A coleopteran triosephosphate isomerase: X-ray structure and phylogenetic impact of insect sequences

A coleopteran triosephosphate isomerase (TIM) from Tenebrio molitor (yellow mealworm beetle) was recombinantly expressed in Escherichia coli and characterized with respect to thermal stability, kinetic parameters and oligomeric state. The enzyme was successfully crystallized and the structure determined by X-ray analysis to 2.0 A resolution. This is the first example of an invertebrate TIM. We compare structural features with known structures of TIMs from microorganisms, plants and vertebrates, and discuss the utility of the Tenebrio TIM sequence, together with several newly sequenced insect TIMs, for molecular phylogenetic analysis.

Anti-c-myc antibody 9E10: epitope key positions and variability characterized using peptide spot synthesis on cellulose

The 9E10 antibody epitope (EQKLISEEDL) derives from a protein sequence in the human proto-oncogen p62(c-myc) and is widely used as a protein fusion tag. This myc-tag is a powerful tool in protein localization, immunochemistry, ELISA or protein purification. Here, we characterize the myc-tag epitope by substitutional analysis and length variation using peptide spot synthesis on cellulose. The key amino acids of this interaction are the core residues LISE. The shortest peptide with a strong binding signal is KLISEEDL. Dissociation constants of selected peptide variants to the antibody 9E10 were determined. scFv constructs with the shortest possible myc-tags were successfully detected by Western blot and ELISA, giving a signal comparable to that of the original myc-tag.

Changing the antigen binding specificity by single point mutations of an anti-p24 (HIV-1) antibody

The murine mAb CB4-1 raised against p24 (HIV-1) recognizes a linear epitope of the HIV-1 capsid protein. Additionally, CB4-1 exhibits cross-reactive binding to epitope-homologous peptides and polyspecific reactions to epitope nonhomologous peptides. Crystal structures demonstrate that the epitope peptide (e-pep) and the nonhomologous peptides adopt different conformations within the binding region of CB4-1. Site-directed mutagenesis of the fragment variable (Fv) region was performed using a single-chain (sc)Fv construct of CB4-1 to analyze binding contributions of single amino acid side chains toward the e-pep and toward one epitope nonhomologous peptide. The mutations of Ab amino acid side chains, which are in direct contact with the Ag, show opposite influences on the binding of the two peptides. Whereas the affinity of the e-pep to the CB4-1 scFv mutant heavy chain variable region Tyr(32)Ala is decreased 250-fold, the binding of the nonhomologous peptide remains unchanged. In contrast, the mutation light chain variable region Phe(94)Ala reduces the affinity of the nonhomologous peptide 10-fold more than it does for the e-pep. Thus, substantial changes in the specificity can be observed by single amino acid exchanges. Further characterization of the scFv mutants by substitutional analysis of the peptides demonstrates that the effect of a mutation is not restricted to contact residues. This method also reveals an inverse compensatory amino acid exchange for the nonhomologous peptide which increases the affinity to the scFv mutant light chain variable region Phe(94)Ala up to the level of the e-pep affinity to the wild-type scFv.

Crystal structure of a phage library-derived single-chain Fv fragment complexed with turkey egg-white lysozyme at 2.0 A resolution

The three-dimensional structure of the single-chain Fv fragment 1F9 in complex with turkey egg-white lysozyme (TEL) has been determined to a nominal resolution of 2.0 A by X-ray diffraction. The scFv fragment 1F9 was derived from phage-display libraries in two steps and binds both hen and turkey egg-white lysozyme, although the level of binding affinity is two orders of magnitude greater for the turkey lysozyme. The comparison of the crystal structure with a model of the single-chain Fv fragment 1F9 in complex with hen egg-white lysozyme (HEL) reveals that in the latter a clash between Asp101 in lysozyme and Trp98 of the complementarity determining region H3 of the heavy chain variable domain occurs. This is the only explanation apparent from the crystal structure for the better binding of TEL compared to HEL. The binding site topology on the paratope is not simply a planar surface as is usually found in antibody-protein interfaces, but includes a cleft between the light chain variable domain and heavy chain variable domain large enough to accommodate a loop from the lysozyme. The scFv fragment 1F9 recognizes an epitope on TEL that differs from the three antigenic determinants recognized in other known crystal structures of monoclonal antibodies in complex with lysozyme.

Characterization of neutralizing anti-pre-S1 and anti-pre-S2 (HBV) monoclonal antibodies and their fragments

Single-chain Fv fragments (scFv) were generated from two murine monoclonal antibodies directed to the neutralizing epitopes of the pre-S1 and pre-S2 region of hepatitis B virus, respectively, using different assembly cloning strategies. The scFv fragments were solubly expressed in E. coli. Dissociation constants were in the nanomolar range for all forms (whole IgG antibodies, Fab fragment and scFv fragments). The epitopes of both antibodies were mapped using solid phase peptide synthesis on continuous cellulose membranes and turned out to be linear determinants. The minimal epitope for the anti-pre-S2 antibody 1F6 was identified to be DPRVRGLYF (amino acid 133-141 of the pre-S region). For the anti-pre-S1 antibody MA 18/7 the minimal epitope proved to be the hexamer LDPAFR (amino acid 30-35 of the pre-S region). Complete substitutional analyses as well as truncation experiments revealed key residues for these antibody-antigen interactions. On the basis of those results we used computer-assisted modeling techniques to suggest models for both antibody-peptide interactions providing insight into the structural basis of these molecular recognitions.

A phage library-derived single-chain Fv fragment in complex with turkey egg-white lysozyme: characterization, crystallization and preliminary X-ray analysis

Using phage-display, an anti-turkey egg-white lysozyme single-chain Fv fragment was selected from a naive light chain variable region repertoire in combination with a heavy chain variable region 'mini library' of anti-hen egg-white lysozyme single-domain binders (Ward et al., 1989). Whereas the selected VH domain alone binds somewhat better hen egg-white lysozyme than turkey egg-white lysozyme, but both with comparatively low affinity, the specificity of VH is converted by addition of the VL domain. Thus, the single-chain Fv fragment is more specific for turkey egg-white lysozyme, with markedly increased affinities towards both lysozymes. The complex of single-chain Fv with turkey lysozyme has been crystallized and characterized by preliminary X-ray analysis.

Structural base of the interaction of a monoclonal antibody against p24 of HIV-1 with its peptide epitope

The interaction of a murine monoclonal antibody (CB 4-1) against the core protein p24 of HIV-1 with its peptide antigen was studied in detail. The amino acid sequence of the variable regions of the heavy and light chain as derived from DNA sequencing was used to model the structure of the antigen binding region on the basis of reported Fab structures from the Brookhaven Protein Data Base. A linear peptide epitope responsible for the p24 binding to the antibody was determined by peptide scan. Subsequent N- and C-terminal truncation of the corresponding sequence region as well as amino acid substitutions were performed to recognize the epitope and the amino acid residues critical for antibody binding. These data were used to derive a structural model of the peptide-antibody interaction.

Immunoglobulin V regions and epitope mapping of a murine monoclonal antibody against p24 core protein of HIV-1

The nucleotide sequence of a murine monoclonal antibody (CB-mab-p24/13-5) against p24 core protein of the human immunodeficiency virus (HIV-1) was determined for variable regions of the heavy and light chain, respectively. Genetic elements encoding the VDJH- and VJL-regions of the antibody were generated from RNA by the polymerase chain reaction, cloned into the vector pICEM 19R and sequenced. Synthetic peptides, 10 amino acids overlapping served for the localization of the epitope. The residues 152-156 within the p24 sequence contain the epitope.

Oxidation of a methionine residue in subtilisin-type proteinases by the hydrogen peroxide/borate system--an active site-directed reaction

Subtilisin-type proteinases (thermitase, subtilisin Carlsberg, alkaline proteinase ZIMET 10911, proteinase K) are partially inactivated by hydrogen peroxide in the alkaline pH range only in the presence of boric acid or phenylboronic acid. A model is presented to describe the inactivation mechanism. Both boric acid and perboric acid existing in equilibrium in the presence of hydrogen peroxide bind competitively at the active site of the enzyme. The inactivation, which is known to be caused by sulfoxide formation from the methionine residue in the active site (Stauffer, C.E. and Etson, D. (1969) J. Biol. Chem. 244, 5333-5338), is due to the enzyme-bound perboric acid species. The dissociation constants for the boric acid-thermitase and perboric acid-thermitase complexes are 36 +/- 7 and 4 +/- 1 mM, respectively. The first-order rate constant of inactivation is k = 0.63 +/- 0.14 min-1. The same mechanism of inactivation holds true for phenylboronic acid in alkaline hydrogen peroxide solutions.