Site-specific conjugation of a cytotoxic drug to an antibody improves the therapeutic index.

Antibody-drug conjugates enhance the antitumor effects of antibodies and reduce adverse systemic effects of potent cytotoxic drugs. However, conventional drug conjugation strategies yield heterogenous conjugates with relatively narrow therapeutic index (maximum tolerated dose/curative dose). Using leads from our previously described phage display-based method to predict suitable conjugation sites, we engineered cysteine substitutions at positions on light and heavy chains that provide reactive thiol groups and do not perturb immunoglobulin folding and assembly, or alter antigen binding. When conjugated to monomethyl auristatin E, an antibody against the ovarian cancer antigen MUC16 is as efficacious as a conventional conjugate in mouse xenograft models. Moreover, it is tolerated at higher doses in rats and cynomolgus monkeys than the same conjugate prepared by conventional approaches. The favorable in vivo properties of the near-homogenous composition of this conjugate suggest that our strategy offers a general approach to retaining the antitumor efficacy of antibody-drug conjugates, while minimizing their systemic toxicity.

A new ELISA for use in a 3-ELISA system to assess concentrations of VEGF splice variants and VEGF(110) in ovarian cancer tumors.

BACKGROUND: Vascular endothelial growth factor (VEGF), which affects tumor angiogenesis, is expressed as different splice variants, including the major isoforms VEGF(165) and VEGF(121), and can be cleaved by plasmin to generate VEGF(110). The amount of VEGF(121) and VEGF(110) in biological samples has not been well studied. METHODS: We developed an ELISA that detects VEGF(165) and VEGF(121) equally, but does not detect VEGF(110). We used this ELISA together with 2 other ELISAs, one detecting VEGF(165) and the other detecting VEGF(165), VEGF(121), and VEGF(110) equally, to assess the concentrations of VEGF(121) and VEGF(110) in ovarian cancer tumors. RESULTS: The median concentrations in ovarian cancer tumor lysates were 0.61 (range <0.055-74) fmol/mg protein for VEGF(165), 1.4 (range <0.20-500) fmol/mg protein for VEGF(165) plus VEGF(121), and 2.3 (range <0.079-520) fmol/mg protein for total VEGF including VEGF(110) (n = 248). VEGF concentrations measured by the 3 ELISAs were highly correlated (r = 0.91-0.94). Median estimated VEGF(121) and VEGF(110) concentrations were 0.77 and 0.58 fmol/mg protein, respectively. In lysates with measurable VEGF(165) and total VEGF concentrations, mean VEGF(165) was approximately 31% (SD 23%) of the total VEGF (n = 217). In contrast, VEGF(165) constituted approximately half of the total circulating VEGF. CONCLUSION: VEGF(165), VEGF(121), and VEGF(110) may be present at significant amounts in ovarian cancer tumors.

Convergent and divergent ligand specificity among PDZ domains of the LAP and zonula occludens (ZO) families.

We present a detailed comparative analysis of the PDZ domains of the human LAP proteins Erbin, Densin-180, and Scribble and the MAGUK ZO-1. Phage-displayed peptide libraries and in vitro affinity assays were used to define ligand binding profiles for each domain. The analysis reveals the importance of interactions with all four C-terminal residues of the ligand, which constitute a core recognition motif, and also the role of interactions with more upstream ligand residues that support and modulate the core binding interaction. In particular, the results highlight the importance of site(-1), which interacts with the penultimate residue of ligand C termini. Site(-1) was found to be monospecific in the Erbin PDZ domain (accepts tryptophan only), bispecific in the first PDZ domain of ZO-1 (accepts tryptophan or tyrosine), and promiscuous in the Scribble PDZ domains. Furthermore, it appears that the level of promiscuity within site(-1) greatly influences the range of potential biological partners and functions that can be associated with each protein. These findings show that subtle changes in binding specificity can significantly alter the range of biological partners for PDZ domains, and the insights enhance our understanding of this diverse family of peptide-binding modules.