RESUMEN
BACKGROUND: The follicle-stimulating hormone (FSH)-receptor (FSHR) has been reported to be an attractive target for antibody therapy in human cancer. However, divergent immunohistochemical (IHC) findings have been reported for FSHR expression in tumor tissues, which could be due to the specificity of the antibodies used. METHODS: Three frequently used antibodies (sc-7798, sc-13935, and FSHR323) were validated for their suitability in an immunohistochemical study for FSHR expression in different tissues. As quality control, two potential therapeutic anti-hFSHR Ylanthia® antibodies (Y010913, Y010916) were used. The specificity criteria for selection of antibodies were binding to native hFSHR of different sources, and no binding to non-related proteins. The ability of antibodies to stain the paraffin-embedded Flp-In Chinese hamster ovary (CHO)/FSHR cells was tested after application of different epitope retrieval methods. RESULTS: From the five tested anti-hFSHR antibodies, only Y010913, Y010916, and FSHR323 showed specific binding to native, cell-presented hFSHR. Since Ylanthia® antibodies were selected to specifically recognize native FSHR, as required for a potential therapeutic antibody candidate, FSHR323 was the only antibody to detect the receptor in IHC/histochemical settings on transfected cells, and at markedly lower, physiological concentrations (ex., in Sertoli cells of human testes). The pattern of FSH323 staining noticed for ovarian, prostatic, and renal adenocarcinomas indicated that FSHR was expressed mainly in the peripheral tumor blood vessels. CONCLUSION: Of all published IHC antibodies tested, only antibody FSHR323 proved suitable for target validation of hFSHR in an IHC setting for cancer. Our studies could not confirm the previously reported FSHR overexpression in ovarian and prostate cancer cells. Instead, specific overexpression in peripheral tumor blood vessels could be confirmed after thorough validation of the antibodies used.
RESUMEN
This article describes the design of HuCAL (human combinatorial antibody library) PLATINUM, an optimized, second-generation, synthetic human Fab antibody library with six trinucleotide-randomized complementarity-determining regions (CDRs). Major improvements regarding the optimized antibody library sequence space were implemented. Sequence space optimization is considered a multistep process that includes the analysis of unproductive antibody sequences in order to, for example, avoid motifs such as potential N-glycosylation sites, which are undesirable in antibody production. Gene optimization has been used to improve expression of the antibody master genes in the library context. As a result, full-length IgGs derived from the library show both significant improvements in expression levels and less undesirable glycosylation sites when compared to the previous HuCAL GOLD library. Additionally, in-depth analysis of sequences from public databases revealed that diversity of CDR-H3 is a function of loop length. Based upon this analysis, the relatively uniform diversification strategy used in the CDR-H3s of the previous HuCAL libraries was changed to a length-dependent design, which replicates the natural amino acid distribution of CDR-H3 in the human repertoire. In a side-by-side comparison of HuCAL GOLD and HuCAL PLATINUM, the new library concept led to isolation of about fourfold more unique sequences and to a higher number of high-affinity antibodies. In the majority of HuCAL PLATINUM projects, 100-300 antibodies each having different CDR-H3s are obtained against each antigen. This increased diversity pool has been shown to significantly benefit functional antibody profiling and screening for superior biophysical properties.