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.

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.

Secondary structure determination of conserved SARS-CoV-2 RNA elements by NMR spectroscopy.

The current pandemic situation caused by the Betacoronavirus SARS-CoV-2 (SCoV2) highlights the need for coordinated research to combat COVID-19. A particularly important aspect is the development of medication. In addition to viral proteins, structured RNA elements represent a potent alternative as drug targets. The search for drugs that target RNA requires their high-resolution structural characterization. Using nuclear magnetic resonance (NMR) spectroscopy, a worldwide consortium of NMR researchers aims to characterize potential RNA drug targets of SCoV2. Here, we report the characterization of 15 conserved RNA elements located at the 5' end, the ribosomal frameshift segment and the 3'-untranslated region (3'-UTR) of the SCoV2 genome, their large-scale production and NMR-based secondary structure determination. The NMR data are corroborated with secondary structure probing by DMS footprinting experiments. The close agreement of NMR secondary structure determination of isolated RNA elements with DMS footprinting and NMR performed on larger RNA regions shows that the secondary structure elements fold independently. The NMR data reported here provide the basis for NMR investigations of RNA function, RNA interactions with viral and host proteins and screening campaigns to identify potential RNA binders for pharmaceutical intervention.

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.

Modulation of RNA primer formation by Mn(II)-substituted T7 DNA primase.

Lagging strand DNA synthesis by DNA polymerase requires RNA primers produced by DNA primase. The N-terminal primase domain of the gene 4 protein of phage T7 comprises a zinc-binding domain that recognizes a specific DNA sequence and an RNA polymerase domain that catalyzes RNA polymerization. Based on its crystal structure, the RNA polymerase domain contains two Mg(II) ions. Mn(II) substitution leads to elevated RNA primer synthesis by T7 DNA primase. NMR analysis revealed that upon binding Mn(II), T7 DNA primase undergoes conformational changes near the metal cofactor binding site that are not observed when the enzyme binds Mg(II). A machine-learning algorithm called linear discriminant analysis (LDA) was trained by using the large collection of Mn(II) and Mg(II) binding sites available in the protein data bank (PDB). Application of the model to DNA primase revealed a preference in the enzyme's second metal binding site for Mn(II) over Mg(II), suggesting that T7 DNA primase activity modulation when bound to Mn(II) is based on structural changes in the enzyme.

Identification of DNA primase inhibitors via a combined fragment-based and virtual screening.

The structural differences between bacterial and human primases render the former an excellent target for drug design. Here we describe a technique for selecting small molecule inhibitors of the activity of T7 DNA primase, an ideal model for bacterial primases due to their common structural and functional features. Using NMR screening, fragment molecules that bind T7 primase were identified and then exploited in virtual filtration to select larger molecules from the ZINC database. The molecules were docked to the primase active site using the available primase crystal structure and ranked based on their predicted binding energies to identify the best candidates for functional and structural investigations. Biochemical assays revealed that some of the molecules inhibit T7 primase-dependent DNA replication. The binding mechanism was delineated via NMR spectroscopy. Our approach, which combines fragment based and virtual screening, is rapid and cost effective and can be applied to other targets.

Detection of intermolecular transferred NOEs in large protein complexes using asymmetric deuteration: HIV-1 gp120 in complex with a CCR5 peptide.

Weak protein-protein and protein-ligand interactions play important roles in biological recognition. In many cases, simplification of structural studies of large protein complexes is achieved by investigation of the interaction between the protein and a weakly binding segment of its protein ligand. Detection of pairwise interactions in such complexes is a major challenge for both X-ray crystallography and nuclear magnetic resonance. We demonstrate that 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. Using this approach, we revealed interactions between tyrosine residues of a 27-residue peptide (deuterated at Ile and Val residues) corresponding to the N-terminal segment of the human C-C chemokine receptor 5 (CCR5) chemokine receptor, and a 43 kDa construct of gp120 envelope protein of human immunodeficiency virus type 1 (deuterated on all aromatics) complexed with a cluster of differentiation 4-mimic miniprotein. The complex was present mostly as a dimer as determined by T2 relaxation measurements. The TRNOE crosspeaks in the ternary complex were assigned to the specific Tyr protons in the CCR5 peptide and to methyl protons, predominantly of isoleucine residues, and also of leucine and/or valine residues of gp120. The TRNOE/asymmetric deuteration method benefits from the sensitivity of the homonuclear NOESY experiment and does not suffer the sensitivity losses associated with isotope-edited/isotope-filtered approaches that rely on magnetization transfer between protons and heteronuclei that are bonded to them. The technique can be widely applied for studying large protein complexes that exhibit fast off-rates.

Human translation initiation factor eIF4G1 possesses a low-affinity ATP binding site facing the ATP-binding cleft of eIF4A in the eIF4G/eIF4A complex.

Eukaryotic translation initiation factor 4G (eIF4G) plays a crucial role in translation initiation, serving as a scaffolding protein binding several other initiation factors, other proteins, and RNA. Binding of eIF4G to the ATP-dependent RNA helicase eukaryotic translation initiation factor 4A (eIF4A) enhances the activity of eIF4A in solution and in crowded environments. Previously, this activity enhancement was solely attributed to eIF4G, conferring a closed, active conformation upon eIF4A. Here we show that eIF4G contains a low-affinity binding site at the entrance to the ATP-binding cleft on eIF4A, suggesting that regulation of the local ATP concentration may be an additional reason for the enhancement in activity.

Examining weak protein-protein interactions in start codon recognition via NMR spectroscopy.

Weak protein-protein interactions are critical in numerous biological processes. Unfortunately, they are difficult to characterize due to the high concentrations required for the production and detection of the complex population. The inherent sensitivity of NMR spectroscopy to the chemical environment makes it an excellent tool to tackle this problem. NMR permits the exploration of interactions over a range of affinities, yielding essential insights into dynamic biological processes. The conversion of messanger RNA to protein is one such process that requires the coordinated association of many low-affinity proteins. During start codon recognition, eukaryotic initiation factors assemble into high-order complexes that bind messanger RNA and bring it to the ribosome for decoding. Many of the structures of the eukaryotic initiation factors have been determined; however, little is known regarding the weak binary complexes formed and their structure-function mechanisms. Herein, we use start codon recognition as a model system to review the relevant NMR methods for the characterization of weak interactions and the development of small molecule inhibitors.

Backbone resonance assignment of the HEAT1-domain of the human eukaryotic translation initiation factor 4GI.

Controlling translation during protein synthesis is crucial for cell proliferation and differentiation. Protein translation is orchestrated by an assembly of various protein components at the ribosomal subunits. The eukaryotic translation initiation factor 4G (eIF4G) plays an important role in the formation of the translation initiation complex eIF4F consisting of eIF4G, the ATP dependent RNA helicase eIF4A and the cap binding protein eIF4E. One of the functions of eIF4G is the enhancement of the activity of eIF4A facilitated mainly through binding to the HEAT1 domain of eIF4G. In order to understand the interaction of HEAT1 with eIF4A and other components during translation initiation backbone assignment is essential. Here we report the (1)H, (13)C and (15)N backbone assignment for the HEAT1 domain of human eIF4G isoform I (eIF4GI-HEAT1), the first of three HEAT domains of eIF4G (29 kDa) as a basis for the elucidation of its structure and interactions with its binding partners, necessary for understanding the mechanism of its biological function.

Molecular crowding enhanced ATPase activity of the RNA helicase eIF4A correlates with compaction of its quaternary structure and association with eIF4G.

Enzymatic reactions occur in a crowded and confined environment in vivo, containing proteins, RNA and DNA. Previous reports have shown that interactions between macromolecules, and reactions rates differ significantly between crowded environments and dilute buffers. However, the direct effect of crowding on the level of high-resolution structures of macromolecules has not been extensively analyzed and is not well understood. Here we analyze the effect of macromolecular crowding on structure and function of the human translation initiation factors eIF4A, a two-domain DEAD-Box helicase, the HEAT-1 domain of eIF4G, and their complex. We find that crowding enhances the ATPase activity of eIF4A, which correlates with a shift to a more compact structure as revealed with small-angle X-ray scattering. However, the individual domains of eIF4A, or the eIF4G-HEAT-1 domain alone show little structural changes due to crowding except for flexible regions. Thus, the effect of macromolecular crowding on activity and structure need to be taken into account when evaluating enzyme activities and structures of multidomain proteins, proteins with flexible regions, or protein complexes obtained by X-ray crystallography, NMR, or other structural methods.

Impact of macromolecular crowding on DNA replication.

Enzymatic activities in vivo occur in a crowded environment composed of many macromolecules. This environment influences DNA replication by increasing the concentration of the constituents, desolvation, decreasing the degrees of freedom for diffusion and hopping of proteins onto DNA, and enhancing binding equilibria and catalysis. However, the effect of macromolecular crowding on protein structure is poorly understood. Here we examine macromolecular crowding using the replication system of bacteriophage T7 and we show that it affects several aspects of DNA replication; the activity of DNA helicase increases and the sensitivity of DNA polymerase to salt is reduced. We also demonstrate, using small-angle X-ray scattering analysis, that the complex between DNA helicase and DNA polymerase/trx is far more compact in a crowded environment. The highest enzymatic activity corresponds to the most compact structure. Better knowledge of the effect of crowding on structure and activity will enhance mechanistic insight beyond information obtained from NMR and X-ray structures.

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.

Pyrovanadolysis, a pyrophosphorolysis-like reaction mediated by pyrovanadate, Mn2+, and DNA polymerase of bacteriophage T7.

DNA polymerases catalyze the 3'-5'-pyrophosphorolysis of a DNA primer annealed to a DNA template in the presence of pyrophosphate (PP(i)). In this reversal of the polymerization reaction, deoxynucleotides in DNA are converted to deoxynucleoside 5'-triphosphates. Based on the charge, size, and geometry of the oxygen connecting the two phosphorus atoms of PP(i), a variety of compounds was examined for their ability to carry out a reaction similar to pyrophosphorolysis. We describe a manganese-mediated pyrophosphorolysis-like activity using pyrovanadate (VV) catalyzed by the DNA polymerase of bacteriophage T7. We designate this reaction pyrovanadolysis. X-ray absorption spectroscopy reveals a shorter Mn-V distance of the polymerase-VV complex than the Mn-P distance of the polymerase-PP(i) complex. This structural arrangement at the active site accounts for the enzymatic activation by Mn-VV. We propose that the Mn(2+), larger than Mg(2+), fits the polymerase active site to mediate binding of VV into the active site of the polymerase. Our results may be the first documentation that vanadium can substitute for phosphorus in biological processes.

Conformational dynamics of bacteriophage T7 DNA polymerase and its processivity factor, Escherichia coli thioredoxin.

Gene 5 of bacteriophage T7 encodes a DNA polymerase (gp5) responsible for the replication of the phage DNA. Gp5 polymerizes nucleotides with low processivity, dissociating after the incorporation of 1 to 50 nucleotides. Thioredoxin (trx) of Escherichia coli binds tightly (Kd = 5 nM) to a unique segment in the thumb subdomain of gp5 and increases processivity. We have probed the molecular basis for the increase in processivity. A single-molecule experiment reveals differences in rates of enzymatic activity and processivity between gp5 and gp5/trx. Small angle X-ray scattering studies combined with nuclease footprinting reveal two conformations of gp5, one in the free state and one upon binding to trx. Comparative analysis of the DNA binding clefts of DNA polymerases and DNA binding proteins show that the binding surface contains more hydrophobic residues than other DNA binding proteins. The balanced composition between hydrophobic and charged residues of the binding site allows for efficient sliding of gp5/trx on the DNA. We propose a model for trx-induced conformational changes in gp5 that enhance the processivity by increasing the interaction of gp5 with DNA.

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.

DNA recognition by the DNA primase of bacteriophage T7: a structure-function study of the zinc-binding domain.

Synthesis of oligoribonucleotide primers for lagging-strand DNA synthesis in the DNA replication system of bacteriophage T7 is catalyzed by the primase domain of the gene 4 helicase-primase. The primase consists of a zinc-binding domain (ZBD) and an RNA polymerase (RPD) domain. The ZBD is responsible for recognition of a specific sequence in the ssDNA template whereas catalytic activity resides in the RPD. The ZBD contains a zinc ion coordinated with four cysteine residues. We have examined the ligation state of the zinc ion by X-ray absorption spectroscopy and biochemical analysis of genetically altered primases. The ZBD of primase engaged in catalysis exhibits considerable asymmetry in coordination to zinc, as evidenced by a gradual increase in electron density of the zinc together with elongation of the zinc-sulfur bonds. Both wild-type primase and primase reconstituted from purified ZBD and RPD have a similar electronic change in the level of the zinc ion as well as the configuration of the ZBD. Single amino acid replacements in the ZBD (H33A and C36S) result in the loss of both zinc binding and its structural integrity. Thus the zinc in the ZBD may act as a charge modulation indicator for the surrounding sulfur atoms necessary for recognition of specific DNA sequences.

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.