Use of deuterium labelling in NMR studies of antibody combining site structure

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.

Diastereoselective palladium-catalyzed formate reduction of allylic carbonates en route to polypropionate systems

Diastereoselective palladium-catalyzed formate reduction of allylic carbonates presents unique opportunities for applications in target-oriented organic synthesis provided that selectivity, in particular stereoselectivity, in the course of this metal-catalyzed reaction can be controlled. This article describes our recent developments on new and efficient metal-catalyzed processes exploiting resident stereocenters on the substrates as a means to control stereoselectivity en route to preparing propionate units containing an array of stereochemical patterns. In particular, the effect of the protecting group, the stereochemistry of the aldol adduct, neighboring substituents, and the olefin geometry were examined. Strategic choice of the above parameters provides entry into three of the four possible diastereomeric triads, namely syn-syn, anti-syn, and anti-anti. Preliminary results indicate that construction of the syn-anti triad is possible, albeit in moderate diastereoselectivity.

Malaria parasite-inhibitory antibody epitopes on Plasmodium falciparum merozoite surface protein-1(19) mapped by TROSY NMR

Plasmodium falciparum merozoite surface protein 1 (MSP1)(19), the C-terminal fragment of merozoite surface protein 1, is a leading candidate antigen for development of a vaccine against the blood stages of the malaria parasite. Many human and animal studies have indicated the importance of MSP1(19)-specific immune responses. Anti-MSP1(19) antibodies can prevent invasion of red blood cells by P. falciparum parasites in vitro. However, the fine specificity of anti-MSP1(19) antibodies is also important, as only a fraction of monoclonal antibodies (mAbs) have parasite-inhibitory activity in vitro. Human sera from malaria-endemic locations show strong MSP1(19) reactivity, but individual serum samples vary greatly in inhibitory activity. NMR is an excellent method for studying protein-protein interactions, and has been used widely to study binding of peptides representing known epitopes (as well as non-protein antigens) to antibodies and antibody fragments. The recent development of transverse relaxation optimized spectroscopy (TROSY) and related methods has significantly extended the maximum size limit of molecules that can be studied by NMR. TROSY NMR experiments produce high quality spectra of Fab complexes that allow the mapping of epitopes by the chemical shift perturbation technique on a complete, folded protein antigen such as MSP1(19). We studied the complexes of P. falciparum MSP1(19) with Fab fragments from three monoclonal antibodies. Two of these antibodies have parasite-inhibitory activity in vitro, while the third is non-inhibitory. NMR epitope mapping showed a close relationship between binding sites for the two inhibitory antibodies, distinct from the location of the non-inhibitory antibody. Together with a previously published crystal structure of the P. falciparum MSP1(19) complex with the Fab fragment of another non-inhibitory antibody, these results revealed a surface on MSP1(19) where inhibitory antibodies bind. This information will be useful in evaluating the anti-MSP1(19) immune response in natural populations from endemic areas, as well as in vaccine trials. It will also be valuable for optimizing the MSP1(19) antigen by rational vaccine design. This work also shows that TROSY NMR techniques are very effective for mapping conformational epitopes at the level of individual residues on small- to medium-sized proteins, provided that the antigen can be expressed in a system amenable to stable isotope labelling, such as bacteria or yeast.

The use of 2H, 13C, 15N multidimensional NMR to study the structure and dynamics of proteins

During the past thirty years, deuterium labeling has been used to improve the resolution and sensitivity of protein NMR spectra used in a wide variety of applications. Most recently, the combination of triple resonance experiments and 2H, 13C, 15N labeled samples has been critical to the solution structure determination of several proteins with molecular weights on the order of 30 kDa. Here we review the developments in isotopic labeling strategies, NMR pulse sequences, and structure-determination protocols that have facilitated this advance and hold promise for future NMR-based structural studies of even larger systems. As well, we detail recent progress in the use of solution 2H NMR methods to probe the dynamics of protein sidechains.

Identification of the epitopes of calcitonin gene-related peptide (CGRP) for two anti-CGRP monoclonal antibodies by 2D NMR

The interactions between calcitonin gene-related peptide and FAB fragments prepared from two different high-affinity anti-CGRP monoclonal antibodies (CB3 and CD1) have been studied at physiological pH using the ability of 1H NMR to detect selectively regions of dynamic flexibility. The 37-residue peptide retains considerable flexibility in regions of its sequence when bound to both antibodies; in each case, more than half of the residues can be seen to have linewidths little perturbed from those of the free peptide. However the regions where substantial broadening of resonances occur, attributed to substantially reduced motional freedom of the peptide resulting from interactions within the antibody combining site, differ greatly in the two cases. In the complex with CB3 the results indicate that the restricted residues lie exclusively within the C-terminal half of the peptide, and include residues 25 to 32 and the terminal two residues (36 and 37). By contrast, in the complex with CD1, the conformationally restricted residues appear to lie predominantly within the N-terminal half of the CGRP molecule, particularly residues 4-16, although several residues in the middle section of the sequence (22-31) have reduced conformational freedom. These findings, consistent with the results from immunological assays, add considerably to our knowledge of the epitopes.

Application of 13C NMR spectroscopy to paratope mapping for larger antigen-Fab complexes

For the purpose of engineering the antibody combining site, mapping residues that are involved in antigen binding provide us with valuable information. By use of 13C NMR spectroscopy with selectively 13C-labeled Fv fragments, we have established a general strategy to identify the residues that are perturbed upon binding of small antigen (hapten) molecules [(1990) Biochemistry 30, 6604-6610]. In the present paper, we demonstrate that this strategy can be extended to molecular structural analyses of the complexes of an Fab fragment and a larger antigen molecule such as Pseudomonas aeruginosa exotoxin A with a molecular mass of 67 kDa.

Anatomy of the antibody molecule

The structures of the various regions of an antibody molecule are analysed and correlated with biological function. The structural features which relate to potential applications are detailed.

Improved synthetic methods for the selective deuteration of aromatic amino acids: applications of selective protonation towards the identification of protein folding intermediates through nuclear magnetic resonance

In this report we describe several novel methods for the preparation of selectively deuterated aromatic amino acids. New syntheses for [2,3,5,6-2H4]phenylalanine and [2,4,6,7-2H4]tryptophan, as well as improved catalytic exchange methods for [2,3,5,6-2H4]tyrosine and [2,3,4,5,6-2H5]phenylalanine are presented. Isotopic substitution levels for all compounds are generally found to be greater than 95%. Biosynthetic incorporation of these amino acids is also shown to be possible with little or no evidence of isotopic scrambling. The products from these new syntheses, in combination with other selectively deuterated aromatic amino acids, are found to permit group-specific 'single-proton' labelling of proteins. This highly-efficient and very cost-effective method of selective protonation is shown to produce greatly simplified 1H-NMR spectra of the aromatic region of proteins. The utility of this approach to isotopic editing is demonstrated with the identification of a transient folding intermediate of Escherichia coli thioredoxin which is undetectable by standard 2-D NMR techniques.

NMR studies of the alpha-chymotrypsin-(R)-1-acetamido-2-(4- fluorophenyl)ethane-1-boronic acid complex

The interaction of (R)-1-acetamido-2-(4-fluorophenyl)ethane-1-boronic acid with alpha-chymotrypsin at pH 4 was studied by a variety of 19F-NMR experiments. It was demonstrated that this compound forms a complex with a 1:1 stoichiometry, probably because the boronic acid acts as a 'transition state' inhibitor of the enzyme. Analysis of fluorine T1 relaxation behavior and 19F[1H] NOE data shows that the rate constant for dissociation of the complex is 1.3 s-1 and that the motion of the 4-fluoroaromatic ring within the complex can be characterized by an overall rotational correlation time of 13 ns and a correlation time for rotation about its local C2 axis of 110 ns. Enzyme-induced fluorine chemical shifts, fluorine relaxation times, line width data and 2D 19F[1H] NOE results suggest that the structure of the complex in the vicinity of the fluoroaromatic ring is similar to that found in a closely similar acylated enzyme. However, the dynamics of 4-fluoroaromatic ring motions are different in the two systems, with the ring being slightly more mobile in the boronic acid complex than in the acylenzyme.

A T1 rho-filtered two-dimensional transferred NOE spectrum for studying antibody interactions with peptide antigens

Transferred nuclear Overhauser effect (TRNOE) spectroscopy can be used to study intra- and intermolecular interactions of bound ligands complexed with large proteins. However, the 2D NOE (NOESY) spectra of large proteins are very poorly resolved and it is very difficult to discriminate the TRNOE cross peaks, especially those due to intermolecular interactions, from the numerous cross peaks due to intramolecular interactions in the protein. In previous studies we measured two-dimensional difference spectra that show exclusively TRNOE and exchange cross-peaks (Anglister, J., 1990. Quart. Rev. Biophys. 23:175-203). Here we show that a filtering method based on the difference between the T1rho values of the ligand and the protein protons can be used to directly obtain a two-dimensional transferred NOE spectrum in which the background cross-peaks due to intramolecular interactions in the protein are very effectively removed. The usefulness of this technique to study protein ligand interactions is demonstrated for two different antibodies complexed with a peptide of cholera toxin (CTP3). It is shown that the T1 rho-filtering alleviates t problems encountered in our previous measurements of TRNOE by the difference method. These problems were due to imperfections in the subtraction of two spectra measured for two different samples.

Isotope-edited nuclear magnetic resonance study of Fv fragment of anti-dansyl mouse monoclonal antibody: recognition of the dansyl hapten

An isotope-edited proton nuclear magnetic resonance study is reported of Fv, which is the smallest antigen recognition unit composed of VH and VL domains. Fv has been obtained by clostripain digestion of a short-chain anti-dansyl mouse IgG2a monoclonal antibody [Igarashi, T., Sato, M., Katsube, Y., Takio, K., Tanaka, T., Nakanishi, M., & Arata, Y. (1990) Biochemistry 29, 5727-5733]. A variety of stable-isotope-labeled anti-dansyl Fv analogues have been prepared. The aromatic proton resonances for all Tyr residues of the Fv fragment have been assigned in the absence and presence of epsilon-dansyl-L-lysine by means of isotope-edited homonuclear and heteronuclear two-dimensional NMR experiments. On the basis of the established assignments, it has been concluded that the dansyl ring is bound through Tyr-96H and Tyr-104H to both ends of H3, the third hypervariable region of the heavy chain. We also suggest that the antigen binding results in the formation of a hydrophobic core comprising the dansyl ring and the aromatic rings of Tyr-96H and Tyr-104H.

Structural and kinetic studies of the Fab fragment of a monoclonal anti-spin label antibody by nuclear magnetic resonance

Nuclear magnetic resonance has been used to study the structure of the anti-spin label antibody AN02 combining site and kinetic rates for the hapten-antibody reaction. The association reaction for the hapten dinitrophenyl-diglycine (DNP-diGly) is diffusion-limited. The activation enthalpy for association, 5.1 kcal/mol, is close to the activation enthalpy for diffusion in water. Several reliable resonance assignments have been made with the aid of recently reported crystal structure. Structural data deduced from the nuclear magnetic resonance (n.m.r.) spectra compare favorably with the crystal structure in terms of the combining site amino acid composition, distances of tyrosine residues from the unpaired electron of the hapten, and residues in direct contact with the hapten. Evidence is presented that a single binding site region tyrosine residue can assume two distinct conformations on binding of DNP-diGly. The AN02 antibody is an autoantibody. Dimerization of the Fab fragments is blocked by the hapten DNP-diGly. The n.m.r. spectra suggests that some of the amino acid residues involved in the binding of the DNP-hapten are also involved in the Fab dimerization.

Distinctions in ligand binding sites on the nicotinic acetylcholine receptor

Ligand-gated ion channels possess intrinsic binding sites for noncompetitive inhibitors that differ substantially in ligand specificity and structural characteristics from most binding sites found on globular proteins. We have used the nicotinic acetylcholine receptor to examine the characteristics of such diverse sites because the high-affinity binding site in the proximity of the ion channel has unusual binding interactions and ligand specificity, whereas the site of agonist activation exhibits classical structure-activity characteristics. Noncompetitive inhibitors that bind to the former site show a wide degree of structural variation and appear to associate at separate loci and in distinct orientations in the vicinity of the channel. The receptor structure appears to provide a large domain with multiple hydrophobic crevices that can bind noncompetitive inhibitors, yet binding of these inhibitors is mutually exclusive. The mutually exclusive behavior suggests that association of a single ligand is sufficient to prevent access of additional ligands to distinct sites. This could occur either by physical occlusion to the site of binding or by formation of a conformational state that will not allow entry of additional noncompetitive inhibitors.

Preparation of the Fv fragment from a short-chain mouse IgG2a anti-dansyl monoclonal antibody and use of selectively deuterated Fv analogues for two-dimensional 1H NMR analyses of the antigen-antibody interactions

The Fv fragment, a univalent antigen-binding unit with a molecular weight of 25,000, has successfully been prepared in high yield by limited proteolysis with clostripain of a short-chain mouse IgG2a anti-dansyl monoclonal antibody in which the entire CH1 domain is deleted [Igarashi, T., Sato, M., Takio, K., Tanaka, T., Nakanishi, M., & Arata, Y. (1990) Biochemistry 29, 5727-5733]. The Fv fragment obtained is stable at room temperature and retains its full antigen-binding capability. It has been shown that selective deuterium labeling of the Fv fragment, which is half the size of the Fab fragment, provides 1H NMR spectral data at a sufficient resolution for a detailed structural analysis of the antigen-combining site. NOESY spectra of an Fv analogue, in which all aromatic protons except for His C2'-H and Tyr C3',5'-H had been deuterated, were measured in the presence of varying amounts of dansyl-L-lysine. On the basis of the NOESY data obtained, it was possible to assign all the ring proton resonances for the dansyl group that is bound to the Fv fragment. It was also possible to obtain information about His and Tyr residues of the Fv fragment in the absence and presence of the antigen. On the basis of the NMR data obtained, we have shown that at least two Tyr residues along with one of the amide groups are directly involved in antigen binding. The mode of interaction of the dansyl ring with these residues in the Fv fragment has briefly been discussed.