Protein PEGylation is the most clinically validated method to improve the efficacy of protein-based medicines. Antibody fragments such as Fabs display rapid clearance from blood circulation and therefore are good candidates for PEGylation. We have developed PEG-bis-sulfone reagents 1 that can selectively alkylate both sulfurs derived from a native disulfide. Using PEG-bis-sulfone reagents 1, conjugation of PEG specifically targets the disulfide distal to the binding region of the Fab (Scheme 2 ). PEG-bis-sulfone reagents 1 (10-40 kDa) were used to generate the corresponding PEG-mono-sulfones 2 that underwent essentially quantitative conjugation to give the PEG-Fab product 4. Four Fabs were PEGylated: Fab(beva), Fab'(beva), Fab(rani), and Fab(trast). Proteolytic digestion of bevacizumab with papain gave Fab(beva), while digestion of bevacizumab with IdeS gave F(ab')(2-beva), which after reaction with DTT and PEG-mono-sulfone 2 gave PEG(2)-Fab'(beva). Ranibizumab, which is a clinically used Fab, was directly PEGylated to give PEG-Fab(rani). Trastuzumab was proteolytically digested with papain, and its corresponding Fab was PEGylated to give PEG-Fab(trast). Purification of the PEGylated Fabs was accomplished by a single ion exchange chromatography step to give pure PEG-Fab products as determined by silver-stained SDS-PAGE. No loss of PEG was detected post conjugation. A comparative binding study by SPR using Biacore with low ligand immobilization density was conducted using (i) VEGF(165) for the bevacizumab and ranibizumab derived products or (ii) HER2 for the trastuzumab derived products. VEGF(165) is a dimeric ligand with two binding sites for bevacizumab. HER2 has one domain for the binding of trastuzumab. Binding studies with PEG-Fab(beva) indicated that the apparent affinity was 2-fold less compared to the unPEGylated Fab(beva). Binding properties of the PEG-Fab(beva) products appeared to be independent of PEG molecular weight. Site-specific conjugation of two PEG molecules gave PEG(2×20)-Fab'(beva), whose apparent binding affinity was similar to that observed for PEG-Fab(beva) derivatives. The k(d) values were similar to those of the unPEGylated Fab(beva); hence, once bound, PEG-Fab(beva) remained bound to the same degree as Fab(beva). Biacore analysis indicated that both Fab(rani) and PEG(20)-Fab(rani) did not dissociate from the immobilized VEGF at 25 °C, but ELISA using immobilized VEGF showed 2-fold less apparent binding affinity for PEG(20)-Fab(rani) compared to the unPEGylated Fab(rani). Additionally, the apparent binding affinities for trastuzumab and Fab(trast) were comparable by both Biacore and ELISA. Biacore results suggested that trastuzumab had a slower association rate compared to Fab(trast); however, both molecules displayed the same apparent binding affinity. This could have been due to enhanced rebinding effects of trastuzumab, as it is a bivalent molecule. Analogous to PEG-Fab(beva) products, PEG(20)-Fab(trast) displayed 2-fold lower binding compared to Fab(trast) when evaluated by ELISA. Th...
PEGylation is the covalent conjugation of PEG to therapeutic molecules. Protein PEGylation is a clinically proven approach for extending the circulation half-life and reducing the immunogenicity of protein therapeutics. Most clinically used PEGylated proteins are heterogeneous mixtures of PEG positional isomers conjugated to different residues on the protein main chain. Current research is focused to reduce product heterogeneity and to preserve bioactivity. Recent advances and possible future directions in PEGylation are described in this review. So far protein PEGylation has yielded more than 10 marketed products and in view of the lack of equally successful alternatives to extend the circulation half-life of proteins, PEGylation will still play a major role in drug delivery for many years to come.
IgG antibodies have evolved to be flexible so that they can bind to epitopes located over a wide spatial range. The two Fabs in an IgG antibody are linked together as if each Fab is at the end of a linear, flexible molecule. PEG was used as a scaffold molecule to link two Fabs together to give Fab-PEG-Fab molecules, or FpFs. Preparation of FpFs was achieved with reagents that undergo site-specific conjugation at each PEG terminus by bis-alkylation with the two cysteine thiols from a disulfide bond. This allowed each Fab to be conjugated to the PEG scaffold in essentially the same region that each Fab is linked in an IgG. Fabs were sourced directly (e.g., ranibizumab) or monoclonal IgG antibodies were proteolytically digested to obtain the Fabs. This allowed the resulting FpFs to be directly compared to parent IgGs. PEG scaffolds of 6, 10, and 20 kDa were used to make the corresponding FpFs. Dynamic light scatting data suggested the resulting FpFs were similar in size to an IgG antibody and about half the size of a 20 kDa PEGylated-Fab. The solution size of PEG-conjugated proteins is known to be dominated by the extended solution structure of PEG, so it is thought that the smaller size of the FpFs is due to interactions between the two Fabs. Anti-VEGF and anti-Her2 FpFs were prepared and evaluated. The FpFs displayed similar apparent affinities to their parent IgGs. Slower dissociation rates were observed for the anti-VEGF FpFs compared to bevacizumab. The anti-VEGF FpFs also displayed in vitro anti-angiogenic properties comparable to or better than bevacizumab. These first studies indicate that FpFs warrant further examination in a therapeutic indication where the presence of the Fc may not be required.
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