Studies on functional interaction between brome mosaic virus replicase proteins during RNA recombination, using combined mutants in vivo and in vitro.

Two viral proteins, 1a and 2a, direct replication of brome mosaic bromovirus (BMV) RNAs as well as they participate in BMV RNA recombination. To study the relationship between replication and recombination, double BMV variants that carried mutations in 1a and 2a genes were tested. The observed effects revealed that the 1a helicase and 2a N-terminal or core domains were functionally linked during both processes in vivo. The use of a series of mutant BMV replicase (RdRp) preparations demonstrated in vitro the participation of the 1a and 2a domains in BMV RNA copying and in template switching during minus-strand synthesis. The observed effects support previous observations that the characteristics of homologous and nonhomologous recombination can be modified separately by mutations at different sites on BMV replicase proteins.

Effects on interaction kinetics of mutations at the VH-VL interface of Fabs depend on the structural context.

The influence of framework residues belonging to VH and VL modules of antibody molecules on antigen binding remains poorly understood. To investigate the functional role of such residues, we have performed semi-conservative amino acid replacements at the VH-VL interface. This work was carried out with (i) variants of the same antibody and (ii) with antibodies of different specificities (Fab fragments 145P and 1F1h), in order to check if functional effects are additive and/or similar for the two antibodies. Interaction kinetics of Fab mutants with peptide and protein antigens were measured using a BIACORE instrument. The substitutions introduced at the VH-VL interface had no significant effects on k(a) but showed small, significant effects on k(d). Mutations in the VH module affected k(d) not only for the two different antibodies but also for variants of the same antibody. These effects varied both in direction and in magnitude. In the VL module, the double mutation F(L37)L-Q(L38)L, alone or in combination with other mutations, consistently decreased k(d) about two-fold in Fab 145P. Other mutations in the VL module had no effect on k(d) in 145P, but always decreased k(d) in 1F1h. Moreover, in both systems, small-magnitude non-additive effects on k(d) were observed, but affinity variations seemed to be limited by a threshold. When comparing functional effects in antibodies of different specificity, no general rules could be established. In addition, no clear relationship could be pointed out between the nature of the amino acid change and the observed functional effect. Our results show that binding kinetics are affected by alteration of framework residues remote from the binding site, although these effects are unpredictable for most of the studied changes.

Kinetic analysis of the effect on Fab binding of identical substitutions in a peptide and its parent protein.

Monoclonal antibody 57P, which was raised against tobacco mosaic virus protein, cross-reacts with a peptide corresponding to residues 134-146 of this protein. Previous studies using peptide variants suggested that the peptide in the antibody combining site adopts a helical configuration that mimics the structure in the protein. In this study, we carried out a detailed comparison of Fab-peptide and Fab-protein interactions. The same five amino acid substitutions were introduced in the peptide (residues 134-151) and the parent protein, and the effect of these substitutions on antibody binding parameters have been measured with a Biacore instrument. Fabs that recognize epitopes located away from the site of mutations were used as indirect probes for the conformational integrity of protein antigens. Their interaction kinetics with all proteins were similar, suggesting that the substitutions had no drastic effect on their conformation. The five substitutions introduced in the peptide and the protein had minor effects on association rate constants (ka) and significant effects on dissociation rate constants (kd) of the antigen-Fab 57P interactions. In four out of five cases, the effect on binding affinity of the substitutions was identical when the epitope was presented in the form of a peptide or a protein antigen, indicating that antibody binding specifity was not affected by epitope presentation. However, ka values were about 10 times larger and kd values about 5 times larger for the peptide-Fab compared to the protein-Fab interaction, suggesting a different binding mechanism. Circular dichroism measurements performed for three of the peptides showed that they were mainly lacking structure in solution. Differences in conformational properties of the peptide and protein antigens in solution and/or in the paratope could explain differences in binding kinetics. Our results demonstrate that the peptides were able to mimic correctly some but not all properties of the protein-Fab 57P interaction and highlight the importance of quantitative analysis of both equilibrium and kinetic binding parameters in the design of synthetic vaccines and drugs.

Measurement of antigen-antibody interactions with biosensors.

The introduction in 1990 of a new biosensor technology based on surface plasmon resonance has revolutionized the measurement of antigen-antibody binding interactions. In this technique, one of the interacting partners is immobilized on a sensor chip and the binding of the other is followed by the increase in refractive index caused by the mass of bound species. The following immunochemical applications of this new technology will be described: (1) functional mapping of epitopes and paratopes by mutagenesis; (2) analysis of the thermodynamic parameters of the interaction; (3) measurement of the concentration of biologically active molecules; (4) selection of diagnostic probes.

Concentration measurement of unpurified proteins using biosensor technology under conditions of partial mass transport limitation.

Using biosensor technology, it is possible to measure protein concentration when the binding of the protein to an appropriate ligand immobilized on the sensor surface is totally limited by diffusion and mass transport, a condition difficult to achieve in practice. In such a case, the observed binding rate does not reflect the intrinsic binding capacity of the molecular partners, but is simply proportional to the concentration of the protein analyte that is introduced in a continuous flow over the ligand. We describe here a more general biosensor method for measuring protein concentration which is applicable to conditions where mass transport is not totally but only partially rate limiting. The proposed method, which is based on measurements at different flow rates, does not require a standard of known protein concentration and can be used with unpurified proteins. The method is applicable to ligand-analyte pairs with an association rate constant as low as 10(3) M-1 s-1 and requires only knowledge of the molecular weight and diffusion coefficient of the analyte. The method was used successfully to measure the concentration of monoclonal antibodies, monoclonal antibody fragments (Fab) obtained by papain cleavage, and recombinant Fab fragments of widely different affinities in crude Escherichia coli extracts.

Uses of biosensors in the study of viral antigens.

The introduction in 1990 of a new biosensor technology based on surface plasmon resonance has greatly simplified the measurement of binding interactions in biology. This new technology known as biomolecular interaction analysis makes it possible to visualize the binding process as a function of time by following the increase in refractive index that occurs when one of the interacting partners binds to its ligand immobilized on the surface of a sensor chip. None of the reactants needs to be labelled, which avoids the artefactual changes in binding properties that often result when the molecules are labelled. Biosensor instruments are well-suited for the rapid mapping of viral epitopes and for identifying which combinations of capturing and detector Mabs will give the best results in sandwich assays. Biosensor binding data are also useful for selecting peptides to be used in diagnostic solid-phase immunoassays. Very small changes in binding affinity can be measured with considerable precision which is a prerequisite for analyzing the functional effect and thermodynamic implications of limited structural changes in interacting molecules. On-rate (ka) and off-rate (kd) kinetic constants of the interaction between virus and antibody can be readily measured and the equilibrium affinity constant K can be calculated from the ratio ka/kd = K.

Comparative interaction kinetics of two recombinant Fabs and of the corresponding antibodies directed to the coat protein of tobacco mosaic virus.

Two recombinant Fab fragments, 57P and 174P, recognizing peptide 134-146 of the coat protein of tobacco mosaic virus have been cloned, sequenced and expressed in Escherichia coli. They differ by 15 amino acid changes in the sequence of their variable region. The interaction kinetics of the Fabs with the wild-type and four mutant peptides have been compared using a BIAcoreTM biosensor instrument. The recombinant Fab 174P had the same reactivity as the Fab fragment obtained by enzymatic cleavage of monoclonal antibody 174P. The two recombinant Fabs recognized the various peptides in the same ranking order but Fab 174P consistently dissociated somewhat faster from the peptides compared to Fab 57P. The two whole antibodies showed the same relative differences in reactivity as the two recombinant Fabs. The location of amino acid changes was visualized on a model structure of the Fab. Differences in dissociation rates of the two antibodies are most likely due to changes located at the periphery of the antigen-combining site and/or at the interface between the light and heavy chain domains. Our results demonstrate the feasibility of detecting very small differences in binding affinity by the biosensor technology, which is a prerequisite for assessing the functional effect of limited structural changes.