Display-induced antigenic variation in recombinant peptides

Engineering nuclear localization signals in modular protein vehicles for gene therapy

Amino acids from 126 to 135 of the SV40 virus T antigen act as efficient nuclear localization signal during infection but also when fused to recombinant proteins. This peptide has been inserted into two alternative acceptor sites of a modified Escherichia coli beta-galactosidase which also displays a DNA-binding domain, a cell-binding motif for integrin alpha(v)beta(3) targeting and cell internalization, and a cryptic nuclear targeting signal naturally present in the bacterial enzyme. In cultured cells, the presence of the SV40 peptide enhances the expression of a delivered DNA up to 30-fold. However, the DNA expression levels are largely depending on the chosen insertion site for the SV40 segment concomitant to the structural impact of peptide accommodation on the protein vehicle. The structural stability of the hybrid protein, apparently critical for efficient gene transfer, is discussed in the context of modular protein engineering to develop non-viral vectors for gene therapy.

Engineering of Escherichia coli beta-galactosidase for solvent display of a functional scFv antibody fragment

Protein engineering allows the generation of hybrid polypeptides with functional domains from different origins and therefore exhibiting new biological properties. We have explored several permissive sites in Escherichia coli beta-galactosidase to generate functional hybrid enzymes displaying a mouse scFv antibody fragment. When this segment was placed at the amino-terminus of the enzyme, the whole fusion protein was stable, maintained its specific activity and interacted specifically with the target antigen, a main antigenic determinant of foot-and-mouth disease virus. In addition, the antigen-targeted enzyme was enzymatically active when bound to the antigen and therefore useful as a reagent in single-step immunoassays. These results prove the flexibility of E. coli beta-galactosidase as a carrier for large-sized functional domains with binding properties and prompt the further exploration of the biotechnological applicability of the scFv enzyme targeting principle for diagnosis or other biomedical applications involving antigen tagging.

Exploiting viral cell-targeting abilities in a single polypeptide, non-infectious, recombinant vehicle for integrin-mediated DNA delivery and gene expression

A recombinant, multifunctional protein has been designed for optimized, cell-targeted DNA delivery and gene expression in mammalian cells. This hybrid construct comprises a viral peptide ligand for integrin alpha(V)beta(3) binding, a DNA-condensing poly-L-lysine domain, and a complete, functional beta-galactosidase protein that serves simultaneously as purification tag and DNA-shielding agent. This recombinant protein is stable; it has been produced successfully in Escherichia coli and can be purified in a single step by affinity chromatography. At optimal molar ratios, mixtures of this vector and a luciferase-reporter plasmid form stable complexes that transfect cultured cells. After exposure to these cell-targeted complexes, steady levels of gene expression are observed for more than 3 days after transfection, representing between 20 and 40% of those achieved with untargeted, lipid-based DNA-condensing agents. The principle to include viral motifs for cell infection in single polypeptide recombinant proteins represents a promising approach towards the design of non-viral modular DNA transfer vectors that conserve the cell-target- ing specificity of native viruses and that do not need further processing after bioproduction in a recombinant host.

Successful mimicry of a complex viral antigen by multiple peptide insertions in a carrier protein

The antigenic properties of a viral peptide from the surface of foot-and-mouth disease virus particles have been successfully mimicked by multiple insertion in solvent-exposed regions of Escherichia coli beta-galactosidase. By increasing the number of viral peptides per enzyme monomer, the average IC(50) of hybrid proteins in a competitive enzyme-linked immunosorbent assay) have decreased to values close to that presented by natural virions. Moreover, the antigenic diversity of these new recombinant enzymes when measured with different anti-virus antibodies has also been largely reduced, indicating a better presentation of the epitopes located in the viral peptide. Although bivalent antibody binding could have been favoured by multiple presentation, conformational modifications of the viral peptide, due to the presence of other insertions or a cooperative antibody binding cannot be excluded. In addition, a multidimensional antigenic analysis have grouped together the multiple-inserted proteins with the native virus, suggesting that increasing the number of insertions could be a good strategy to reproduce the antigenic properties of an immunoreactive peptide in a natural multimeric disposition.

Detection of molecular interactions by using a new peptide-displaying bacteriophage biosensor

Foreign peptides fused to the carboxy terminus of P22 tailspike protein are solvent-exposed and highly antigenic when displayed on the surface of infectious virus particles. Binding of an anti-peptide specific Fab antibody fragment enhances the infectivity of chimeric bacteriophage particles in a titre-dependent fashion. Although the precise molecular basis of this enhanced infectivity remains unclear, experimental data and modelling approaches suggest that the antibody binding might restore conformational impairments in the assembled tail protein affecting its activity and performance during infection. These results suggest that in addition to free enzymes, peptide-displaying bacteriophages could be engineered as new biosensors to detect molecular interactions by using natural viral enzymes critical for cell infection.

Distinct mechanisms of antibody-mediated enzymatic reactivation in beta-galactosidase molecular sensors

The antibody-mediated reactivation of engineered Escherichia coli beta-galactosidases [Benito et al. (1996) J. Biol. Chem. 271, 21251-21256] has been thoughtfully investigated in three recombinant molecular sensors. Proteins M278VP1, JX772A and JX795A display the highly antigenic G-H loop peptide segment of foot-and-mouth disease virus VP1 protein, accommodated in different solvent-exposed loops of the assembled tetramer. These chimaeric enzymes exhibit a significant increase in enzymatic activity upon binding of either monoclonal antibodies or sera directed against the inserted viral peptide. In JX772A but not in M278VP1, the Fab 3E5 antibody fragment promotes reactivation to the same extent as the complete antibody. On the other hand, M278VP1 Km is reduced by more than 50% in the presence of activating serum, this parameter remains invariable in JX772A and it is only slightly modified in JX795A. In these last two proteins, significant k(cat) variations can account for the increased enzymatic activity. Alternative reactivation mechanisms in the different beta-galactosidase probes are discussed in the context of the bacterial enzyme structure and its tolerance to antibody-induced conformational modifications.