Dear Editor,
Herpesviruses encode G protein-coupled receptors (GPCRs) in their viral genomes and express these receptors in infected host cells to reprogram cell signaling networks of the host for survival, replication and pathogenesis. As a ubiquitous herpesvirus with a seroprevalence of more than 50% in adults, human cytomegalovirus (HCMV) encodes four viral GPCRs (vGPCRs) including US27, US28, UL33 and UL78. The first three show about 30% homology to chemokine receptors (e.g., CXCR3, CX3CR1, CCR10 and CXCR1)1, whereas UL78 displays negligible homology to any endogenous receptors (Supplementary Figs. S1, S2)2. US28 is not only constitutively active but also capable of silencing the signal transduction of chemokine receptors by binding to various chemokines and promiscuously coupling to G proteins3. Meanwhile, four X-ray and three cryo-electron microscopy (cryo-EM) structures have been determined for US28 in the presence of either structural ligand (CX3CL3 or CX3CL1.35), intracellular binder (nanobody or G protein) or both; all of them adopt active or active-like conformations (Supplementary Table S1)4,5. While previous studies suggest that US27, UL33 and UL78 regulate viral replication or reactivation, there is no existing evidence demonstrating their interactions with chemokines; thus, they are classified as orphan receptors5,6. Among the two reported cryo-EM structures, US27 has an occluded ligand-binding pocket and captures a guanosine diphosphate-bound inactive Gi (Supplementary Table S1)5. Similarly, the inhibitory G protein (Gi)-coupled Epstein-Barr virus (EBV)-encoded GPCR (BILF1) was found to adopt an occluded extracellular surface to block the typical chemokine-binding site7.
Besides the traditional vGPCR-mediated signaling paradigms including ligand-dependent signaling through a ligand−receptor−effector complex (as seen in US28) or ligand-independent, constitutive signaling via a receptor−effector complex (observed in US27 and BILF1), receptor hetero- or homo-oligomerization has gained increasing experimental supports4,8. Notably, UL78 and UL33 can either form heterodimers with human CXCR4 and CCR5 interrupting normal signaling, or present oligomers to modulate the functions of other vGPCRs and host GPCRs9. Moreover, several chemokine receptors exhibit features of dimerization and higher order oligomerization9,10,11. Atomic visualization of GPCR oligomerization has been achieved mainly in classes C and D1 GPCR dimers, except one class A GPCR (apelin receptor) dimer12. In this study, we report the cryo-EM structure of UL78 and unveil a novel form of GPCR oligomerization unseen before — a homotrimeric architecture, thereby broadening our knowledge about GPCR structures.
To determine the cryo-EM structure of UL78, we followed the protocols previously adopted in solving the structures of US27 and BILF15,7, wherein the receptor was co-expressed with Gi protein, and the formation of the UL78−Gi complex was confirmed by size exclusion chromatography and SDS-PAGE. However, only a small fraction of the complex particles appeared in 2D classification (Fig. 1a; Supplementary Fig. S3a), and most of them were observed with a clear trimeric architecture, unaffected by the absence of Gi protein or the fused LgBiT (Supplementary Fig. S3b, c). When the receptor was expressed solely, only the trimeric form rather than monomer was detected in non-denaturing gel (Supplementary Fig. S3c). After sample preparation, cryo-EM data collection and single-particle analysis, a 3D consensus density map was reconstructed with a global resolution of 3.12 Å (Fig. 1b; Supplementary Fig. S4), enabling model building for all seven transmembrane helices (TMs), three intracellular loops (ICLs) and extracellular loops (ECLs) 1 and 2 (Supplementary Fig. S5 and Table S2).
The overall structure of UL78 comprises a homotrimer along the 3-fold symmetry axis with each protomer closely interacting with the other two (Fig. 1c). Three protomer structures share a highly conserved conformation with Cα root mean square deviation (RMSD) values of 0.50–0.56 Å and adopt a unique conformation that distinct from both active and inactive CXCR3 structures (Cα RMSD values of 1.06 Å and 1.28 Å, respectively) (Supplementary Fig. S6).
Specifically, the inward movements (10.0 Å and 13.1 Å) of ICL2 and the intracellular end of TM7 fulfill the receptor intracellular crevice (Fig. 1d), thereby hindering the insertion of the C-terminus of Gαi (Fig. 1e–h). This intracellular closure is achieved by various interactions, including D133TM3−R134TM3−E148ICL2 salt bridges, D143ICL2−R301H8 salt bridge, R69ICL1−W145ICL2−H146ICL2−H147ICL2−R142ICL2 stackings, F127TM3−F239TM6−Y240TM6−F294TM7−F298TM7 stackings and I138TM3−V229TM6 hydrophobic contacts (Fig. 1f). Consistently, alanine mutations at D133ICL2, R134ICL2, D143ICL2 and R301H8 decreased the bimolecular fluorescence complementation (BiFC)−bioluminescence resonance energy transfer (BRET)-measured trimer formation by 66%, 78%, 96% and 68%, respectively, while replacement of UL78 ICL2 by those of US28 and US27 caused notable reduction in BRET signal by 41% and 72%, respectively, indicating a unique conformation of ICL2 favoring the UL78 trimer formation (Fig. 1h). By comparison, the inactive CXCR3 and many other class A GPCRs prefer the intracellular part of TM6 to tightly pack TM3 and then move outward to accommodate G protein binding (Fig. 1d, e).
Looking at the extracellular side, the top of orthosteric ligand-binding pocket was significantly covered by the inward-folded ECL2, while the latter forms many polar contacts with the surrounding TMs (Fig. 1g; Supplementary Fig. S7). A series of charged residues (R183ECL2, D274TM7, R257TM6, E277TM7 and R254TM6) along with polar residues including Q188ECL2 and Y250TM6, contribute profound interactions to stabilize the ECL2 coverage. Additionally, the orthosteric ligand-binding pocket was narrowed by two inter-TM residue pairs, including S95 in TM2 and R281 in TM7 via one hydrogen bond, and D117 and Y121 in TM3 and D197 and K201 in TM5 via multiple polar contacts. Two mutations (R257TM6D and R281TM7A) decreased the trimer formation by ~65% and 85%, respectively (Fig. 1h). Despite the same β-hairpin conformation, ECL2 of UL78 differs from those of CXCR3 and US28 in both apo and chemokine-binding states (Supplementary Fig. S7), whose extracellular vestibules are open and accessible for chemokine recognition. Although the ECL2 of BILF1 and US27 also forms a lid that caps the chemokine-binding pocket, the extracellular architecture of UL78 is more compact, and lacks the participation of ECL3 or interaction with the N-terminus (Supplementary Fig. S7). These structural features highlight a unique extracellular conformation of UL78.
UL78 forms a stable homotrimeric architecture through an extensive interface covering TMs 3–6, ICL1 and ICL2 with a large interface area (7956 Å2) (Fig. 1i–k; Supplementary Fig. S8). A central triangle in the trimer was formed by the tightly packed TM5 from three protomers, while the extracellular and intracellular halves of TM5 were further clasped by TM4 and TM3 from one neighboring protomer, respectively (Fig. 1j; Supplementary Fig. S9). Additionally, TM6 stacks in parallel with TM4 from the adjacent protomer. To stabilize the trimer interface, the extracellular segments of TMs made massive hydrophobic and stacking interactions especially through six adjacent aromatic residues (W203TM5−F204TM5 from three protomers) (Fig. 1i, j). In comparison, polar interactions were more dominant in the intracellular bottom of the trimer interface, where R142ICL2 has one salt bridge with D224ICL3 of the adjacent protomer, R225ICL3 forms two salt bridges with the downward E219TM5 and one hydrogen bond with S223TM5, while Y222TM5 penetrates into the TM3−TM4 cleft of the adjacent protomer forming two hydrogen bonds with D133TM3 and E148ICL2 (Fig. 1j). These observations are consistent with the BiFC−BRET assay results showing that R142ICL2A, E219TM5A, W203TM5A, Y222TM5A, D224ICL3A and R225ICL3A decreased the trimer formation by 98%, 76%, 54%, 80%, 44% and 51%, respectively (Fig. 1h). Such a unique homotrimeric architecture of UL78 employs a maximal number of residues (68 positions) and four TMs to construct the largest transmembrane domain (TMD) interface area per protomer (2680 Å2) among these reported GPCR structures12,13,14, including active and inactive Ste2 (fungal class D1 GPCR), classes A and C GPCRs (Fig. 1k, l).
Taken together, using cryo-EM and available structures, we have discovered a homotrimeric architecture of GPCR. The homotrimeric interface of UL78 differs significantly from all reported GPCR homodimer or heterodimer structures and illuminates a new and most compact TMD packing arrangement. Meanwhile, the special conformations of UL78 at both intracellular and extracellular sides may occupy the orthosteric pocket and impede the access of signaling proteins, supporting the hypothesis that UL78 is not a conventional ‘orphan’ receptor and acts via receptor oligomerization. Considering its trafficking between cell surface and cytoplasm15 and its ability to heterodimerize with US28, CCR5 and CXCR4, both structural and functional studies on the heteromeric UL78 with US28/CCR5/CXCR4 in the presence or absence of G proteins are worth pursuing9. Clearly, further exploration of the physiological significance of our discovery could expand the knowledge about GPCR biology.
Data availability
The atomic coordinates and the electron microscopy maps of the UL78 trimer have been deposited in the Protein Data Bank (PDB) under accession code 8Z1E, and Electron Microscopy Data Bank (EMDB) under accession code EMD-39724.
References
Vischer, H. F. et al. Trends Pharm. Sci. 27, 56–63 (2006).
Rosenkilde, M. M. et al. Annu. Rev. Virol. 9, 329–351 (2022).
Vischer, H. F. et al. Nat. Rev. Drug Discov. 13, 123–139 (2014).
Burg, J. S. et al. Science 347, 1113–1117 (2015).
Tsutsumi, N. et al. Sci. Adv. 8, eabl5442 (2022).
van Senten, J. R. et al. Pharm. Res. 156, 104804 (2020).
Tsutsumi, N. et al. Immunity 54, 1405–1416 (2021).
Tschische, P. et al. Biochem. Pharm. 82, 610–619 (2011).
Tadagaki, K. et al. Blood 119, 4908–4918 (2012).
Hamatake, M. et al. Cancer Sci. 100, 95–102 (2009).
Di Marino, D. et al. Nat. Commun. 14, 6439 (2023).
Yue, Y. et al. Nat. Struct. Mol. Biol. 29, 688–697 (2022).
Velazhahan, V. et al. Nature 589, 148–153 (2020).
Lin, S. et al. Nature 594, 583–588 (2021).
Wagner, S. et al. Arch. Virol. 157, 935–949 (2012).
Acknowledgements
This work was partially supported by the National Natural Science Foundation of China (82273961, 82073904, 81872915 to M.-W.W., 82273985, 82121005, 81973373 to D.Y. and 32200576 to Z.C.); Postdoctoral Science Foundation of China (2022M710806 to Z.C.); Postdoctoral Innovative Talent Support Plan of China (BX20220070 to Z.C.); STI2030-Major Project (2021ZD0203400 to Q.Z.) and Hainan Provincial Major Science and Technology Project (ZDKJ2021028 to D.Y. and Q.Z.). The cryo-EM data were collected at the Cryo-Electron Microscopy Research Center, Shanghai Institute of Materia Medica, Chinese Academy of Sciences.
Author information
Authors and Affiliations
Contributions
Y.C., Y.L., Q.Z., Z.C. and S.L. performed research; Q.Z. conducted map calculation, built the model, and carried out structural analyses; X.C. and J.Y. assisted in protein purification; Y.C., Y.L., Q.Z., Z.C. and M.-W.W. analyzed the data and wrote the manuscript with inputs from all co-authors; M.-W.W., D.Y. and T.Y. initiated the project and supervised the studies.
Corresponding authors
Ethics declarations
Conflict of interest
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Chen, Y., Li, Y., Zhou, Q. et al. A homotrimeric GPCR architecture of the human cytomegalovirus revealed by cryo-EM. Cell Discov 10, 52 (2024). https://doi.org/10.1038/s41421-024-00684-x
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41421-024-00684-x