Abstract
The human MT1 and MT2 melatonin receptors1,2 are G-protein-coupled receptors (GPCRs) that help to regulate circadian rhythm and sleep patterns3. Drug development efforts have targeted both receptors for the treatment of insomnia, circadian rhythm and mood disorders, and cancer3, and MT2 has also been implicated in type 2 diabetes4,5. Here we report X-ray free electron laser (XFEL) structures of the human MT2 receptor in complex with the agonists 2-phenylmelatonin (2-PMT) and ramelteon6 at resolutions of 2.8 Å and 3.3 Å, respectively, along with two structures of function-related mutants: H2085.46A (superscripts represent the Ballesteros–Weinstein residue numbering nomenclature7) and N862.50D, obtained in complex with 2-PMT. Comparison of the structures of MT2 with a published structure8 of MT1 reveals that, despite conservation of the orthosteric ligand-binding site residues, there are notable conformational variations as well as differences in [3H]melatonin dissociation kinetics that provide insights into the selectivity between melatonin receptor subtypes. A membrane-buried lateral ligand entry channel is observed in both MT1 and MT2, but in addition the MT2 structures reveal a narrow opening towards the solvent in the extracellular part of the receptor. We provide functional and kinetic data that support a prominent role for intramembrane ligand entry in both receptors, and suggest that there might also be an extracellular entry path in MT2. Our findings contribute to a molecular understanding of melatonin receptor subtype selectivity and ligand access modes, which are essential for the design of highly selective melatonin tool compounds and therapeutic agents.
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Acknowledgements
We thank M. Chu, C. Hanson, K. Villers, and J. Velasquez for help with cloning and expression, T. Grant for XFEL data processing, and H. Shaye for technical support. This work was supported by the National Institutes of Health grants R35 GM127086 (V.C.), R21 DA042298 (W.L.), R01 GM124152 (W.L.), U24DK116195 (B.L.R.), R01MH112205 (B.L.R.), the NIMH Psychoactive Drug Screening Program and the Michael Hooker Distinguished Professorship to B.L.R. and F31-NS093917 (R.H.J.O.), the STC Program of the National Science Foundation (NSF) through BioXFEL (No. 1231306) (B.S., U.W., W.L., N.A.Z., V.C.), NSF ABI grant 1565180 (C.L, N.Z., U.W.), HFSP long-term fellowship LT000046/2014-L (L.C.J.), postdoctoral fellowship from the Swedish Research Council (L.C.J.) and EMBO ALTF 677-2014 (B.S.). Parts of this research were carried out at the LCLS, a National User Facility operated by Stanford University on behalf of the US Department of Energy and supported by the US Department of Energy Office of Science, Office of Basic Energy Sciences under Contract No. DE-AC02-76SF00515. This research benefited from the use of credits from the National Institutes of Health (NIH) Cloud Credits Model Pilot, a component of the NIH Big Data to Knowledge (BD2K) program.
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Nature thanks Christian Siebold, Ieva Sutkeviciute, Jean-Pierre Vilardaga and the other anonymous reviewer(s) for their contribution to the peer review of this work.
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L.C.J., B.S., V.K., and V.C. conceived the project, analysed data, and wrote the paper with contributions from all authors. L.C.J. and B.S. designed, optimized, purified and characterized receptor constructs for structural studies and crystallized the receptor, prepared crystal samples and figures, solved and refined the structures, and assisted in generating mutant constructs for binding and functional analyses. J.D.M., X.-P.H., and S.T.S. performed radioligand binding and functional experiments, assisted in making mutant and wild-type constructs, and analysed binding and functional data. L.C.J., B.S., A.B., L.Z., W.L., and V.C. collected XFEL data. S.Z. and U.W. operated the LCP injector during XFEL data collection. S.H., L.Z., and W.L. assisted in XFEL sample preparation. A.B., C.G., C.L., and N.A.Z. processed XFEL data. L.C.J., G.W.H. and A.B. determined the structures. L.C.J. and G.W.H. performed the structure refinement and quality control. N.P., J.M.G., and V.K. designed mutants for radioligand and functional studies, and performed molecular docking and molecular dynamics simulations. R.H.J.O. and A.R.T. assisted with molecular biology and functional experiments. S.Y. synthesized the bitopic compound, analysed data, and edited the paper. R.C.S. contributed to study design and selection of chemical compounds for receptor stabilization and functional characterization, supervised protein expression, and edited the paper. B.L.R. supervised pharmacological experiments and edited the paper. V.K. supervised molecular docking and molecular dynamics calculations. V.C. coordinated and supervised the whole project.
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Extended data figures and tables
Extended Data Fig. 1 Crystallization of MT2: crystals, crystal packing and electron density.
a, b, Bright field (a) and cross-polarized images (b) of representative MT2–2-PMT crystals optimized for synchrotron data collection (representing three independent crystallization setups). c, Cross-polarized image of representative MT2(N86D)–2-PMT crystals used for XFEL data collection (representing three independent crystallization setups). See Extended Data Table 2 for data collection statistics. d, e, Crystal packing (receptor, purple; BRIL, green; rubredoxin, blue). Space for missing rubredoxin in molecule B of the asymmetric unit is indicated with a red circle. Lattice rotated 90° is shown in e. f, Overlay of 2-PMT (purple) and ramelteon (blue) ligands of MT2. g–i, 2mFo – DFc density (grey) contoured at 1σ of ramelteon (g), N862.50D mutation (h), and H2085.46A mutation (i). 2-PMT is shown in purple.
Extended Data Fig. 2 Structural differences between MT1 and MT2.
a, Overlay of MT1–2-PMT (green) and MT2–2-PMT (violet) structures (Cα r.m.s.d = 0.6 Å). b, Comparison of MT1 (green) and MT2 (violet) binding pockets. Overall, the binding pocket in MT2 is about 50 Å3 larger than in MT1. c, Comparison of 2-PMT ligand conformations in MT1 (green) and MT2 (violet). Hydrogen bonds are shown as yellow dashed lines. d, Overlay of MT1 and MT2, showing residues with different conformations in the vicinity of the binding pocket. N4.60 makes a hydrogen bond with Y5.38 in MT2 but not in MT1.
Extended Data Fig. 3 Molecular dynamics simulations.
a, b, Distance plots for interactions between residues in MT2 (N1754.60, atom ND2; Q194ECL2, atom NE2; N2686.52, atom ND2), and closest oxygen atoms of the ligand methoxy and acetyl groups, respectively, in complexes with melatonin (a) and 2-PMT (b) from three independent simulation runs. c, Distance histograms for interactions of N1754.60 with methoxy of melatonin (yellow) and 2-PMT (violet). d, Distance histograms for interactions of Q194ECL2 with alkylamide tail of melatonin (yellow) and 2-PMT (violet).
Extended Data Fig. 4 Structural and functional differences between MT2–2-PMT and MT2(H208A5.46)–2-PMT.
a, Overlay of the MT2–2-PMT (purple) structure with that of MT2(H2085.46A)–2-PMT (grey) reveals an inward shift of helix V of about 0.9 Å, due to the H2085.46A mutation (black arrow). b, Surface representation of the H2085.46 and H2085.46A residues. Rotation of helix V renders the binding pocket volume about 50 Å3 smaller for the H2085.46A structure (binding site volume for MT2–2-PMT: 766 Å3 compared to 716 Å3 for the MT2(H2085.46A)–2-PMT structure). c, Comparison of the channel profiles (from the outside of the protein towards the ligand) for MT2–2-PMT (purple) and MT2(H2085.46A)–2-PMT (grey) reveals a narrowing of the MT2(H2085.46A)–2-PMT channel at a depth of around 6 Å as a consequence of the mutation and subsequent inward rotation of helix V. d, Functional data for wild-type and H2085.46A mutant MT2 expressed in HEK293T cells by using GloSensor to measure Gi/o-mediated inhibition of cAMP. Data represent mean ± s.e.m. for n independent experiments as indicated in square brackets. %EMAX (maximum effect of a drug) is relative to wild-type receptor (in columns), and %EMAX∗ is relative to melatonin activity (in rows). See Methods for further information and Supplementary Fig. 6 for dose–response curves.
Extended Data Fig. 5 Selectivity analysis of melatonergic compounds.
a, Binding affinities of ligands for MT1 (ChEMBL target identifier CHEMBL1945) and MT2 (CHEMBL1946) were retrieved from the ChEMBL database15 (v. 24) of experimental literature values. Of these ligands, 525 have affinities reported for both receptor subtypes. For ligands with multiple reported affinity values for a given receptor, pKi values were averaged. MT1-selective ligands are in the lower right quadrant; MT2-selective ligands are in the upper left quadrant. Data points are coloured by absolute pKi difference between subtypes (that is, selectivity). b, Histogram of observed ligand selectivities. MT2 selective ligands are on the left of the panel, MT1 selective ligands are on the right. c, Plot of the docking score difference of select ligands that were docked between MT2 and MT1 versus their pKi difference (MT2 – MT1). Dashed lines indicate pKi selectivity cutoff criteria (MT1: −1 and MT2: 4). Data points are coloured by molecular mass (Da). See Supplementary Table 1 for details of docked ligands.
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Supplementary Figures
This file contains Supplementary Figures 1-7.
Supplementary Table 1
A table of docked ligands plotted in Extended Data Fig. 5c. MW, molecular weight in Dalton (Da), pKi values in nM. Docking scores are expressed in arbitrary units.
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Johansson, L.C., Stauch, B., McCorvy, J.D. et al. XFEL structures of the human MT2 melatonin receptor reveal the basis of subtype selectivity. Nature 569, 289–292 (2019). https://doi.org/10.1038/s41586-019-1144-0
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DOI: https://doi.org/10.1038/s41586-019-1144-0
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