Histidine residue mediates radical-induced hinge cleavage of human IgG1.

Hydroxyl radicals induce hinge cleavage in a human IgG1 molecule via initial radical formation at the first hinge Cys(231) followed by electron transfer to the upper hinge residues. To enable engineering of a stable monoclonal antibody hinge, we investigated the role of the hinge His(229) residue using structure modeling and site-directed mutagenesis. Direct involvement of His(229) in the reaction mechanism is suggested by a 75-85% reduction of the hinge cleavage for variants in which His(229) was substituted with either Gln, Ser, or Ala. In contrast, mutation of Lys(227) to Gln, Ser, or Ala increased hinge cleavage. However, the H229S/K227S double mutant shows hinge cleavage levels similar to that of the single H229S variant, further revealing the importance of His(229). Examination of the hinge structure shows that His(229) is capable of forming hydrogen bonds with surrounding residues. These observations led us to hypothesize that the imidazole ring of His(229) may function to facilitate the cleavage by forming a transient radical center that is capable of extracting a proton from neighboring residues. The work presented here suggests the feasibility of engineering a new generation of monoclonal antibodies capable of resisting hinge cleavage to improve product stability and efficacy.

Human IgG1 hinge fragmentation as the result of H2O2-mediated radical cleavage.

Hinge cleavage of a recombinant human IgG1 antibody, generated during production in a Chinese hamster ovary cell culture, was observed in the purified material. The cleavage products could be reproduced by incubation of the antibody with H(2)O(2) and featured complementary ladders of the C- and N-terminal residues (Asp(226)-Lys(227)-Thr(228)-His(229)-Thr(230)) in the heavy chain of the Fab domain and the upper hinge of one of the Fc domains, respectively. Two adducts of +45 and +71 Da were also observed at the N-terminal residues of some Fc fragments and were identified as isocyanate and alpha-ketoacyl derivatives generated by radical cleavage at the alpha-carbon position through the diamide and alpha-amidation pathways. We determined that the hinge cleavage was initiated by radical-induced breakage of the disulfide bond between the two hinge cysteines at position 231 (Cys(231)-Pro-Pro-Cys-Pro), followed by the formation of a thiyl radical (Cys(231)-S(*)) on one cysteine and sulfenic acid (Cys(231)-SOH) on the other. The location of the initial radical attack and the critical role of Cys(231) were demonstrated by the observation that 5,5-dimethyl-1-pyrroline N-oxide only reacted with the Cys(231) radical and completely blocked hinge cleavage, suggesting the necessity of an electron/radical transfer from the Cys(231) radical to the hinge residues where cleavage was observed. As a precursor of hydroxyl radicals, H(2)O(2) is widely produced in healthy cells and tissues and therefore could be the source for the radical-induced fragmentation of human IgG1 antibodies in vivo.

Succinimide formation at Asn 55 in the complementarity determining region of a recombinant monoclonal antibody IgG1 heavy chain.

We investigated the formation and stability of succinimide, an intermediate of deamidation events, in recombinant monoclonal antibodies (mAbs). During the course of an analytical development study of an IgG1 mAbs, we observed that a specific antibody population could be separated from the main product by cation-exchange (CEX) chromatography. The cell-based bioassay measured a approximately 70% drop in potency for this fraction. Liquid chromatography time-of-flight mass spectrometry (LC-TOF/MS) and tandem mass spectrometry (LC-MS/MS) analyses showed that the modified CEX fraction resulted from the formation of a succinimide intermediate at Asn 55 in the complementarity determining region (CDR) of the heavy chain. Biacore assay revealed a approximately 50% decrease in ligand binding activity for the succinimide-containing Fab with respect to the native Fab. It was found that the succinimide form existed as a stable intermediate with a half-life of approximately 3 h at 37 degrees C and pH 7.6. Stress studies indicated that mildly acidic pH conditions (pH 5) favored succinimide accumulation, causing a gradual loss in potency. Hydrolysis of the succinimide resulted in a further drop in potency. The implications of the succinimide formation at Asn 55, a highly conserved residue among IgG1 (mAbs), are discussed.

Analysis of human antibody IgG2 domains by reversed-phase liquid chromatography and mass spectrometry.

It has been well documented that papain cleaves an IgG1 molecule to release Fab and Fc domains; however, papain was found unable to release such domains from an IgG2. Here we present a new combinatory strategy to analyze the heterogeneity of the light chain (LC), single chain Fc (sFc), and Fab portion of the heavy chain (Fd) of an IgG2 molecule released by papain cleavage under mild reducing conditions. These domains were well separated on reversed-phase high performance liquid chromatography (RP-HPLC) and analyzed by in-line liquid chromatography time-of-flight mass spectrometry (LC-TOF/MS). In addition, some modifications of these domains were revealed by in-line mass spectrometry, and confirmed by the peptide mapping on LC-MS/MS analysis. This same strategy was proven suitable for IgG1 molecules as well. This procedure provides a simplified approach for the characterization of antibody biomolecules by facilitating the detection of low-level modifications in a domain. In addition, the technique offers a new strategy as an identification assay to distinguish IgG2 molecules on RP-HPLC, by which highly conserved Fc domains remain at a constant retention time (RT) unique to its subisotype, while varying RTs of the light chain and the Fd distinguish the monoclonal antibody from other molecules of the same isotype based on the underlying characteristics of each antibody.

Analysis of post-translational modifications in recombinant monoclonal antibody IgG1 by reversed-phase liquid chromatography/mass spectrometry.

Characterization and quantitative analysis of modifications in recombinant monoclonal antibodies (mAbs) plays an important role in biopharmaceutical development. This study demonstrates a new approach to assess variants in mAbs, based on individual analysis of subdomains. These subdomains were generated by dithiothreitol reduction and papain cleavage. A reversed-phase LC-MS method was developed that provides efficient separation of subdomains (light and heavy chains, Fab and Fc) containing several specific modifications such as pyroglutamic acid, deamidation, isomerization and oxidation. The best separation was achieved on Zorbax SB C8 columns using linear water-acetonitrile gradients in 0.1% trifluoroacetic acid. Deconvoluted electrospray ionization mass spectra of these domains revealed the modification profiles of these variants with high accuracy and resolution. This study presents a strategy that offers orthogonal approaches to analyze antibody variants, and provide a qualitative and quantitative assessment of mAb heterogeneity.