Megumi Tanaka

Generation of a humanized anti-glypican 3 antibody by CDR grafting and stability optimization.

Glypican 3 (GPC3), a glycosylphosphatidylinositol-anchored heparan sulfate proteoglycan, is expressed in a majority of hepatocellular carcinoma tissues. The murine monoclonal antibody GC33 that specifically binds to the COOH-terminal part of GPC3 causes strong antibody-dependent cellular cytotoxicity against hepatocellular carcinoma cells and exhibits strong antitumor activity in the xenograft models. To apply GC33 for clinical use, we generated a humanized GC33 from complementarity-determining region grafting with the aid of both the hybrid variable region and two-step design methods. The humanized antibody bound to GPC3 specifically and induced antibody-dependent cellular cytotoxicity as effectively as a chimeric GC33 antibody. To improve stability of the humanized GC33, we further optimized humanized GC33 by replacing the amino acid residues that may affect the structure of the variable region of a heavy chain. Substitution of Glu6 with Gln in the heavy chain significantly improved the stability under high temperatures. GC33 also has the risk of deamidation of the -Asn–Gly- sequence in the complementarity-determining region 1 of the light chain. As substitution of Asn diminished the antigen binding, we changed the neighboring Gly to Arg to avoid deamidation. The resulting humanized anti-GPC3 antibody was as efficacious as chimeric GC33 against the HepG2 xenograft and is now being evaluated in clinical trials.

VH/VL interface engineering to promote selective expression and inhibit conformational isomerization of thrombopoietin receptor agonist single-chain diabody

Thrombopoietin receptor agonist humanized VB22B single-chain diabody (hVB22B (scFv)(2)) was found to be expressed as a mixture of two conformational isomers, a single-chain diabody form and a bivalent scFv form, which had different V(H)/V(L) (variable region of the heavy chain/light chain) association patterns. The single-chain diabody form showed significantly higher biological activity than the bivalent scFv form and, when incubated at elevated temperatures, exhibited novel isomerization to the inactive bivalent scFv form. Therefore, therapeutic development of hVB22B (scFv)(2) would require separation of the purified single-chain diabody form from the mixture of the two conformational isomers and also inhibition of isomerization into an inactive bivalent scFv form during storage. Novel V(H)/V(L) interface engineering in hVB22 (scFv)(2), in which hydrogen bonding between H39 and L38 was substituted with electrostatic interaction to enhance the desired V(H)/V(L) association and inhibit the undesired V(H)/V(L) association, enabled selective expression of the desired conformational isomer without any reduction in biological activity or thermal stability. Moreover, V(H)/V(L) interface-engineered hVB22 (scFv)(2) was completely resistant to isomerization. Because the hydrogen bonding interaction between H39 and L38 and the surrounding residues are highly conserved in human antibody sequences, V(H)/V(L) interface engineering could be generally applied to various (scFv)(2) molecules for selective expression and inhibition of the isomerization of conformational isomers.

O-linked glucosylation of a therapeutic recombinant humanised monoclonal antibody produced in CHO cells.

An unpredictable modification of a therapeutic recombinant humanised monoclonal antibody (rh-mAbX) produced using CHO cells was found. LC/MS analysis of rh-mAbX indicated the presence of heterogeneity in the light chain with a corresponding mass shift of 162 Da compared to the theoretical mass. To characterise the heterogeneity, that is, the attached moiety, several analyses were performed. Peptide mapping of rh-mAbX indicated that the attached moiety was located in the amino acid sequence from Leu20 to Lys45, which is a part of the variable region of the light chain. The peptide was efficiently purified in two-steps by RP-HPLC by utilising two different types of RP columns. N-terminal sequencing and LC/MS/MS analysis of the peptide suggested that Ser29 of the light chain was the modification site, and that the attached moiety was a single O-linked hexose. HPAEC-PAD analysis following β-elimination indicated the presence of an O-linked glucose in the modified peptide. Monosaccharide composition analysis after acid hydrolysis supported this result. The content of antibodies containing this species was determined to be approximately 10% by Lys-C peptide mapping detected at 280 nm. Thus, this study demonstrated the formation of a unique O-linked glucosylation posttranslational modification in a recombinant humanised monoclonal antibody produced in CHO cells.