Immobilization of histidine-tagged proteins on gold surfaces using chelator thioalkanes.

The reversible, oriented immobilization of proteins on solid surfaces is a prerequisite for the investigation of molecular interactions and the controlled formation of supramolecular assemblies. This paper describes a generally applicable method using a synthetic chelator thioalkane that can be self-assembled on gold surfaces. The reversible binding of an anti-lysozyme F(ab) fragment modified with a C-terminal hexahistidine extension was monitored and the apparent dissociation constants determined using surface plasmon resonance. Infra-red spectroscopy demonstrated that the secondary structure of the protein was unaffected by the immobilization process. The retention of functionality of the immobilized protein was also successfully demonstrated. Given the mild reaction conditions and reversibility, this method of oriented immobilization of proteins opens possibilities for the development of biosensors.

Sequence analysis and bacterial production of the anti-c-myc antibody 9E10: the V(H) domain has an extended CDR-H3 and exhibits unusual solubility.

The cDNAs for the two variable domains of the antibody 9E10 were cloned from the hybridoma cell line. A chimeric 9E10 Fab fragment was produced in E. coli under control of the tightly controlled tetracycline promoter. The functional Fab fragment was isolated in a single step via a His6-tag, which also served for its recognition by a nickel chelate-alkaline phosphatase conjugate. Thus, the recombinant Fab fragment permitted the immunochemical detection of the myc tag in a sandwich ELISA. The dissociation constant for the interaction with the myc tag peptide was determined as 80 +/- 5 nM by fluorescence titration. In an attempt to produce the smaller 9E10 Fv fragment it was found that its V(H) domain alone can be readily isolated from E. coli as a soluble protein. This unusual behaviour may be explained by the 18 amino acid-long CDR-H3 and could be of value in the design of 'single domain' antibodies.

The rational construction of an antibody against cystatin: lessons from the crystal structure of an artificial Fab fragment.

In a protein design study the artificial antibody M41 was modelled with its binding site complementary to the protease inhibitor cystatin, which was chosen as a structurally well-characterized "antigen". The modelling of M41 took advantage of the crystal structure of the anti-lysozyme antibody HyHEL-10 as a structural template. Its combining site was reshaped by replacing 19 amino acid side-chains in the hypervariable loops. In addition, ten amino acid residues were substituted in the framework regions. The crystal structure of the corresponding antibody model M41, which was produced as an F(ab) fragment in Escherichia coli, was determined at a resolution of 1.95 A. The crystals exhibited symmetry of the space group P2(1)2(1)2(1) (a = 96.5 A; b = 103.5 A; c = 113.6 A) with two F(ab) fragments in the asymmetric unit, which were independently refined (final R-factor 21.7%). The resulting coordinates were used for a detailed comparison with the modelled protein structure. It was found that the mutual arrangement of the six complementarity-determining regions as well as most of their backbone conformation had been correctly predicted. One major difference that was detected for the conformation of a five residue insertion in complementarity-determining region L1 could be explained by an erroneously defined segment in the structure of the antibody 4-4-20, which had been used as a template for this loop. In the light of more recent crystallographic data it appears that this segment adopts a new canonical structure. Apart from this region, most of the side-chains in the antigen-binding site had been properly placed in the M41 model. There was however one important exception concerning Trp H98, whose side-chain conformation had been kept as it appeared in HyHEL-10. The differing orientation of this residue in the model compared with the crystal structure of the artificial F(ab) fragment M41 explains why an antigen affinity could not be detected so far. The detailed analysis of this and other, more subtle deviations suggests how to make this F(ab) fragment function by introducing a few additional amino acid changes into M41.

The Escherichia coli-derived Fab fragment of the IgM/kappa antibody IN-1 recognizes and neutralizes myelin-associated inhibitors of neurite growth.

A recombinant Fab fragment was prepared from the monoclonal IgM/kappa antibody IN-1, which neutralizes central nervous system myelin-associated neurite growth inhibitors both in vitro and in vivo. The variable domain gene sequences were amplified and cloned after cDNA synthesis from the hybridoma RNA. After insertion into the tet promoter vector pASK85, which provided the constant domains of class IgG1/kappa, equipped with a His6 tag, large amounts of the Fab fragment were produced in Escherichia coli by medium cell density fermentation. The Fab fragment was purified to homogeneity by immobilized metal-affinity chromatography and its biochemical activity was compared with the original IN-1 antibody. In an assay for neurite outgrowth and fibroblast spreading, the Fab fragment showed a similar neutralizing effect on inhibitory substrate properties of central nervous system myelin as the unpurified IgM, although an approximately tenfold higher concentration was necessary. Immunoprecipitation experiments revealed a more selective antigen-binding behaviour for the Fab fragment. The Fab fragment was also successfully applied for antigen detection in immunohistochemical analyses. Therefore, the recombinant Fab fragment of IN-1 shows full functionality in vitro and appears to be well suited for replacing the monoclonal IgM in investigations on fiber tract regeneration in vivo.

Fermenter production of an artificial fab fragment, rationally designed for the antigen cystatin, and its optimized crystallization through constant domain shuffling.

The synthetic antibody model "M41" was rationally designed with a binding site complementary to chicken egg white cystatin as the prescribed antigen. In order to permit comparison between the computer model and an experimental three-dimensional structure of the artificial protein, its X-ray crystallographic analysis was pursued. For this purpose, M41 was expressed as a recombinant Fab fragment in E. coli by medium cell density fermentation employing the tightly regulated tetracycline promoter. The Fab fragment was efficiently purified via a His-6 tail fused to its heavy chain and immobilized metal affinity chromatography. To raise the chances for the productive formation of crystal packing contacts, three versions of the Fab fragment were generated with differing constant domains. One of these, the variant with murine C kappa and CH1 gamma 1 domains, was successfully crystallized by microseeding in a sitting drop. The orthorhombic crystals exhibited symmetry of the space group P2(1)2(1)2(1) with unit cell dimensions a = 104.7 A, b = 113.9 A, c = 98.8 A and diffracted X-rays to a nominal resolution of 2.5 A.