Generation of chimeric monoclonal antibodies from mice that carry human immunoglobulin Cgamma1 heavy of Ckappa light chain gene segments.

Gene targeting in mouse embryonic stem (ES) cells was used to replace (i) the mouse immunoglobulin heavy chain (IgH) Cgamma2a gene segment (mCgamma2a) with the human Cgamma1 gene segment (hCgamma1), and (ii) the mouse immunoglobulin light chain (IgL) Ckappa gene segment (mC kappa) with its human counterpart (hC kappa). ES cells carrying these gene conversions were used to generate chimeric mice that transmitted the human alleles through the germ line. Mice homozygous for both gene alterations were generated by breeding. Serum from homozygous mutant mice contained comparable amounts of antibodies with chimeric kappa or mouse lambda light chains but only small fractions of basal serum IgG or antibodies elicited against immunizing agents contained chimeric heavy chains. A relative increase in immunogen-specific hCgamma1 antibodies was seen following immunization in combination with the saponin adjuvant QS-21. The effect of this was to shift the IgG1-dominated response to an IgG subclass profile that included significant amounts of IgG2a, IgG2b and IgG3 and chimeric IgG. The amounts of antibody secreted by hybridomas derived from mutant and wild-type mice were similar. Sequencing confirmed correct splicing of hCgamma1 and hCkappa gene segments to mouse J gene segments in hybridoma Ig gene transcripts. In conclusion, IgHhCgamma1/IgLhCkappa double mutant mice provide a useful animal model for deriving humanized antibodies with potential applications in immunotherapy and diagnostics in vivo as well as for investigating hCgamma1 associated functions.

Molecular analysis of anti-idiotypic monoclonal antibodies in the HLA-DR antigenic system.

The structural organization of anti-idiotypic (id) antibodies has been investigated mostly in haptenic systems. No information is available about the structural characteristics of anti-id antibodies in major histocompatibility complex (MHC) antigenic systems, although these data may contribute to our understanding of the molecular basis of their functional role in the immune response. Therefore, we have determined the nucleotide and derived amino acid sequence of the VH and VL regions of the anti-id monoclonal antibodies (mAb) F5-444, F5-830, F5-963, F5-1126, F5-1336 and F5-1419, which had been elicited with the syngeneic anti-HLA-DR1, 4, w14, w8, 9 mAb AC1.59. The six anti-id mAb are heterogenous in their VH and VL region gene usage. This structural heterogeneity is not correlated with their target specificity and with their ability to elicit anti-HLA-DR antibodies. The latter characteristic is markedly influenced by a limited number of amino acid substitutions, since mAb F5-444, which induces anti-HLA-DR antibodies, differs only in two residues in complementarity-determining regions and in five residues in framework regions from mAb F5-1126, which does not induce anti-HLA-DR antibodies. The heterogeneity in VH and VL region gene usage by the six anti-id mAb in the HLA-DR system is at variance with the restricted VH and VL region gene usage by syngeneic anti-id mAb in several haptenic systems. Furthermore, at variance with haptenic systems, the primary structure of the D segments of the anti-id mAb is not correlated with their ability to induce anti-HLA-DR antibodies. On the other hand, the frequency of D-D fusion events underlying the derivation of the D segments of the six anti-id mAb in the HLA-DR system and their average length are similar to those found in anti-id mAb in haptenic systems. In addition, like in the latter systems, somatic mutations appear to contribute to the generation of diversity of anti-id mAb in the HLA-DR system.

Construction, bacterial expression and characterization of a bifunctional single-chain antibody-phosphatase fusion protein targeted to the human erbB-2 receptor.

We have constructed genes expressing single-chain antigen binding proteins (scFv) which recognize the human erbB-2 receptor. These genes encode the heavy and light chain variable domains of an erbB-2 receptor specific monoclonal antibody, MAb FRP5, connected by a peptide linker. In order to express a bifunctional molecule, a bacterial alkaline phosphatase gene was fused 3' to the scFv gene. The scFv(FRP5) and scFv(FRP5)-alkaline phosphatase fusion protein (scFv(FRP5)-PhoA) expressed in E. coli specifically recognize the human erbB-2 protein and compete with MAb FRP5 for binding to the receptor. The bound scFv(FRP5)-PhoA protein can be detected directly on tumor cells using a substrate for alkaline phosphatase, showing that the chimeric protein retains both binding and enzymatic activity.

Application of genetically-engineered anti-CEA antibodies for potential immunotherapy of colorectal cancer.

Hitherto anti-CEA monoclonal antibodies (MAbs), normally of mouse origin, have been used primarily for clinical diagnosis of colorectal cancer, either as a tumor marker in serum to monitor tumor recurrence, or latterly as a means to localize in vivo CEA-bearing tumors, and metastases in patients. In vivo diagnosis using mouse anti-CEA MAbs has so far had limited clinical utility because the antibodies elicit a strong anti-mouse immunoglobulin immune response on repeated administration in man. This problem has been addressed by the development of various strategies for "humanization" of mouse anti-CEA MAbs by genetic manipulation of immunoglobulin genes. Such humanized, engineered antibodies markedly attenuate the antigenic response directed against the MAb, such that safe, repeated administration to patients has become feasible. Such humanized anti-CEA antibodies can thus be radioactively-labelled and applied for in vivo monitoring and detection of recurrent malignant disease, or used for therapeutic strategies which similarly take advantage of the ability of the antibodies to target cytotoxic agents selectively to tumor cells. The application of these novel procedures for manipulating MAb structure presents entirely new opportunities for diagnosis and treatment of human colorectal cancer.

Selective cloning of B cell hybridoma-specific rearranged immunoglobulin gene loci using the polymerase chain reaction.

The use of conventional DNA cloning procedures to obtain productively rearranged Ig genes from B cell hybridomas for structure/function analysis of immunoglobulins is tedious and time-consuming. Here we describe a procedure based on PCR which permits rapid, selective isolation of DNA segments containing individual hybridoma-specific Ig gene rearrangements. The method, an adaptation of the so-called 'inverted PCR' technique (IPCR), can be applied most efficiently to specific genes where a preliminary restriction map is available from Southern blot analysis of the hybridoma genomic DNA. To achieve amplification of a given rearranged Ig locus, small amounts of total hybridoma DNA are digested to completion with a chosen restriction endonuclease and the fragments circularised by DNA ligase. Cleavage of the DNA circles using a second restriction enzyme, chosen specifically to cut 3' to a rearranged V-(D)-J exon, leads to linear DNA segments where the rearranged gene is now flanked by segments of known nucleotide sequence derived originally from the 3' region of the Ig H or L chain gene locus. This permits the selection of oligonucleotides that provide convergent primers for specific amplification of DNA segments containing the required gene rearrangement. Amplified DNA fragments can be cloned and rapidly characterised by sequence analysis.