Scientific Best Practices for Primary Sequence Confirmation and Sequence Variant Analysis in the Development of Therapeutic Proteins.

In this commentary, we will provide a high-level introduction into LC-MS product characterization methodologies deployed throughout biopharmaceutical development. The ICH guidelines for early and late phase filings is broad so that it is applicable to diverse biotherapeutic products in the clinic and industry pipelines. This commentary is meant to address areas of protein primary sequence confirmation and sequence variant analysis where ambiguity exists in industry on the specific scope of work that is needed to fulfill the general guidance that is given in sections Q5b and Q6b. This commentary highlights the discussion and outcomes of two recent workshops centering on the application of LC-MS to primary structure confirmation and sequence variant analysis (SVA) that were held at the 2018 and 2019 CASSS Practical Applications of Mass Spectrometry in the Biotechnology Industry Symposia in San Francisco, CA and Chicago, IL, respectively. Recommendations from the conferences fall into two distinct but related areas; 1) consolidation of opinions amongst industry stakeholders on the specific definitions of peptide mapping and peptide sequencing for primary structure confirmation and the technologies used for both, as they relate to regulatory expectations and submissions and 2) development of fit-for-purpose strategy to define appropriate assay controls in SVA experiments.

Control of Antibody Impurities Induced by Riboflavin in Culture Media During Production.

During the manufacturing of protein biologics, product variability during cell culture production and harvest needs to be actively controlled and monitored to maintain acceptable product quality. To a large degree, variants that have previously been described are covalent in nature and are easily analyzed by a variety of techniques. Here, we describe a noncovalent post translational modification of recombinantly expressed antibodies, containing variable domain tryptophans, that are exposed to culture media components and ambient laboratory light. The modified species, designated as conformer, can be monitored by hydrophobic interaction chromatography and often exhibits reduced potency. We studied conformer formation and identified key elements driving its accelerated growth using an IgG2 monoclonal antibody. Conformer is a result of a noncovalent interaction of the antibody with riboflavin, an essential vitamin added to many production cell culture formulations. Chemical and physical factors that influence the impact of riboflavin are identified, and methods for process control of this product quality attribute are addressed in order to prevent loss of antibody potency and potential safety issues. Identifying therapeutic antibody drug candidates with the potential to form conformers can be performed early in development to avoid this undesirable product quality propensity.

Native size-exclusion chromatography-mass spectrometry: suitability for antibody-drug conjugate drug-to-antibody ratio quantitation across a range of chemotypes and drug-loading levels.

Native size-exclusion chromatography-mass spectrometry (nSEC-MS) is an analytical methodology that is appropriate for accurately quantitating the drug-to-antibody ratio (DAR) on a wide variety of interchain cysteine-linked antibody-drug conjugates (ADCs), irrespective of chemotype. In the current preclinical environment, novel ADCs conjugated with unique drug-linkers need to progress toward the clinic as quickly as possible. Platform analytical approaches can reduce time-to-clinic because key process development and optimization activities can be decoupled from the development of bespoke, molecule-specific analytical methods. In this work, we assessed the potential of nSEC-MS as a platformable, quantitative DAR method. The nSEC-MS method was evaluated according to performance characteristics and parameters described in the ICH guideline Validation of Analytical Procedures: Text and Methodology Q2(R1). In order to comprehensively assess the accuracy and bias of nSEC-MS DAR quantitation, ADCs were generated using three different drug-linker chemotypes with DARs ranging from 2 to 8. These molecules were tested by hydrophobic interaction chromatography (HIC) and nSEC-MS, and DARs obtained from both methods were compared to assess the degree to which nSEC-MS quantitation aligned with the HIC release assay. Our results indicated that there is no bias introduced by nSEC-MS quantitation of DAR and that SEC-MS data can be bridged to HIC data without the need for a correction factor or offset. nSEC-MS was also found to be suitable for unbiased DAR quantitation in the other ADC chemotypes that were evaluated. Based on the totality of our work, we conclude that, used as intended, nSEC-MS is well suited for quantitating DAR on a variety of interchain cysteine-linked ADCs in an accurate, unbiased manner.

Localized conformational interrogation of antibody and antibody-drug conjugates by site-specific carboxyl group footprinting.

Establishing and maintaining conformational integrity of monoclonal antibodies (mAbs) and antibody-drug conjugates (ADCs) during development and manufacturing is critical for ensuring their clinical efficacy. As presented here, we applied site-specific carboxyl group footprinting (CGF) for localized conformational interrogation of mAbs. The approach relies on covalent labeling that introduces glycine ethyl ester tags onto solvent-accessible side chains of protein carboxylates. Peptide mapping is used to monitor the labeling kinetics of carboxyl residues and the labeling kinetics reflects the conformation or solvent-accessibility of side chains. Our results for two case studies are shown here. The first study was aimed at defining the conformational changes of mAbs induced by deglycosylation. We found that two residues in CH2 domain (D268 and E297) show significantly enhanced side chain accessibility upon deglycosylation. This site-specific result highlighted the advantage of monitoring the labeling kinetics at the amino acid level as opposed to the peptide level, which would result in averaging out of highly localized conformational differences. The second study was designed to assess conformational effects brought on by conjugation of mAbs with drug-linkers. All 59 monitored carboxyl residues displayed similar solvent-accessibility between the ADC and mAb under native conditions, which suggests the ADC and mAb share similar side chain conformation. The findings are well correlated and complementary with results from other assays. This work illustrated that site-specific CGF is capable of pinpointing local conformational changes in mAbs or ADCs that might arise during development and manufacturing. The methodology can be readily implemented within the industry to provide comprehensive conformational assessment of these molecules.

Antibody structural integrity of site-specific antibody-drug conjugates investigated by hydrogen/deuterium exchange mass spectrometry.

We present the results of a hydrogen/deuterium exchange mass spectrometric (HDX-MS) investigation of an antibody-drug conjugate (ADC) comprised of drug-linkers conjugated to cysteine residues that have been engineered into heavy chain (HC) fragment crystallizable (Fc) domain at position 239. A side-by-side comparison of the HC Ser239 wild type (wt) monoclonal antibody (mAb) and the engineered Cys239 mAb indicates that site directed mutagenesis of Ser239 to cysteine has no impact on the HDX kinetics of the mAb. According to the crystal structure of a homologous immunoglobulin G1 (IgG1) antibody (PDB: 1HZH ), the backbone amide of Ser239 is hydrogen-bonded to Val264 backbone amide in the wt-mAb studied here. Replacing Ser239 with a Cys residue does not alter the exchange kinetics of the backbone amide of Val264 suggesting that either Ser or Cys at position 239 has similar amide-hydrogen bonding with Val264. However, a small segment in CH2 domain of the ADC ((264)VDVS) was found to have a slightly increased HDX rate compared to the wt- and C239-mAb constructs. The slightly increased HDX rate of the segment (264)VDVS in ADCs indicates that the further modification of Cys239 with drug-linkers only attenuates the local backbone amide hydrogen-bonding network between Cys239 and Val264. All other regions which are proximal to the site of drug conjugation are unaffected. The results demonstrate that the site-specific drug conjugation at the engineered Cys residue at the position 239 of HC does not impact the structural integrity of antibodies. The results also highlight the utility of applying HDX-MS to ADCs to gain a molecular level insight into the impact of site-specific conjugation technologies on the higher-order structure (HOS) of mAbs. The methodology can be applied generally to site-specific ADC modalities to understand the individual contributions of site-mutagenesis and drug-linker conjugation on the HOS of therapeutic candidate ADCs.

Solid-state mAbs and ADCs subjected to heat-stress stability conditions can be covalently modified with buffer and excipient molecules.

We report that a unique type of chemical modification occurs on lyophilized proteins. Freeze-dried mAbs and antibody-drug conjugates (ADCs) can be covalently modified with buffer and excipient molecules on the side chains of Glu, Asp, Thr, and Ser amino acids when subjected to temperature stress. The reaction occurs primarily via condensation of common buffers and excipients such as histidine, tris, trehalose and sucrose, with Glu and Asp carboxylates in the primary sequence of proteins. The reaction was also found to proceed through condensation of carboxylate containing buffers such as citrate, with Thr and Ser hydroxyls in the primary sequence of proteins. Based on the mass of the covalent adducts observed on mAbs and ADCs, it is apparent that the reaction produces water as a product and is thus favored in a low moisture environments such as a lyophilized protein cake. Herein, we present the evidence for the covalent modification of proteins drawn from case studies of in-depth characterization of heat-stressed mAbs and ADCs in the solid state. We also demonstrate how common charge variant assays such as imaged capillary isoelectric focusing and mass spectrometry can be used to monitor this specific class of protein modification.

Approaches to Interchain Cysteine-Linked ADC Characterization by Mass Spectrometry.

Therapeutic antibody-drug conjugates (ADCs) harness the cell-killing potential of cytotoxic agents and the tumor targeting specificity of monoclonal antibodies to selectively kill tumor cells. Recent years have witnessed the development of several promising modalities that follow the same basic principles of ADC based therapies but which employ unique cytotoxic agents and conjugation strategies in order to realize therapeutic benefit. The complexity and heterogeneity of ADCs present a challenge to some of the conventional analytical methods that industry has relied upon for biologics characterization. This current review will highlight some of the more recent methodological approaches in mass spectrometry that have bridged the gap that is created when conventional analytical techniques provide an incomplete picture of ADC product quality. Specifically, we will discuss mass spectrometric approaches that preserve and/or capture information about the native structure of ADCs and provide unique insights into the higher order structure (HOS) of these therapeutic molecules.

Conformation and dynamics of interchain cysteine-linked antibody-drug conjugates as revealed by hydrogen/deuterium exchange mass spectrometry.

Antibody-drug conjugates (ADCs) are protein therapeutics in which a target specific monoclonal antibody (mAb) is conjugated with drug molecules. The manufacturing of ADCs involves additional conjugation steps, which are carried out on the parent mAbs, and it is important to evaluate how the drug conjugation process impacts the conformation and dynamics of the mAb. Here, we present a comparative study of interchain cysteine linked IgG1 ADCs and the corresponding mAb by hydrogen/deuterium exchange mass spectrometry (HDX-MS). We found that ∼90% of the primary sequence of the ADC conjugated with either monomethyl auristatin E or F (vcMMAE/mcMMAF) displayed the same HDX kinetics as the mAb, indicating the ADCs and mAbs share very similar conformation and dynamics in solution. Minor increases in HDX kinetic rates were observed in two Fc regions in the ADCs relative to the mAb which indicated that both regions become more structurally dynamic and/or more solvent-accessible in the ADCs. The findings led to a subsequent inquiry into whether the local conformational changes were due to the presence of drugs on the interchain cysteine residues or the absence of intact interchain disulfides or both. To address this question, a side-by-side HDX comparison of ADCs, mAbs, reduced mAbs (containing 8 reduced interchain cysteine thiols), and partially reduced mAbs (conjugation process intermediate) was performed. Our results indicated that the slight increase in conformational dynamics detected at the two regions in the ADCs was due to the absence of intact interchain disulfide bonds and not the presence of vcMMAE or mcMMAF on the alkylated interchain cysteine residues. These results highlight the utility of HDX-MS for interrogating the higher-order structure of ADCs and other protein therapeutics.

Native intact mass determination of antibodies conjugated with monomethyl Auristatin E and F at interchain cysteine residues.

We present here a method for the rapid determination of the intact mass of noncovalently associated antibody heavy chains (HC) and light chains (LC) which result from the attachment of drug conjugates to interchain cysteine residues. By analyzing the antibody-drug conjugate (ADC) using native desalting conditions, we maintain the intact bivalent structure of the ADC, which ordinarily would decompose as a consequence of denaturing chromatographic conditions typically used for liquid chromatographic-mass spectrometric (LC-MS) analysis. The mass of the desalted ADC is subsequently determined using standard desolvation and ionization conditions. Methods presented previously in the literature for analyzing interchain cysteinyl-linked ADCs are either not amenable to online mass spectrometry or result in the denaturing dissociation of conjugated HC and LC during chromatographic separation and subsequent mass measurement. We have avoided this outcome with our method and have successfully and routinely obtained intact mass measurement of IgG1 mAbs conjugated with maleimidocaproyl-monomethyl Auristatin F (mcMMAF) and valine-citrulline-monomethyl Auristatin E (vcMMAE) at interchain cysteine residues. Our results thus represent the first reported direct measurement of the intact mass of an ADC conjugated at interchain cysteine residues.

Photochemical degradation of citrate buffers leads to covalent acetonation of recombinant protein therapeutics.

Novel acetone and aldimine covalent adducts were identified on the N-termini and lysine side chains of recombinant monoclonal antibodies. Photochemical degradation of citrate buffers, in the presence of trace levels of iron, is demonstrated as the source of these modifications. The link between degradation of citrate and the observed protein modifications was conclusively established by tracking the citrate decomposition products and protein adducts resulting from photochemical degradation of isotope labeled (13)C citrate by mass spectrometry. The structure of the acetone modification was determined by nuclear magnetic resonance (NMR) spectroscopy on modified-free glycine and found to correspond to acetone linked to the N-terminus of the amino acid through a methyl carbon. Results from mass spectrometric fragmentation of glycine modified with an acetone adduct derived from (13)C labeled citrate indicated that the three central carbons of citrate are incorporated onto protein amines in the presence of iron and light. While citrate is known to stoichiometrically decompose to acetone and CO(2) through various intermediates in photochemical systems, it has never been shown to be a causative agent in protein carbonylation. Our results point to a previously unknown source for the generation of reactive carbonyl species. This work also highlights the potential deleterious impact of trace metals on recombinant protein therapeutics formulated in citrate buffers.

Resolving disulfide structural isoforms of IgG2 monoclonal antibodies by ion mobility mass spectrometry.

Recombinant monoclonal antibodies are an important class of therapeutic agents that have found widespread use for the treatment of many human diseases. Here, we have examined the utility of ion mobility mass spectrometry (IMMS) for the rapid characterization of disulfide variants in intact IgG2 monoclonal antibodies. It is shown that IMMS reveals 2 to 3 gas-phase conformer populations for IgG2s. In contrast, a single gas-phase conformer is revealed using IMMS for both an IgG1 antibody and a Cys-232 --> Ser mutant IgG2, both of which are homogeneous with respect to disulfide bonding. This provides strong evidence that the observed IgG2 gas-phase conformers are related to disulfide bond heterogeneity. Additionally, IMMS analysis of redox enriched disulfide isoforms allows assignment of the mobility peaks to established disulfide bonding patterns. These data clearly illustrate how IMMS can be used to quickly provide information on the higher order structure of antibody therapeutics.

Glutamine-linked and non-consensus asparagine-linked oligosaccharides present in human recombinant antibodies define novel protein glycosylation motifs.

We report the presence of oligosaccharide structures on a glutamine residue present in the V(L) domain sequence of a recombinant human IgG2 molecule. Residue Gln-106, present in the QGT sequence following the rule of an asparagine-linked consensus motif, was modified with biantennary fucosylated oligosaccharide structures. In addition to the glycosylated glutamine, analysis of a lectin-enriched antibody population showed that 4 asparagine residues: heavy chain Asn-162, Asn-360, and light chain Asn-164, both of which are present in the IgG1 and IgG2 constant domain sequences, and Asn-35, which was present in CDR(L)1, were also modified with oligosaccharide structures at low levels. The primary sequences around these modified residues do not adhere to the N-linked consensus sequon, NX(S/T). Modeling of these residues from known antibody crystal structures and sequence homology comparison indicates that non-consensus glycosylation occurs on Asn residues in the context of a reverse consensus motif (S/T)XN located on highly flexile turns within 3 residues of a conformational change. Taken together our results indicate that protein glycosylation is governed by more diversified requirements than previously appreciated.

Asparagine-linked oligosaccharides present on a non-consensus amino acid sequence in the CH1 domain of human antibodies.

We report that N-linked oligosaccharide structures can be present on an asparagine residue not adhering to the consensus site motif NX(S/T), where X is not proline, described in the literature. We have observed oligosaccharides on a non-consensus asparaginyl residue in the C(H)1 constant domain of IgG1 and IgG2 antibodies. The initial findings were obtained from characterization of charge variant populations evident in a recombinant human antibody of the IgG2 subclass. HPLC-MS results indicated that cation-exchange chromatography acidic variant populations were enriched in antibody with a second glycosylation site, in addition to the well documented canonical glycosylation site located in the C(H)2 domain. Subsequent tryptic and chymotryptic peptide map data indicated that the second glycosylation site was associated with the amino acid sequence TVSWN(162)SGAL in the C(H)1 domain of the antibody. This highly atypical modification is present at levels of 0.5-2.0% on most of the recombinant antibodies that have been tested and has also been observed in IgG1 antibodies derived from human donors. Site-directed mutagenesis of the C(H)1 domain sequence in a recombinant-human IgG1 antibody resulted in an increase in non-consensus glycosylation to 3.15%, a greater than 4-fold increase over the level observed in the wild type, by changing the -1 and +1 amino acids relative to the asparagine residue at position 162. We believe that further understanding of the phenomenon of non-consensus glycosylation can be used to gain fundamental insights into the fidelity of the cellular glycosylation machinery.

O-fucosylation of an antibody light chain: characterization of a modification occurring on an IgG1 molecule.

We describe the characterization of an O-fucosyl modification to a serine residue on the light chain of a recombinant, human IgG1 molecule expressed in Chinese hamster ovary (CHO) cells. Cation exchange chromatography (CEX) and hydrophobic interaction chromatography (HIC) were used to isolate a Fab population which was 146 Da heavier than the expected mass. Isolated Fab fragments were treated with a reducing agent to facilitate mass spectrometric analysis of the reduced light chain (LC) and fragment difficult (Fd). An antibody light chain with a net addition of 146 Da was detected by mass spectrometric analysis of the modified Fab. A light chain tryptic peptide in complementarity determining region-1 (CDR-1) was subsequently identified with a net addition of 146 Da by a peptide map. Results from a nanospray infusion of the modified peptide into a linear ion trap mass spectrometer with electron transfer dissociation (ETD) functionality indicated that the modified residue was a serine at position 30 in the light chain. Acid hydrolysis of the modified tryptic peptide followed by fluorescent labeling with 2-aminoanthranilic acid (2AA) and HPLC comparison with monosaccharide standards confirmed the presence of fucose on the light chain peptide. The presence of O-fucose on an antibody has not been previously reported. Currently, O-fucose has been described as occurring on mammalian proteins with amino acid sequence motifs associated with epidermal growth factor (EGF)-like repeats or thrombospondin type 1 repeats (TSRs). The amino acid sequence around the modified Ser in the IgG1 molecule does not conform to any known O-fucosylation sequence motif and thus is the first description of this type of modification on a nonconsensus sequence in a mammalian protein.