Cynthia P. Quan

Charge variants in IgG1: Isolation, characterization, in vitro binding properties and pharmacokinetics in rats

Antibody charge variants have gained considerable attention in the biotechnology industry due to their potential influence on stability and biological activity. Subtle differences in the relative proportions of charge variants are often observed during routine biomanufacture or process changes and pose a challenge to demonstrating product comparability. To gain further insights into the impact on biological activity and pharmacokinetics (PK) of monoclonal antibody (mAb) charge heterogeneity, we isolated the major charge forms of a recombinant humanized IgG1 and compared their in vitro properties and in vivo PK. The mAb starting material had a pI range of 8.7-9.1 and was composed of about 20% acidic variants, 12% basic variants, and 68% main peak. Cation exchange displacement chromatography was used to isolate the acidic, basic, and main peak fractions for animal studies. Detailed analyses were performed on the isolated fractions to identify specific chemical modification contributing to the charge differences, and were also characterized for purity and in vitro potency prior to being administered either subcutaneously (SC) or intravenously (IV) in rats. All isolated materials had similar potency and rat FcRn binding relative to the starting material. Following IV or SC administration (10 mg/kg) in rats, no difference in serum PK was observed, indicating that physiochemical modifications and pI differences among charge variants were not sufficient to result in PK changes. Thus, these results provided meaningful information for the comparative evaluation of charge-related heterogeneity of mAbs, and suggested that charge variants of IgGs do not affect the in vitro potency, FcRn binding affinity, or the PK properties in rats.

The effect of low intensity ultraviolet-C light on monoclonal antibodies

As part of an investigation to identify potential new viral reduction strategies, ultraviolet‐C (UV‐C) light was examined. Although this technology has been known for decades to possess excellent virus inactivation capabilities, UV‐C light can also introduce significant unwanted damage to proteins. To study the effect on monoclonal antibodies, three different antibodies were subjected to varying levels of UV‐C light using a novel dosing device from Bayer Technology Services GmbH. The range of fluencies (or doses) covered was between 0 and 300 J/m2 at a wavelength of 254 nm. Product quality data generated from the processed pools showed only minimal damage done to the antibodies. Aggregate formation was low for two of the three antibodies tested. Acidic and basic variants increased for all three antibodies, with the basic species increasing more than the acidic species. Peptide maps made for the three sets of pools showed no damage to two of the three antibody backbones, whereas the third antibody had very low levels of methionine oxidation evident. Samples held at 2–8°C for 33 days showed no increase in aggregates or charge variants, indicating that the proteins did not degrade and were not damaged further by reactive or catalytic species that may have been created on exposure to UV‐C light. Overall, UV‐C light was shown to induce very little damage to monoclonal antibodies at lower fluencies and appears to be a viable option for viral inactivation in biotechnology applications.

Characterization of a tryptic digest by high-performance displacement chromatography and mass spectrometry☆

High-performance displacement chromatography (HPDC) provides a means of increasing the capacity of a chromatographic column, while maintaining the resolution afforded by high-performance liquid chromatographic (HPLC) instruments. The high capacity and high resolution of HPDC can be exploited in tryptic mapping to facilitate the characterization of a protein preparation. In this manner, minor constituents of the mixture, which may be difficult to isolate by conventional chromatographic methods, can be obtained in sufficient amounts to permit chemical characterization by established techniques. The isolation by HPDC of peptides obtained by digestion of recombinant human growth hormone (rhGH) and the subsequent characterization of the peptides are described. The identification of certain of these peptides revealed information on the specificity of trypsin for the substrate, rhGH, and for autolysis. Fractions from the HPDC tryptic map were collected and analyzed by electrospray ionization mass spectrometry (ESI-MS) either directly or following further separation by gradient elution HPLC. Fragment ions observed in the ESI mass spectra facilitated identification of peptides obtained by HPDC tryptic mapping.

Use of acidic and basic pH and calcium ion addition in the capillary zone electrophoretic characterization of recombinant human deoxyribonuclease, a complex phosphoglycoprotein

This paper describes the analysis of recombinant human deoxyribonuclease (rhDNAse), an acidic and complex phosphoglycoprotein, by capillary zone electrophoresis (CZE). Separation performance was found to be dramatically improved by the addition of calcium ions to the CZE running buffer, due to the influence of calcium binding on the charge and the electrophoretic behavior of rhDNAse. The pH dependent calcium binding effects on the electrophoretic separation were demonstrated at both acidic and basic pH, resulting in a two-dimensional (pH 4.8 and 8.0) calcium aided analysis that achieved multipeak resolution of the complex, glycosylation based, charge microheterogeneity of rhDNAse. Two-dimensional investigation of neuraminidase- and alkaline phosphatase-digested protein further demonstrated that the acidic pH resolved acidic charge heterogeneity and that the basic pH discriminated neutral heterogeneity. This work demonstrates the resolving power of CZE for the analysis of a complex microheterogeneous glycoprotein, and emphasizes the importance of employing multiple separation conditions in accordance with known structural characteristics of the protein.

Glycation of antibodies: Modification, methods and potential effects on biological functions

ABSTRACT Glycation is an important protein modification that could potentially affect bioactivity and molecular stability, and glycation of therapeutic proteins such as monoclonal antibodies should be well characterized. Glycated protein could undergo further degradation into advance glycation end (AGE) products. Here, we review the root cause of glycation during the manufacturing, storage and in vivo circulation of therapeutic antibodies, and the current analytical methods used to detect and characterize glycation and AGEs, including boronate affinity chromatography, charge-based methods, liquid chromatography-mass spectrometry and colorimetric assay. The biological effects of therapeutic protein glycation and AGEs, which ranged from no affect to loss of activity, are also discussed.

Structure-Based Correlation of Light-Induced Histidine Reactivity in A Model Protein

Light is known to induce covalently linked aggregates in proteins. These aggregates can be immunogenic and are of concern for drug product development in the biotechnology industry. Histidine (His) is proposed to be a key residue in cross-link generation ( Pattison , D. I. Photochem. Photobiol. Sci. 2012 , 11 , 38 - 53 ). However, the factors that influence the reactivity of His in proteins, especially the intrinsic factors are little known. Here, we used rhDNase, which only forms His-His covalent dimers after light treatment to determine the factors that influence the light-induced reactivity of His. This system allowed us to fully characterize the light-induced covalent dimer and rank the reactivities of the His residues in this protein. The reactivities of these His residues were correlated with solvent accessibility-related parameters both by crystal structure-based calculations of solvent-accessible surface area and by hydrogen-deuterium exchange (HDX) experiments. Through this correlation, we demonstrate that the photoreactivity of His is determined by both solvent accessibility and structural flexibility. This new insight can explain the highly complex chemistry of light-induced aggregation and help predict the aggregation propensity of protein under light treatment.

Light-Induced Covalent Buffer Adducts to Histidine in a Model Protein

PurposeLight is known to induce histidine (His) oxidation and His-His crosslinking in proteins. The crosslinking is resulted from the nucleophilic attack of a His to a photooxidized His from another protein. The goal of this work is to understand if covalent buffer adducts on His residues can be generated by light through similar mechanisms in nucleophilic buffers such as Tris and His.MethodsA model protein (DNase) was buffer exchanged into nucleophilic buffers before light exposure. Photogenerated products were characterized by tryptic peptide mapping with mass spectrometry (MS) analysis. Several buffer adductions on His residues were identified after light exposure. To understand the influencing factors of such reactions, the levels of adducts were measured for six nucleophilic buffers on all His residues in DNase.ResultsThe levels of adducts were found to correlate with the solvent accessibility of the His residue. The levels of adducts also correlate with the structure of the nucleophile, especially the steric restrictions of the nucleophile. The levels of adducts can be higher than that of other His photoreaction products, including photooxidation and crosslinking.ConclusionsIn nucleophilic buffers, light can induce covalently-linked adducts to His residues.

Effects of the Solution Environment on the Resolution of Recombinant Human Deoxyribonuclease Variants in Capillary Zone Electrophoresis

Capillary zone electrophoresis (CZE) is used to demonstrate the interaction of a protein analyte and the surrounding free solution environment, specifically the effects of hydrogen ion or divalent metal cation titration on the resolution of recombinant human deoxyribonuclease I (rhDNase) variants. Hydrogen ion titration of the CZE buffer solution environment observably alters the surface charges of the protein, leading to measurable changes in the electrophoretic mobility which correlates to the theoretical net average protein charge (Z). Similarly, divalent metal cations, when added to the CZE buffer solution, associate with the acidic rhDNase surface charges and lead to observable changes in electrophoretic mobility. Typically, conditions that led to decreased electrophoretic mobility of the protein also led to enhanced resolution of broad zones associated with the heterogeneity of the protein. Additional characterization of the observed heterogeneity distinguished between a distribution of associated ions and glycosylation variation as the source of the protein-associated heterogeneity.