The methyl 13C-edited/13C-filtered transferred NOE for studying protein interactions with short linear motifs.

Many proteins interact with their ligand proteins by recognition of short linear motifs that are often intrinsically disordered. These interactions are usually weak and are characterized by fast exchange. NMR spectroscopy is a powerful tool to study weak interactions. The methods that have been commonly used are analysis of chemicals shift perturbations (CSP) upon ligand binding and saturation transfer difference spectroscopy. These two methods identify residues at the binding interface between the protein and its ligand. In the present study, we used a combination of transferred-NOE, specific methyl-labeling and an optimized isotope-edited/isotope-filtered NOESY experiment to study specific interactions between the 42 kDa p38α mitogen-activated protein kinase and the kinase interaction motif (KIM) on the STEP phosphatase. These measurements distinguished between residues that both exhibit CSPs upon ligand binding and interact with the KIM peptide from residues that exhibit CSPs but do not interact with the peptide. In addition, these results provide information about pairwise interactions that is important for a more reliable docking of the KIM peptide into its interacting surface on p38α. This combination of techniques should be applicable for many protein-peptide complexes up to 80 kDa for which methyl resonance assignment can be achieved.

The chemokines CCL5 and CXCL12 exhibit high-affinity binding to N-terminal peptides of the non-cognate receptors CXCR4 and CCR5, respectively.

CC and CXC chemokines are distinct chemokine subfamilies. CC chemokines usually do not bind CXC-chemokine receptors and vice versa. CCR5 and CXCR4 receptors are activated by CCL5 and CXCL12 chemokines, respectively, and are also used as HIV-1 coreceptors. CCL5 contains one conserved binding site for a sulfated tyrosine residue, whereas CXCL12 is unique in having two additional sites for sulfated/nonsulfated tyrosine residues. In this study, N-terminal (Nt) CXCR4 peptides were found to bind CCL5 with somewhat higher affinities in comparison to those of short Nt-CCR5(8-20) peptides with the same number of sulfated tyrosine residues. Similarly, a long Nt-CCR5(1-27)(s Y3,s Y10,s Y14) peptide cross reacts with CXCL12 and with lower KD in comparison to its binding to CCL5. Intermolecular nuclear overhauser effect (NOE) measurements were used to decipher the mechanism of the chemokine/Nt-receptor peptide binding. The Nt-CXCR4 peptides interact with the conserved CCL5 tyrosine sulfate-binding site by an allovalency mechanism like that observed for CCL5 binding of Nt-CCR5 peptides. Nt-CCR5 peptides bind CXCL12 in multiple modes analogous to their binding to HIV-1 gp120 and interact with all three tyrosine/sulfated tyrosine-binding pockets of CXCL12. We suggest that the chemokine-receptors Nt-segments bind promiscuously to cognate and non-cognate chemokines and in a mechanism that is dependent on the number of binding pockets for tyrosine residues found on the chemokine. In conclusion, common features shared among the chemokine-receptors' Nt-segments such as multiple tyrosine residues that are potentially sulfated, and a large number of negatively charged residues are the reason of the cross binding observed in this study.

Multiple binding modes of an N-terminal CCR5-peptide in complex with HIV-1 gp120.

The N-terminal segment of CCR5 contains four tyrosine residues, sulphation of two of which is essential for high-affinity binding to gp120. In the present study, the interactions of gp120YU2 with a 27-residue N-terminal CCR5 peptide sulphated at position Y10 and Y14, i.e. Nt-CCR5, were studied using 13 C-edited-HMQC methyl-NOESY [1 H(13 C)-1 H], combined with transferred NOE NMR spectroscopy. A large number of pairwise interactions were observed between the methyl protons of methionine, threonine, valine and isoleucine residues of gp120, and the aromatic tyrosine-protons of Nt-CCR5. M434, V120 and V200 of gp120 were found to interact with all four tyrosine residues, Y3, sY10, sY14 and Y15. Particularly intriguing was the observation that Y3 and Y15 interact with the same gp120 methyl protons. Such interactions cannot be explained by the single cryo-EM structure of gp120/CD4/CCR5 complex published recently (Nature, 565, 318-323, 2019). Rather, they are consistent with the existence of a dynamic equilibrium involving two or more binding modes of Nt-CCR5 to gp120. These different modes of binding can coexist because the surface of gp120 contains two sites that can optimally interact with a sulphated tyrosine residue and two sites that can interact favorably with a non-sulphated tyrosine residue. Modelling of gp120YU2 complexed with the Nt-CCR5 peptide or with the entire CCR5 receptor provides an explanation for the NMR observations and the existence of these different binding modes of the disordered N-terminus of CCR5. The data presented extend our understanding of the two-step model and suggest a more variable binding mode of Nt-CCR5 with gp120.

Observation of intermolecular interactions in large protein complexes by 2D-double difference nuclear Overhauser enhancement spectroscopy: application to the 44 kDa interferon-receptor complex.

NMR detection of intermolecular interactions between protons in large protein complexes is very challenging because it is difficult to distinguish between weak NOEs from intermolecular interactions and the much larger number of strong intramolecular NOEs. This challenging task is exacerbated by the decrease in signal-to-noise ratio in the often used isotope-edited and isotope-filtered experiments as a result of enhanced T(2) relaxation. Here, we calculate a double difference spectrum that shows exclusively intermolecular NOEs and manifests the good signal-to-noise ratio in 2D homonuclear NOESY spectra even for large proteins. The method is straightforward and results in a complete picture of all intermolecular interactions involving non exchangeable protons. Ninety-seven such (1)H-(1)H NOEs were assigned for the 44 KDa interferon-α2/IFNAR2 complex and used for docking these two proteins. The symmetry of the difference spectrum, its superb resolution, and unprecedented signal-to-noise ratio in this large protein/receptor complex suggest that this method is generally applicable to study large biopolymeric complexes.

Allovalency observed by transferred NOE: interactions of sulfated tyrosine residues in the N-terminal segment of CCR5 with the CCL5 chemokine.

The N-terminal segment of the chemokine receptor Human CC chemokine receptor 5 (CCR5), Nt-CCR5, contains four tyrosine residues, Y3, Y10, Y14, and Y15. Sulfation of at least two of these tyrosine residues was found to be essential for high-affinity binding of CCR5 to its chemokine ligands. Here, we show that among the monosulfated Nt-CCR5(8-20) peptide surrogates (sNt-CCR5) those sulfated at Y15 and Y14 have the highest affinity for the CC chemokine ligand 5 (CCL5) chemokine in comparison with monosulfation at position Y10. Sulfation at Y3 was not investigated. A peptide sulfated at both Y14 and Y15 has the highest affinity for CCL5 by up to a factor of 3, in comparison with the other disulfated (sNt-CCR5) peptides. Chemical shift perturbation analysis and transferred nuclear Overhauser effect measurements indicate that the sulfated tyrosine residues interact with the same CCL5-binding pocket and that each of the sulfated tyrosines at positions 10, 14, and 15 can occupy individually the binding site on CCL5 in a similar manner, although with somewhat different affinity, suggesting the possibility of allovalency in sulfated Nt-CCR5 peptides. The affinity of the disulfated peptides to CCL5 could be increased by this allovalency and by stronger electrostatic interactions.

NMR mapping of the IFNAR1-EC binding site on IFNalpha2 reveals allosteric changes in the IFNAR2-EC binding site.

All type I interferons (IFNs) bind to a common cell-surface receptor consisting of two subunits. IFNs initiate intracellular signal transduction cascades by simultaneous interaction with the extracellular domains of its receptor subunits, IFNAR1 and IFNAR2. In this study, we mapped the surface of IFNalpha2 interacting with the extracellular domain of IFNAR1 (IFNAR1-EC) by following changes in or the disappearance of the (1)H-(15)N TROSY-HSQC cross peaks of IFNalpha2 caused by the binding of the extracellular domain of IFNAR1 (IFNAR1-EC) to the binary complex of IFNalpha2 with IFNAR2-EC. The NMR study of the 89 kDa complex was conducted at pH 8 and 308 K using an 800 MHz spectrometer. IFNAR1 binding affected a total of 47 of 165 IFNalpha2 residues contained in two large patches on the face of the protein opposing the binding site for IFNAR2 and in a third patch located on the face containing the IFNAR2 binding site. The first two patches form the IFNAR1 binding site, and one of these matches the IFNAR1 binding site previously identified by site-directed mutagenesis. The third patch partially matches the IFNalpha2 binding site for IFNAR2-EC, indicating allosteric communication between the binding sites for the two receptor subunits.

Intermolecular interactions in a 44 kDa interferon-receptor complex detected by asymmetric reverse-protonation and two-dimensional NOESY.

Type I interferons (IFNs) make up a family of homologous helical cytokines initiating strong antiviral and antiproliferative activity. All type I IFNs bind to a common cell surface receptor consisting of two subunits, IFNAR1 and IFNAR2, associating upon binding of interferon. We studied intermolecular interactions between IFNAR2-EC and IFNalpha2 using asymmetric reverse-protonation of the different complex components and two-dimensional homonuclear NOESY. This new approach revealed with an excellent signal-to-noise ratio 24 new intermolecular NOEs between the two molecules despite the low concentration of the complex (0.25 mM) and its high molecular mass (44 kDa). Sequential and side chain assignment of IFNAR2-EC and IFNalpha2 in their binary complex helped assign the intermolecular NOEs to the corresponding protons. A docking model of the IFNAR2-EC-IFNalpha2 complex was calculated on the basis of the intermolecular interactions found in this study as well as four double mutant cycle constraints, previously observed NOEs between a single pair of residues and the NMR mapping of the binding sites on IFNAR2-EC and IFNalpha2. Our docking model doubles the buried surface area of the previous model and significantly increases the number of intermolecular hydrogen bonds, salt bridges, and van der Waals interactions. Furthermore, our model reveals the participation of several new regions in the binding site such as the N-terminus and A helix of IFNalpha2 and the C domain of IFNAR2-EC. As a result of these additions, the orientation of IFNAR2-EC relative to IFNalpha2 has changed by 30 degrees in comparison with a previously calculated model that was based on NMR mapping of the binding sites and double mutant cycle constraints. In addition, the new model strongly supports the recently proposed allosteric changes in IFNalpha2 upon binding of IFNAR1-EC to the binary IFNalpha2-IFNAR2-EC complex.

HIV-1 peptide vaccine candidates: selecting constrained V3 peptides with highest affinity to antibody 447-52D.

The V3 region of the envelope glycoprotein gp120 of the human immunodeficiency virus type 1 (HIV-1) is a potential target for an anti-HIV-1 vaccine. Peptides corresponding to V3 form three variations of a beta-hairpin conformation when bound to anti-V3 HIV-1 neutralizing antibodies. The conformation of a V3(IIIB) peptide bound to the 0.5beta antibody, generated against an X4 gp120, has been postulated to represent the V3 conformation of X4 viruses while the conformations of a V3(MN) and a V3(CONSENSUS) peptide bound to the 447-52D human monoclonal antibody were postulated to represent the R5A and R5B V3 conformations of R5 viruses, respectively. To constrain the conformation of synthetic V3 peptides to these X4, R5A, and R5B conformations, we formed disulfide bonds between Cys residues whose location in a peptide template representing the entire V3(CONSENSUS) epitope recognized by the broadly neutralizing 447-52D antibody was changed systematically. In a previous study [Mor, A., et al. (2009) Biochemistry 48, 3288-3303] we showed that these constrained peptides adopted conformations resembling the three antibody-bound V3 conformations according to the location of the disulfide bonds. Here we show that these constrained peptides, with the exception of peptides in which the disulfide bond flanks the GPGR segment, retain high-affinity binding to the 447-52D antibody. Compared with peptides designed to mimic the X4 conformation, peptides designed to mimic either the R5A or R5B conformation had higher affinity to 447-52D. It is possible that constrained peptides which mimic the R5A and R5B conformations of the V3 and retain high-affinity binding to 447-52D are good candidates for eliciting a broad neutralizing antibody response similar to that of 447-52D.

Mimicking the structure of the V3 epitope bound to HIV-1 neutralizing antibodies.

The third variable region (V3) of the HIV-1 envelope glycoprotein gp120 is a target for virus neutralizing antibodies. The V3 sequence determines whether the virus will manifest R5 or X4 phenotypes and use the CCR5 or CXCR4 chemokine coreceptor, respectively. Previous NMR studies revealed that both R5- and X4-V3 peptides bound to antibodies 0.5beta and 447-52D form beta-hairpin conformations with the GPGR segment at the turn. In contrast, in their free form, linear V3 peptides and a cyclic peptide consisting of the entire 35-residue V3 loop were highly unstructured in aqueous solution. Herein we evaluated a series of synthetic disulfide constrained V3-peptides in which the position of the disulfide bonds, and therefore the ring size, was systematically varied. NMR structures determined for singly and doubly disulfide constrained V3-peptides in aqueous solution were compared with those found for unconstrained V3(JRFL) and V3(IIIB) peptides bound to 447-52D and to 0.5beta, respectively. Our study indicated that cyclic V3 peptides manifested significantly reduced conformational space compared to their linear homologues and that in all cases cyclic peptides exhibited cross-strand interactions suggestive of beta-hairpin-like structures. Nevertheless, the singly constrained V3-peptides retained significant flexibility and did not form an idealized beta-hairpin. Incorporation of a second disulfide bond results in significant overall rigidity, and in one case, a structure close to that of V3(MN) peptide bound to 447-52D Fab was assumed and in another case a structure close to that formed by the linear V3(IIIB) peptide bound to antibody 0.5beta was assumed.

Epitope mapping of antibody-antigen complexes by nuclear magnetic resonance spectroscopy.

Nuclear magnetic resonance (NMR) is a very powerful tool for determining the boundaries of peptide epitopes recognized by antibodies. NMR can be used to study antibodies in complexes that exhibit a wide range of binding affinities from very weak and transient to very tight. Choice of the specific method depends upon the dissociation constant, especially the ligand off-rate.Epitope mapping by NMR is based on the difference in mobility between the amino acid residues of a peptide antigen that interact tightly with the antibody and residues outside the epitope that do not interact with the antibody. The interacting peptide residues become considerably immobilized upon binding. Their mobility will resemble that of the antibody's residues. Several NMR methods were developed based on these characteristics. In this chapter we discuss some of these methods, including dynamic filtering, comparison of (1)H-(15)N HSQC peaks' intensities, transverse relaxation time, measurements of (1)H-(15)N nuclear Overhauser effect (NOE) values, and measurements of T (1rho) relaxation time.

The mechanism for acetylcholine receptor inhibition by alpha-neurotoxins and species-specific resistance to alpha-bungarotoxin revealed by NMR.

The structure of a peptide corresponding to residues 182-202 of the acetylcholine receptor alpha1 subunit in complex with alpha-bungarotoxin was solved using NMR spectroscopy. The peptide contains the complete sequence of the major determinant of AChR involved in alpha-bungarotoxin binding. One face of the long beta hairpin formed by the AChR peptide consists of exposed nonconserved residues, which interact extensively with the toxin. Mutations of these receptor residues confer resistance to the toxin. Conserved AChR residues form the opposite face of the beta hairpin, which creates the inner and partially hidden pocket for acetylcholine. An NMR-derived model for the receptor complex with two alpha-bungarotoxin molecules shows that this pocket is occupied by the conserved alpha-neurotoxin residue R36, which forms cation-pi interactions with both alphaW149 and gammaW55/deltaW57 of the receptor and mimics acetylcholine.

The membrane proximal external region of the HIV-1 envelope glycoprotein gp41 contributes to the stabilization of the six-helix bundle formed with a matching N' peptide.

The HIV-1 envelope glycoprotein gp41 undergoes a sequence of extensive conformational changes while participating in the fusion of the virus with the host cell. Since the discovery of its postfusion conformation, the structure and function of the protease-resistant six-helix bundle (6-HB) have been the subject of extensive investigation. In this work, we describe additional determinants (S528-Q540 and W666-N677) in the fusion peptide proximal region (FP-PR) and the membrane proximal external region (MPER) that stabilize the six-helix bundle and are involved in the interaction of T-20 (FUZEON, an anti-HIV-1 fusion inhibitor drug) with the gp41 FP-PR. Circular dichroism and sedimentation equilibrium measurements indicate that the 1:1 mixture of N' and C' peptides comprising residues A541-T569 and I635-K665 from the gp41 first and second helical repeats, HR1 and HR2, respectively, fail to form a stable six-helix bundle. Triglutamic acid and triarginine tags were added to these N' and C' peptides, respectively, at the termini distant from the FP-PR and the MPER to alter their pI and increase their solubility at pH 3.5. The tagged HR1 and HR2 peptides were elongated by addition of residues S528-Q540 from the FP-PR and residues W666-N677 from the MPER, respectively. A 1:1 complex of the elongated peptides formed a stable six-helix bundle which melted at 60 degrees C. These results underscore the importance of a detailed high-resolution characterization of MPER interactions, the results of which may improve our understanding of the structure-function relationship of gp41 and its role in HIV-1 fusion.

Correlated mutations at gp120 positions 322 and 440: implications for gp120 structure.

Analysis of V3 and C4 sequences of HIV-1 reveals correlated mutations at gp120 positions 322 and 440, and a very strong preference for a positively charged residue at position 440 when position 322 is negatively charged. This observation suggests that these two residues are close to each other and interact electrostatically in R5 viruses. This interaction was used to model V3 in the context of gp120 using NMR data for the V3 loop and the crystal structure of the gp120-core. The interaction between residues 322 and 440 may serve as part of the molecular switch for HIV-1 phenotype conversion.

The Synthesis of Sulfated CCR5 Peptide Surrogates and their Use to Study Receptor-Ligand Interactions.

BACKGROUND: Tyrosine sulfation is an important post-translational modification of secreted and membrane proteins in multi-cellular organisms. This modification is catalyzed by tyrosylprotein sulfotransferases that often modify tyrosine residues in their target substrates in a heterogeneous manner. Chemokine receptors such as CCR5, which play roles in inflammation, immunity and viral infection, are sulfated on tyrosine residues in their extracellular N-termini. The heterogeneity of the sulfation has made it difficult to obtain atomic-resolution information on this region of CCR5. Homogeneously sulfated peptide surrogates can be efficiently synthesized by chemical and biochemical approaches. This communication reviews current chemical and biochemical methods for peptide tyrosine sulfation and the use of N-terminal CCR5 peptide surrogates in biochemical and structural analyses. CONCLUSION: Using solid phase peptide synthesis and synthons containing sulfotyrosine or sulfotyrosine neopentyl esters peptides containing up to 30 residues with multiple sulfotyrosines can be synthesized and purified in high (>50-70%) yield. Such peptides can be isotopically labeled at selected positions and used in detailed NMR investigations to investigate the interactions of sulfotyrosine residues with receptors. The application of transferred NOE studies to investigate CCL5/CCR5 interactions has led to the determination of pairwise interactions between the chemokine and its receptor.

Defining specific residue-to-residue interactions between the gp120 bridging sheet and the N-terminal segment of CCR5: applications of transferred NOE NMR.

Infection by HIV-1 requires protein-protein interactions involving gp120, CD4 and CCR5. We have previously demonstrated that the transferred nuclear Overhauser effect (TRNOE), in combination with asymmetric deuteration of a protein and a peptide ligand can be used to detect intermolecular interactions in large protein complexes with molecular weights up to ~ 100 kDa. Here, using this approach, we reveal interactions between tyrosine residues of a 27-residue peptide corresponding to the N-terminal segment of the CCR5 chemokine receptor, and a dimeric extended core YU2 gp120 envelope protein of HIV-1 complexed with a CD4-mimic miniprotein. The TRNOE crosspeaks in the ternary complex were assigned to the specific Tyr protons in the CCR5 peptide and to methyl protons of isoleucine, leucine and/or valine residues of gp120. Site directed mutagenesis combined with selective deuteration and TRNOE resulted in the first discernment by a biophysical method of specific pairwise interactions between gp120 residues in the bridging sheet of gp120 and the N-terminus of CCR5.

The solution structure of monomeric CCL5 in complex with a doubly sulfated N-terminal segment of CCR5.

The inflammatory chemokine CCL5, which binds the chemokine receptor CCR5 in a two-step mechanism so as to activate signaling pathways in hematopoetic cells, plays an important role in immune surveillance, inflammation, and development as well as in several immune system pathologies. The recently published crystal structure of CCR5 bound to a high-affinity variant of CCL5 lacks the N-terminal segment of the receptor that is post-translationally sulfated and is known to be important for high-affinity binding. Here, we report the NMR solution structure of monomeric CCL5 bound to a synthetic doubly sulfated peptide corresponding to the missing first 27 residues of CCR5. Our structures show that two sulfated tyrosine residues, sY10 and sY14, as well as the unsulfated Y15 form a network of strong interactions with a groove on a surface of CCL5 that is formed from evolutionarily conserved basic and hydrophobic amino acids. We then use our NMR structures, in combination with available crystal data, to create an atomic model of full-length wild-type CCR5:CCL5. Our findings reveal the structural determinants involved in the recognition of CCL5 by the CCR5 N terminus. These findings, together with existing structural data, provide a complete structural framework with which to understand the specificity of receptor:chemokine interactions. DATABASE: Structural data are available in the PDB under the accession number 6FGP.

Detection of intermolecular transferred-NOE interactions in small and medium size protein complexes: RANTES complexed with a CCR5 N-terminal peptide.

NMR is a powerful tool for studying structural details of protein/peptide complexes exhibiting weak to medium binding (KD > 10 µm). However, it has been assumed that intermolecular nuclear Overhauser effect (NOE) interactions are difficult to observe in such complexes. We demonstrate that intermolecular NOEs can be revealed by combining the 13 C-edited/13 C-filtered experiment with the transferred NOE effect (TRNOE). Due to the TRNOE phenomenon, intermolecular NOE cross peaks are characterized by both the chemical shifts (CSs) of the protein protons and the average CSs of the peptide protons, which are dominated by the CSs of the protons of the free peptide. Previously, the TRNOE phenomenon was used almost exclusively to investigate the conformation of small ligands bound to large biomolecules. Here, we demonstrate that TRNOE can be extended to enable the study of intermolecular interactions in small- and medium-sized protein complexes. We used the 13 C-edited/13 C-filtered TRNOE experiment to study the interactions of the chemokine regulated upon activation, normal T cell, expressed and secreted (RANTES) with a 27-residue peptide, containing two sulfotyrosine residues, representing the N-terminal segment of the CCR5 receptor ((Nt-CCR5(1-27). The TRNOE phenomenon led to more than doubling of the signal-to-noise ratios (SNRs) for the intermolecular NOEs observed in the 13 C-edited/13 C-filtered experiment for the 11.5-kDa monomeric RANTES/Nt-CCR5(1-27) complex. An even better improvement in the SNR was achieved with dimeric Nt-CCR5(1-27)/RANTES (23 kDa), especially in comparison with the spectra measured with a 1 : 1 protein to peptide ratio. In principle, the isotope-edited/isotope-filtered TRNOE spectrum can discern all intermolecular interactions involving nonexchangeable protons in the complex.

Immunofocusing using conformationally constrained V3 peptide immunogens improves HIV-1 neutralization.

V3-directed antibodies are present in practically all HIV-1 infected patients and in individuals vaccinated with gp120. The levels of maternal V3-directed antibodies were recently shown to correlate with reduced mother to child transmission, and V3 IgGs were found to be a negative correlate of risk in the RV-144 human trial. mAb directed to the tip of the V3 are capable of broad neutralization of Tier-1 and some Tier-2 viruses. Here we report an immunofocusing approach using conformationally constrained V3 peptides of different lengths. Immunofocusing with short constrained V3 peptides following immunizations with long constrained V3 peptides resulted in sera with improved neutralization of Tier-1B viruses in comparison with immunizations with the long constrained peptide alone. Immunizations only with the short constrained peptide were ineffective. Our results demonstrate that immunofocusing with constrained V3 peptides of different lengths could improve the induction of HIV-1 neutralizing antibodies.

Determination of the human type I interferon receptor binding site on human interferon-alpha2 by cross saturation and an NMR-based model of the complex.

Type I interferons (IFNs) are a family of homologous helical cytokines that exhibit pleiotropic effects on a wide variety of cell types, including antiviral activity and antibacterial, antiprozoal, immunomodulatory, and cell growth regulatory functions. Consequently, IFNs are the human proteins most widely used in the treatment of several kinds of cancer, hepatitis C, and multiple sclerosis. All type I IFNs bind to a cell surface receptor consisting of two subunits, IFNAR1 and IFNAR2, associating upon binding of interferon. The structure of the extracellular domain of IFNAR2 (R2-EC) was solved recently. Here we study the complex and the binding interface of IFNalpha2 with R2-EC using multidimensional NMR techniques. NMR shows that IFNalpha2 does not undergo significant structural changes upon binding to its receptor, suggesting a lock-and-key mechanism for binding. Cross saturation experiments were used to determine the receptor binding site upon IFNalpha2. The NMR data and previously published mutagenesis data were used to derive a docking model of the complex with an RMSD of 1 Angstrom, and its well-defined orientation between IFNalpha2 and R2-EC and the structural quality greatly improve upon previously suggested models. The relative ligand-receptor orientation is believed to be important for interferon signaling and possibly one of the parameters that distinguish the different IFN I subtypes. This structural information provides important insight into interferon signaling processes and may allow improvement in the development of therapeutically used IFNs and IFN-like molecules.

The human type I interferon receptor: NMR structure reveals the molecular basis of ligand binding.

The potent antiviral and antiproliferative activities of human type I interferons (IFNs) are mediated by a single receptor comprising two subunits, IFNAR1 and IFNAR2. The structure of the IFNAR2 IFN binding ectodomain (IFNAR2-EC), the first helical cytokine receptor structure determined in solution, reveals the molecular basis for IFN binding. The atypical perpendicular orientation of its two fibronectin domains explains the lack of C domain involvement in ligand binding. A model of the IFNAR2-EC/IFNalpha2 complex based on double mutant cycle-derived constraints uncovers an extensive and predominantly aliphatic hydrophobic patch on the receptor that interacts with a matching hydrophobic surface of IFNalpha2. An adjacent motif of alternating charged side chains guides the two proteins into a tight complex. The binding interface may account for crossreactivity and ligand specificity of the receptor. This molecular description of IFN binding should be invaluable for study and design of IFN-based biomedical agents.