH (20–100 μM) with a C-terminal sortase-recognition motif and His-tag were incubated with GGG-peptide (500 μM) and sortase A pentamutant (10 μM) in Tris-buffered saline (TBS) containing 10 mM CaCl2 overnight at 14 °C. DMSO was added at concentrations up to 20% (vol/vol) in cases where conjugates were prone to aggregation, as previously described51. Functionalized VHHs were purified from unreacted VHH and sortase by exposure to nickel-NTA sepharose beads and removal of GGG-peptide by buffer exchange using a 10 kDa molecular weight cutoff spin filter or a PD10 disposable size exclusion column. Purified VHH conjugates were concentrated using 3 kDa spin filter. Since VHH-PTH(1-14) and VHH-G3-PTH(1-14) conjugates were prone to precipitation following concentration this step was avoided or minimized.
VHH-peptide conjugation reactions
VHH-biotin-azide conjugates (Fig. 2) were mixed with PTH-DBCO (3-fold molar excess) in TBS with 10% (v/v) glycerol. The reaction was shaken at 22 °C until unreacted VHH-biotin-azide had been completely consumed. The product conjugate was purified from free PTH-DBCO using a PD10 size exclusion column. Product identity was confirmed by LC/MS (Supplementary Fig. 3).
Monolayers of HEK293 cells grown on glass cover slips at approximately 80% confluency were washed with Hanks balanced salt solution supplemented with 10 mM HEPES pH 7.4 and 0.1% (w/v) bovine serum albumin (HB). The cells were then incubated with peptide, VHH, or VHH-peptide conjugates in HB at 4 or 22 °C for 30 m. After staining, cells were washed with HB three times, and fixed with 4% formalin either immediately after rinsing or following a 15 m incubation at 22 °C in DMEM + 10% FBS. Indicated slides were permeabolized using 0.5% Triton X100, followed by staining with commercial anti-HA-Alexafluor 594 antibody (20 nM, BioLegend #901511). Cells were then rinsed and mounted with Vector-shield containing DAPI (to visualize nuclei) on glass slides for imaging. Images were acquired using a Nikon Eclipse Ni system with a ×40 PLAN FLUOR 0.75NA DIC M/N2 objective.
Measurement of cAMP response
These assays were performed as previously described26. Briefly, HEK-293-derived cell lines that stably express the Glosensor cAMP reporter (Promega Corp.)30 and PTHR1, a PTHR1 variant, or PTHR2 were seeded into white sided 96-well plates (50,000 cells/well) and grown to confluency. Confluent monolayers of cells were pre-incubated with CO2 independent medium containing D-luciferin (0.5 mM) at 37 °C until a stable baseline level of luminescence was established (20 min). Varying concentrations of ligands were then added, and the time course of luminescence response was recorded using BioTek plate reader. The maximal luminescence response (observed 12–16 min after ligand addition) was used to construct dose-response data sets (Table 1, Supplementary Fig. 6).
For the measurement of cAMP signaling duration experiments (Supplementary Fig. 8) were performed as previously described27. Cells were treated with ligands at the indicated concentrations for 12 min (ligand-on phase). After this period, the medium in each well was removed and the cells were rinsed twice with CO2-independent medium to remove unbound ligand. After the addition of D-luciferin-containing fresh medium to each well, the luminescence was recorded for an additional 30–40 min using a PerkinElmer Envision plate reader (ligand-off phase).
Measurement of cytoplasmic calcium mobilization
The mobilization of Ca2+ levels was assessed in the HEK293 cell line stably transfected with human PTHR1. Intracellular Ca2+ levels were assessed using a cell-permeant Ca2+ sensor, Fura2-AM (Invitrogen). Cells in a black 96-well plate were loaded with Fura2-AM in the presence of Pluronic F-127 for 45 min and then rinsed with Hanks buffered saline solution (HBSS). Following an additional 30-min incubation in HBSS, the plate was analyzed using a PerkinElmer Life Sciences Envision plate reader to monitor fluorescence emission at a wavelength of 510 nm, upon excitation at wavelengths of 340 and 380 nm. The data were recorded at 2-s intervals prior to and after ligand addition. The data were calculated as the ratio of the fluorescence signal obtained with excitation at 340 nm to that obtained with excitation at 380 nm.
Measurement of internalization using GFP fluorescence
Receptor internalization was assessed in the HEK293 cell line stably transfected with human PTHR1-pHluorin2-GFP (GPG10)19. Confluent monolayers of cells in black walled 96-well plates were incubated in HBSS with bovine serum albumin (0.1% w/v) and HEPES buffer (pH 7.4, 10 mM). Peptides or peptide-VHH conjugates were added and wells were analyzed by recording fluorescence readouts with excitation at 485 or 405 nm and emission at 535 nm. Data were analyzed as a ratio of fluorescence intensity following excitation at 485/405 nm over the course of 90 min.
Animal experiments and measurement of in vivo response
Mice (CD1 female, age 11 weeks) were treated in accordance with the ethical guidelines adopted by Massachusetts General Hospital. Calcemic response assays were conducted using cohort sizes comparable to past work26, which provided data adequate for identifying differences in the time course and magnitude of PTH-induced calcemic responses. Peptides and conjugates were administered at doses that allowed for differentiation between compounds with differing levels of in vivo activity26. Statistical analyses were performed assuming Gaussian distribution of data. Mice (n = 4 per compound) were injected subcutaneously with vehicle (10 mM citric acid/150 mM NaCl/0.05% Tween-80, pH 5.0) or vehicle containing PTH or conjugate at a dose of 35 nmol/kg body weight. Prior to injection, mice were grouped according to basal blood calcium concentrations to ensure each group possessed similar average (mean) blood ionized calcium levels at t = 0. Blood was withdrawn just before injection (t = 0) or at times thereafter. Tail vein blood was collected and immediately analyzed. Blood Ca2+ concentration was measured with a Siemens RapidLab 348 Ca2+/pH analyzer.
Data were processed using Microsoft Excel and GraphPad Prism 6. Data from cAMP dose–response assays were analyzed using a sigmoidal dose–response model with variable slope. Data sets were statistically compared by using Student’s t test (two-tailed) assuming unequal variances for the two sets.
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Carter, P. J. & Lazar, G. A. Next generation antibody drugs: pursuit of the ‘high-hanging fruit’. Nat. Rev. Drug Disco. 17, 197–223 (2018).
Thomas, A., Teicher, B. A. & Hassan, R. T. Antibody-drug conjugates for cancer therapy. Lancet Oncol. 17, E254–E262 (2016).
Hauser, A. S., Attwood, M. M., Rask-Andersen, M., Schioth, H. B. & Gloriam, D. E. Trends in GPCR drug discovery: new agents, targets and indications. Nat. Rev. Drug Disco. 16, 829–842 (2017).
Hutchings, C. J., Koglin, M., Olson, W. C. & Marshall, F. H. Opportunities for therapeutic antibodies directed at G-protein-coupled receptors. Nat. Rev. Drug Disco. 16, 787-+ (2017).
Heukers, R., De Groof, T. W. M. & Smit, M. J. Nanobodies detecting and modulating GPCRs outside in and inside out. Curr. Opin. Cell Biol. 57, 115–122 (2019).
Scholten, D. J. et al. Pharmacological modulation of chemokine receptor function. Br. J. Pharm. 165, 1617–1643 (2012).
Bortolato, A. et al. Structure of class B GPCRs: new horizons for drug discovery. Br. J. Pharm. 171, 3132–3145 (2014).
Gardella, T. J. & Vilardaga, J.-P. International Union of Basic and Clinical Pharmacology. XCIII. The parathyroid hormone receptors—family B G protein-coupled receptors. Pharm. Rev. 67, 310–337 (2015).
de Graaf, C. et al. Extending the structural view of class B GPCRs. Trends Biochem Sci. 42, 946–960 (2017).
Ingram, J. R., Schmidt, F. I. & Ploegh, H. L. Exploiting nanobodies’ singular traits. Annu Rev. Immunol. 36, 695–715 (2018).
Koehl, A. et al. Structural insights into the activation of metabotropic glutamate receptors. Nature 566, 79 (2019).
Konning, D. et al. Camelid and shark single domain antibodies: structural features and therapeutic potential. Curr. Opin. Struct. Biol. 45, 10–16 (2017).
Ehrenmann, J. et al. High-resolution crystal structure of parathyroid hormone 1 receptor in complex with a peptide agonist. Nat. Struct. Mol. Biol. 25, 1086–+ (2018).
Zhao, L. H. et al. Structure and dynamics of the active human parathyroid hormone receptor-1. Science 364, 148–+ (2019).
Guimaraes, C. P. et al. Site-specific C-terminal internal loop labeling of proteins using sortase-mediated reactions. Nat. Protoc. 8, 1787–1799 (2013).
Cheloha, R. W., Gellman, S. H., Vilardaga, J.-P. & Gardella, T. J. PTH receptor-1 signalling[mdash]mechanistic insights and therapeutic prospects. Nat. Rev. Endocrinol. 11, 712–724 (2015).
Pioszak, A. A. & Xu, H. E. Molecular recognition of parathyroid hormone by its G protein-coupled receptor. Proc. Natl Acad. Sci. USA 105, 5034–5039 (2008).
Lee, C. W. et al. Role of the extracellular regions of the parathyroid-hormone (PTH) PTH-related peptide receptor in hormone-binding. Endocrinology 135, 1488–1495 (1994).
Mahon, M. J. pHluorin2: an enhanced, ratiometric, pH-sensitive green florescent protein. Adv. Biosci. Biotechnol. 2, 132–137 (2011).
Ling, J. et al. A nanobody that recognizes a 14-residue peptide epitope in the E2 ubiquitin-conjugating enzyme UBC6e modulates its activity. Mol. Immunol. 14, 513–523 (2019).
Carter, P. H. et al. Actions of the small molecule ligands SW106 and AH-3960 on the type-1 parathyroid hormone receptor. Mol. Endocrinol. 29, 307–321 (2015).
Kirchhofer, A. et al. Modulation of protein properties in living cells using nanobodies. Nat. Struct. Mol. Biol. 17, 133–U162 (2010).
Adams, H., Saunders, M. J. S. & De Haard, J. J. W. Amino acid sequences directed against GPCRs and polypeptides comprising the same for the treatment of GPCR-related diseases and disorders. US patent US9512236B2 (2010).
Rashidian, M. et al. Noninvasive imaging of immune responses. Proc. Natl Acad. Sci. USA 112, 6146–6151 (2015).
Duarte, J. N. et al. Generation of immunity against pathogens via single-domain antibody-antigen constructs. J. Immunol. 197, 4838–4847 (2016).
Cheloha, R. W., Maeda, A., Dean, T., Gardella, T. J. & Gellman, S. H. Backbone modification of a polypeptide drug alters duration of action in vivo. Nat. Biotechnol. 32, 653–655 (2014).
Liu, S., Cheloha, R. W., Watanabe, T., Gardella, T. J. & Gellman, S. H. Receptor selectivity from minimal backbone modification of a polypeptide agonist. Proc. Natl Acad. Sci. USA 115, 12383–12388 (2018).
Ferrandon, S. et al. Sustained cyclic AMP production by parathyroid hormone receptor endocytosis. Nat. Chem. Biol. 5, 734–742 (2009).
Okazaki, M. et al. Prolonged signaling at the parathyroid hormone receptor by peptide ligands targeted to a specific receptor conformation. Proc. Natl Acad. Sci. USA 105, 16525–16530 (2008).
Binkowski, B. F. et al. A luminescent biosensor with increased dynamic range for intracellular cAMP. ACS Chem. Biol. 6, 1193–1197 (2011).
Rabbani, S. A. et al. Recombinant human parathyroid-hormone synthesized in Escherichia coli. Purification and characterization. J. Biol. Chem. 263, 1307–1313 (1988).
Cheloha, R. W. et al. Development of potent, protease-resistant agonists of the parathyroid hormone receptor with broad beta residue distribution. J. Med. Chem. 60, 8816–8833 (2017).
Wootten, D., Christopoulos, A., Marti-Solano, M., Babu, M. M. & Sexton, P. M. Mechanisms of signalling and biased agonism in G protein-coupled receptors. Nat. Rev. Mol. Cell Biol. 19, 638–653 (2018).
Cupp, M. E., Nayak, S. K., Adem, A. S. & Thomsen, W. J. Parathyroid hormone (PTH) and PTH-related peptide domains contributing to activation of different PTH receptor-mediated signaling pathways. J. Pharm. Exp. Ther. 345, 404–418 (2013).
Neri, D. Antibody-cytokine fusions: versatile products for the modulation of anticancer immunity. Cancer Immunol. Res. 7, 348–354 (2019).
Tzeng, A., Kwan, B. H., Opel, C. F., Navaratna, T. & Wittrup, K. D. Antigen specificity can be irrelevant to immunocytokine efficacy and biodistribution. Proc. Natl Acad. Sci. USA 112, 3320–3325 (2015).
Garcin, G. et al. High efficiency cell-specific targeting of cytokine activity. Nat. Commun. 5, https://doi.org/10.1038/ncomms4016 (2014).
Pogue, S. L. et al. Targeting attenuated interferon-alpha to myeloma cells with a CD38 antibody induces potent tumor regression with reduced off-target activity. PLoS ONE 11, https://doi.org/10.1371/journal.pone.0162472 (2016).
Farrants, H. et al. SNAP-tagged nanobodies enable reversible optical control of a G protein-coupled receptor via a remotely tethered photoswitchable ligand. ACS Chem. Biol. 13, 2682–2688 (2018).
Chodorge, M. et al. Engineering of a GLP-1 analogue peptide/anti-PCSK9 antibody fusion for type 2 diabetes treatment. Sci. Rep. 8, https://doi.org/10.1038/s41598-018-35869-4 (2018).
Shimizu, M., Carter, P. H. & Gardella, T. J. Autoactivation of type-1 parathyroid hormone receptors containing a tethered ligand. J. Biol. Chem. 275, 19456–19460 (2000).
Devigny, C. et al. Biomimetic screening of class-B G protein-coupled receptors. J. Am. Chem. Soc. 133, 8927–8933 (2011).
Urban, D. J. & Roth, B. L. DREADDs (designer receptors exclusively activated by designer drugs): chemogenetic tools with therapeutic utility. Annu Rev. Pharm. Toxicol. 55, 399–417 (2015).
Armbruster, B. N., Li, X., Pausch, M. H., Herlitze, S. & Roth, B. L. Evolving the lock to fit the key to create a family of G protein-coupled receptors potently activated by an inert ligand. Proc. Natl Acad. Sci. USA 104, 5163–5168 (2007).
Guettier, J. M. et al. A chemical-genetic approach to study G protein regulation of beta cell function in vivo. Proc. Natl Acad. Sci. USA 106, 19197–19202 (2009).
Sockolosky, J. T. et al. Selective targeting of engineered T cells using orthogonal IL-2 cytokine-receptor complexes. Science 359, 1037-+ (2018).
Alvarez-Curto, E. & Milligan, G. Defining the functional equivalence of wild-type and chemically engineered G protein-coupled receptors. Designer Receptors Exclusively Activated Designer Drugs 108, 1–28 (2015).
Maeda, A. et al. Critical role of parathyroid hormone (PTH) receptor-1 phosphorylation in regulating acute responses to PTH. Proc. Natl Acad. Sci. USA 110, 5864–5869 (2013).
Herenbrink, C. K. et al. The role of kinetic context in apparent biased agonism at GPCRs. Nat. Comm. 7, https://doi.org/10.1038/ncomms10842 (2016).
Wehbi, V. L. et al. Noncanonical GPCR signaling arising from a PTH receptor-arrestin-G beta gamma complex. Proc. Natl Acad. Sci. USA 110, 1530–1535 (2013).
Cheloha, R. W. et al. Internalization of influenza virus and cell surface proteins monitored by site-specific conjugation of protease-sensitive probes. ACS Chem. Biol. 14, 1836–1844 (2019).
Funding was provided by the National Institutes of Health grant numbers P01-DK011794 (T.J.G.), P30-AR066261 (T.J.G.), 1DP1AI150593 (H.L.P.) and R01-AI087879 (H.L.P.). R.W.C. is supported in part by funding from the Cancer Research Institute Irvington Postdoctoral Fellowship. A.W.W. is supported by the Arnold O. Beckman Postdoctoral Fellowship. We acknowledge Jean-Pierre Vilardaga at the University of Pittsburgh Medical Center for generously providing the plasmid for β-Arr2-YFP. We acknowledge Ashok Khatri at Massahusetts General Hospital for providing PTH(1-20)-fluorescein and PTH(1-34)-TMR conjugates. We acknowledge Thomas Dean at Massachusetts General Hospital for technical assistance with cell bioassays.
R.W.C., T.G., and H.L.P. have filed a patent (U.S. Provisional Application Serial No. 62/814,096) covering the use of V.H.H. fusions for targeting GPCRs. F.A.F., A.W.W., E.D., and N.S. declare no competing interests.
Peer review information Nature Communications thanks Friedrich Koch-Nolte, Martine Smit and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Peer reviewer reports are available.
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Cheloha, R.W., Fischer, F.A., Woodham, A.W. et al. Improved GPCR ligands from nanobody tethering. Nat Commun 11, 2087 (2020). https://doi.org/10.1038/s41467-020-15884-8
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