Significance mAbs are increasingly being used for treatment of chronic diseases wherein the subcutaneous delivery route is preferred to enable self-administration and at-home use. To deliver high doses (several hundred milligrams) through a small volume (∼1 mL) into the subcutaneous space, mAb solutions need to have low viscosity. Concomitantly, acceptable chemical stability is required for adequate shelf life, and normal in vivo clearance is needed for less frequent dosing. We propose in silico tools that provide rapid assessment of atypical behavior of mAbs (high viscosity, chemical degradation, and fast plasma clearance), which are simply predicted from sequence and/or structure-derived parameters. Such analysis will greatly improve the probability of success to move mAb-based therapeutics efficiently into clinical development and ultimately benefit patients.
A systematic analytical approach combining tryptic and chymotryptic peptide mapping with a Mascot Error Tolerant Search (ETS) has been developed to detect and identify low level protein sequence variants, i.e., amino acid substitutions, in recombinant monoclonal antibodies. The reversed-phase HPLC separation with ultraviolet (UV) detection and mass spectral acquisition parameters of the peptide mapping methods were optimized by using a series of model samples that contained low levels (0.5-5.0%) of recombinant humanized anti-HER2 antibody (rhumAb HER2) along with another unrelated recombinant humanized monoclonal antibody (rhumAb A). This systematic approach's application in protein sequence variant analysis depends upon time and sensitivity constraints. An example of using this approach as a rapid screening assay is described in the first case study. For stable CHO clone selection for an early stage antibody project, comparison of peptide map UV profiles from the top four clone-derived rhumAb B samples quickly detected two sequence variants (M83R at 5% and P274T at 42% protein levels) from two clones among the four. The second case study described in this work demonstrates how this approach can be applied to late stage antibody projects. A sequence variant, L413Q, present at 0.3% relative to the expected sequence of rhumAb C was identified by a Mascot-ETS for one out of four top producers. The incorporation of this systematic sequence variant analysis into clone selection and the peptide mapping procedure described herein have practical applications for the biotechnology industry, including possible detection of polymorphisms in endogenous proteins.
The reaction of singlet oxygen with water to form hydrogen peroxide was catalyzed by antibodies and has been termed as the antibody catalyzed water oxidation pathway (ACWOP) (Nieva and Wentworth, Trends Biochem. Sci. 2004, 29, 274-278; Nieva et al. Immunol. Lett. 2006, 103, 33-38). While conserved and buried tryptophans in the antibody are thought to play a major role in this pathway, our studies with a monoclonal antibody, mAb-1 and its mutant W53A, clearly demonstrate the role of surface-exposed tryptophans in production of hydrogen peroxide, via the photo-oxidation pathway. Reactive oxygen species (ROS) such as singlet oxygen and superoxide were detected and site-specific tryptophan (Trp53) oxidation was observed under these conditions using RP-HPLC and mass spectrometry. The single mutant of the surface exposed Trp53 to Ala53 (W53A) results in a 50% reduction in hydrogen peroxide generated under these conditions, indicating that surface exposed tryptophans are highly efficient in transferring light energy to oxygen and contribute significantly to ROS generation. ACWOP potentially leads to the chemical instability of mAb-1 via the generation of ROS and is important to consider during clinical and pharmaceutical development of mAbs.
Bispecific antibodies have great potential to be the next-generation biotherapeutics due to their ability to simultaneously recognize two different targets. Compared to conventional monoclonal antibodies, knob-into-hole bispecific antibodies face unique challenges in production and characterization due to the increase in variant possibilities, such as homodimerization in covalent and noncovalent forms. In this study, a storage- and pH-sensitive hydrophobic interaction chromatography (HIC) profile change was observed for the hole-hole homodimer, and the multiple HIC peaks were explored and shown to be conformational isomers. We combined traditional analytical methods with hydrogen/deuterium exchange mass spectrometry (HDX MS), native mass spectrometry, and negative-staining electron microscopy to comprehensively characterize the hole-hole homodimer. HDX MS revealed conformational changes at the resolution of a few amino acids overlapping the C2-C3 domain interface. Conformational heterogeneity was also assessed by HDX MS isotopic distribution. The hole-hole homodimer was demonstrated to adopt a more homogeneous conformational distribution during storage. This conformational change is likely caused by a lack of C3 domain dimerization (due to the three "hole" point mutations), resulting in a unique storage- and pH-dependent conformational destabilization and refolding of the hole-hole homodimer Fc. Compared with the hole-hole homodimer under different storage conditions, the bispecific heterodimer, guided by the knob-into-hole assembly, proved to be a stable conformation with homogeneous distribution, confirming its high quality as a desired therapeutic. Functional studies by antigen binding and neonatal Fc receptor (FcRn) binding correlated very well with the structural characterization. Comprehensive interpretation of the results has provided a better understanding of both the homodimer variant and the bispecific molecule.
Capillary isoelectric focusing (cIEF) is widely used in the biopharmaceutical industry to measure the charge distribution of therapeutic proteins. The implementation of this technology has created a new challenge. Capillary volumes are on the order of hundreds of nanoliters and cannot be scaled up for the preparative collection of charge variants. This makes it difficult to identify the charge variants in a cIEF electropherogram. Therefore, preparative IEF methods are needed to fractionate charge variants for characterization. We used free-flow electrophoresis (FFE) to isolate monoclonal antibody charge variants observed in a cIEF electropherogram. The same antibody was also fractionated using the Rotofor and Offgel instruments for comparison. A strategy for purifying the fractionated charge variants and downstream characterization is described. Acidic and basic variants were identified and related back to the analytical cIEF charge profile. This study establishes free-flow isoelectric focusing as a valuable tool for characterizing therapeutic proteins.
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