Probing DNA and RNA single molecules with a double optical tweezer.

A double-tweezer setup is used to induce mechanical stress in systems of molecular biology. A double strand of DNA is first stretched and the data is compared to precedent experiments to check the experimental setup. Then a short foldable fragment of RNA is probed; the typical unfolding/refolding hysteresis behaviour of this kind of construction is shown and followed by a study of its elasticity and a comparison to a worm-like chain model. Eventually, we describe the unfolding of a larger RNA structure, which unfolds by multiple steps. We show that this unfolding is not reversible and that it presents numerous unfolding pathways.

Mechanism of neutralization of influenza virus infectivity by antibodies.

We have determined the mechanism of neutralization of influenza virus infectivity by three antihemagglutinin monoclonal antibodies, the structures of which we have analyzed before as complexes with hemagglutinin. The antibodies differ in their sites of interaction with hemagglutinin and in their abilities to interfere in vitro with its two functions of receptor binding and membrane fusion. We demonstrate that despite these differences all three antibodies neutralize infectivity by preventing virus from binding to cells. Neutralization occurs at an average of one antibody bound per four hemagglutinins, a ratio sufficient to prevent the simultaneous receptor binding of hemagglutinins that is necessary to attach virus to cells.

An antibody that prevents the hemagglutinin low pH fusogenic transition.

We have determined the structure of a complex of influenza hemagglutinin (HA) with an antibody that binds simultaneously to the membrane-distal domains of two HA monomers, effectively cross-linking them. The antibody prevents the low pH structural transition of HA that is required for its membrane fusion activity, providing evidence that a rearrangement of HA membrane-distal domains is an essential component of the transition.

A neutralizing antibody Fab-influenza haemagglutinin complex with an unprecedented 2:1 stoichiometry: characterization and crystallization.

The haemagglutinin HA is a trimer of identical subunits and is the more abundant viral surface glycoprotein of the influenza virus. It is the target of antibodies that neutralize viral infectivity. Antibodies that bind to HA with 3:1 and 1:1 stoichiometries have been identified. Here, an antibody whose Fab binds to HA with an unprecedented 2:1 Fab:HA stoichiometry is characterized. The complex has been crystallized and synchrotron data to 3.5 A resolution have been collected. Molecular replacement confirms the stoichiometry of the complex.

Structural evidence for recognition of a single epitope by two distinct antibodies.

The structure of a complex between the hemagglutinin of influenza virus and the Fab of a neutralizing antibody was determined by X-ray crystallography at 2.8 A resolution. This antibody and another which has only 56% sequence identity bind to the same epitope with very similar affinities and in the same orientation. One third of the interactions is conserved in the two complexes; a significant proportion of the interactions that differ are established by residues of the H3 complementarity-determining regions (CDR) which adopt distinct conformations in the two antibodies. This demonstrates that there is a definite flexibility in the selection of antibodies that bind to a given epitope, despite the high affinity of their complexes. This flexibility allows the humoral immune response to be redundant, a feature that may be useful in achieving longer lasting protection against evolving viral pathogens.

A complex of influenza hemagglutinin with a neutralizing antibody that binds outside the virus receptor binding site.

The structure of a complex of influenza hemagglutinin (HA) with a neutralizing antibody shows that the antibody binds to HA at a distance from the virus receptor binding site. Comparison of the properties of this antibody and its Fab with those of an antibody that recognizes an epitope overlapping the receptor binding site leads to two main conclusions. First, inhibition of receptor binding is an important component of neutralization. Second, the efficiency of neutralization by the antibodies ranks in the same order as their avidities for HA, and their large size makes these antibodies highly efficient at neutralization, regardless of the location of their epitope in relation to the virus receptor binding site. These observations provide rationales for the range of antibody specificities that are detected in immune sera and for the distribution of sequence changes on the membrane-distal surface of influenza HAs that occur during 'antigenic drift.'

Antigen distortion allows influenza virus to escape neutralization.

The structure of the hemagglutinin (HA) of a mutant influenza virus that escapes neutralization by a monoclonal antibody shows that the mutation causes changes in HA structure which avoid an energetically less favorable conformation. However, the structure of the mutant HA.Fab complex indicates that the antibody binds selectively to mutant HA in a wild type-like distorted conformation. The association of an antibody with a less favored HA conformation represents an alternative to previously described mechanisms of escape from neutralization by antibodies.

Structural and functional properties of mutant Arg203Pro from yeast phosphoglycerate kinase, as a model of phosphoglycerate kinase-Uppsala.

A pathological variant of human phosphoglycerate kinase, phosphoglycerate kinase-Uppsala, associated with chronic nonspherocytic hemolytic anemia has been found to differ from the normal enzyme by substitution of an arginine at position 206 (corresponding to position 203 in yeast) by a proline. In order to understand the structural and functional consequences of this mutation, the corresponding mutant in yeast phosphoglycerate kinase was constructed. The three-dimensional structure of this mutant was resolved at 2.9 A. Although the overall structure is not modified, small local changes were observed. The kinetic parameters of the mutant were not found to be greatly affected, the catalytic constant being lowered by only 10-20%. The most significant difference when compared with the wild-type enzyme is a decrease in stability by about 3 kcal/mol. The physiological implications of this instability are discussed.

Crystallization and preliminary X-ray diffraction studies of complexes between an influenza hemagglutinin and Fab fragments of two different monoclonal antibodies.

Fab fragments from two different monoclonal antibodies (BH151 and HC45) which bind to the same antigenic region of the influenza hemagglutinin were crystallized as complexes with the hemagglutinin. The complexes crystallize in PEG 600, pH 6.0, and PEG 2000, pH 8.5, respectively. Both crystals belong to space group P321, with very similar unit cell dimensions.

Structure of influenza virus haemagglutinin complexed with a neutralizing antibody.

Haemagglutinin (HA) is the influenza surface glycoprotein that interacts with infectivity-neutralizing antibodies. As a consequence of this immune pressure, it is the variable virus component, which is important in antigenic drift, that results in recurrent epidemics of influenza. We have determined the crystallographic structure of a complex formed between the antigen-binding fragment (Fab) of a neutralizing antibody and the membrane-distal domain ('HA top') of a HA subunit prepared from HA in its membrane-fusion-active conformation. A dramatic change is seen in the structure of the Fab-combining site on complex formation. Our results indicate that neutralization of infectivity by this antibody involves the inhibition of receptor binding, and demonstrate how influenza virus can maintain its conserved receptor-binding site despite the immune selective pressure for change in this region of the molecule; they also contribute to a complete description of the endosomal pH-induced fusion-active HA structure.

Refined three-dimensional structure of the Fab fragment of a murine IgGl,lambda antibody.

We report the cDNA sequence determination and the crystal structure of the Fab fragment of a murine IgG1,lambda antibody (HC19), specific for an influenza virus hemagglutinin. The HC19 Fab-fragment structure has been refined; the crystallographic R-factor is 19.5% at 2.3 A resolution. We have compared the conformation of HC19 complementarity determining regions (CDRs) with those of CDR loops of Fab structures available from the Protein Data Bank. These loops were chosen based on the identity of key residues, following the canonical-structure approach; four CDRs have a main-chain conformation very similar to the canonical structure that had been identified. HC19 L1 CDR adopts a conformation clearly distinct from all L1 CDRs that belong to a chain of a different class or origin; this is determined by the nature of a few residues at positions in the sequence different from those of key residues in other light chains. This canonical structure should be representative of most murine lambda-class light chains, as inferred from the very high sequence homologies of these polypeptides.

Crystal structure of a catalytic antibody Fab with esterase-like activity.

BACKGROUND: Antibodies with catalytic properties can be prepared by eliciting an antibody response against 'transition state analog' haptens. The specificity, rate and number of reaction cycles observed with these antibodies more closely resemble the properties of enzymes than any of the many other known enzyme-mimicking systems. RESULTS: We have determined to 3 A resolution the first X-ray structure of a catalytic antibody Fab. This antibody catalyzes the hydrolysis of a p-nitrophenyl ester. In conjunction with binding studies in solution, this structure of the uncomplexed site suggests a model for transition state fixation where two tyrosines mimic the oxyanion binding hole of serine proteases. A comparison with the structures of known Fabs specific for low molecular weight haptens reveals that this catalytic antibody has an unusually long groove at its combining site. CONCLUSION: Since transition state analogs contain elements of the desired product, product inhibition is a severe problem in antibody catalysis. The observation of a long groove at the combining site may relate to the ability of this catalytic antibody to achieve multiple cycles of reaction.

Rigid-body docking with mutant constraints of influenza hemagglutinin with antibody HC19.

An automatic docking algorithm has been applied to the modeling of the complex between hemagglutinin from influenza virus and the Fab fragment of a monoclonal antibody raised against this antigen. We have introduced here the use of biochemical information provided by mutants of hemagglutinin. The docking procedure finds a small number of candidate solutions where three sites of escape mutations are buried and form hydrogen bonds in the interface. The localization of the epitope is improved by additional biochemical data about mutants that do not affect antibody binding. Five candidate solutions with low energy, reasonably well-packed interfaces, and six to ten hydrogen bonds are compatible with mutant information. One of the five stands out as generally better than the others from these points of views.

Use of molecular replacement in the solution of an immunoglobulin Fab fragment structure.

Molecular-replacement efficiency depends highly on structural and sequence homologies between available models and the molecule in the crystal being studied. The structure of the Fab fragment of an antibody specific for an influenza virus hemagglutinin was determined by molecular replacement and the Fv and the CH1:CL parts were localized separately. When rotation functions were calculated using known Fv structures as probes, a solution could not be found; this turns out to be due to an insufficient structural homology between the structure and the probes. When the structural homology between the Fv part and its model was enhanced by combining known structures of Fv domains based on sequence information, the right orientation was determined and confirmed by translation-function results. In the cases described here, a high contrast of the translation function was the most reliable criterion to detect a molecular-replacement solution.

Crystallization and preliminary X-ray diffraction studies of a monoclonal antibody Fab fragment specific for an influenza virus haemagglutinin and of an escape mutant of that haemagglutinin.

Preliminary crystallographic data are given for two molecules involved in the interaction between the humoral immune response and the influenza virus. These molecules are the Fab fragment of an antibody specific for the haemagglutinin of influenza virus strain X31 (Hong Kong 1/68 (H3N2)) and a mutant of X31 haemagglutinin that escapes recognition by that antibody. Crystals of the haemagglutinin are isomorphous to those of X31, whose structure is known; they diffract to 3.4 A resolution. Crystals of the Fab fragment are trigonal with space group P3(1)21 (or P3(2)21) and diffract to 2.6 A resolution. The unit cell dimensions are a = b = 98.9 A, c = 89.2 A. A native data set has been collected for both proteins.