Oscar Salas-Solano

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.

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.

Recent developments in DNA sequencing by capillary and microdevice electrophoresis

The present review covers papers published in the years 1997 and 1998 on DNA sequencing by capillary and microdevice electrophoresis. The article does not include other electrophoretic DNA applications such as analysis of oligonucleotides, genotyping, and mutational analysis. Capillary gel electrophoresis (CGE) is starting to become a viable competitor to slab gel electrophoresis for DNA sequencing. Commercially available multicapillary array sequencers are now entering sequencing facilities which to date have totally relied on traditional slab gel technology. CGE research on DNA sequencing therefore becomes increasingly concerned with the critical task of fine‐tuning the operational parameters to create robust sequencing systems. Electrophoretic microdevices are being considered the next technological step in DNA sequencing by electrophoresis.

Charge heterogeneity of monoclonal antibodies by multiplexed imaged capillary isoelectric focusing immunoassay with chemiluminescence detection.

Characterization of charge heterogeneity of recombinant monoclonal antibodies (mAbs) requires high throughput analytical methods to support clone selection and formulation screens. We applied the NanoPro technology to rapidly measure relative charge distribution of mAbs in early stage process development. The NanoPro is a multiplexed capillary-based isoelectric immunoassay with whole-column imaging detection. This assay offers specificity, speed and sensitivity advantages over conventional capillary isoelectric focusing (CIEF) platforms. After CIEF, charge variants are photochemically immobilized to the wall of a short coated capillary. Once immobilized, mAbs are probed using a secondary anti-IgG conjugated with horseradish peroxidase. After flushing away excess reagents, secondary antibodies bound to their targets are then detected by chemiluminescence upon incubation with peroxidase reactive substrates. Charge heterogeneity as determined by chemiluminescence was similar to that measured by conventional CIEF technology with absorbance detection for purified mAbs and contaminated mAbs derived directly from host cellular extract. Upon method optimization, the automated CIEF immunoassay was applied to several mAbs of varying isoelectric points, demonstrating the suitability of NanoPro as a rugged high-throughput product characterization tool. Furthermore, qualification of detection sensitivity, precision, and dynamic range are reported with discussion of its advantages as an alternative approach to rapidly characterize charge variants during process development of mAbs.

Investigation of Sample Preparation Artifacts Formed during the Enzymatic Release of N-Linked Glycans prior to Analysis by Capillary Electrophoresis

In the biotechnology industry, highly sensitive and accurate methods are required for monitoring glycosylation of therapeutic recombinant monoclonal antibodies (rMAbs) due to possible effects on bioactivity. At Genentech, a method employing PNGase F digestion, fluorescent labeling of released glycans, and analysis by capillary electrophoresis (CE) is used for routine monitoring of N-linked glycosylation during process development and quality control of therapeutic glycoproteins. In our laboratory, capillary electrophoresis-mass spectrometry (CE-MS) technology was developed to identify minor glycan species in assay and it revealed several unidentified isomeric species. Additional studies indicate that these species (1-10% total glycans) are sample preparation artifacts caused by base-catalyzed epimerization of N-acetylglucosamine (GlcNAc) at the reducing terminus by following the use of commercially available PNGase F and the supplied incubation buffer (pH 7.5). As these isomeric species directly impact the accuracy of the reported results, an optimized PNGase F release step is presented which minimizes and/or eliminates the formation of these artifacts. We have found that PNGase F incubation at pH 5.5 for IgG(1) rMAbs shows no significant decrease in enzyme activity while minimizing GlcNAc epimerization. Implementation of this change has resulted in a more accurate and robust CE-laser-induced fluorescence (LIF) assay and is generally applicable to any analysis requiring PNGase F digestion of rMAbs.

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.

High-Resolution Capillary Zone Electrophoresis with Mass Spectrometry Peptide Mapping of Therapeutic Proteins: Peptide Recovery and Post-translational Modification Analysis in Monoclonal Antibodies and Antibody–Drug Conjugates

Reversed phase liquid chromatography with mass spectrometry (RPLC-MS) peptide mapping is routinely used for interrogating molecular and structural attributes such as amino acid composition, sequence variants, and post-translational modifications (PTMs) in antibody-derived therapeutics. RPLC has some limitations that often impact the analysis of certain peptides including large hydrophobic peptides, hydrophilic di-/tripeptides and glycopeptides. Capillary zone electrophoresis with mass spectrometry (CZE-MS) has great potential for peptide mapping due to high efficiency and outstanding sensitivity. In this report we demonstrate the utility of CZE-MS as an orthogonal and complementary technique to RPLC-MS for peptide mapping analyses of antibody-drug conjugates (ADCs) and their parent antibodies. This work is based on high-resolution CZE-MS separation recently developed in our group, where a mixed aqueous-organic solvent system containing N,N-dimethylacetamide (DMA) or N,N-dimethylformamide (DMF) was used to improve the separation selectivity. The results described here show several advantages of CZE-MS for the analysis of small hydrophilic di-/tripeptides, large hydrophobic peptides, glycopeptides, and hydrophobic drug-linked peptides.

High-Resolution Capillary Zone Electrophoresis with Mass Spectrometry Peptide Mapping of Therapeutic Proteins: Improved Separation with Mixed Aqueous–Aprotic Dipolar Solvents (N,N-Dimethylacetamide and N,N-Dimethylformamide) as the Background Electrolyte

Peptide mapping with mass spectrometry (MS) detection is a powerful technique routinely used for interrogating physicochemical properties of proteins. Peptide mapping benefits from an efficient front-end separation to increase selectivity and reduce complexity prior to MS detection. The most commonly used method for peptide mapping is based on reverse phase liquid chromatography with mass spectrometry. Capillary zone electrophoresis with mass spectrometry (CZE-MS) is an orthogonal technique with growing attention for peptide mapping of biotherapeutic proteins due to its high efficiency and sensitivity. However, that growth has been slow due to poorer peptide resolution and method robustness compared to RPLC. Here we present results from optimization of CZE-MS peptide mapping separation using mixed aqueous-aprotic dipolar solvent (N,N-dimethylacetamide (DMA) and N,N-dimethylformamide (DMF), as the background electrolyte (BGE) to improve the separation performance. Addition of DMA or DMF to the BGE impacts separation selectivity through differential change in pKa of the peptides. The CZE-MS peptide mapping method with the modified BGE produced significant improvement in resolution over the conventional CZE-MS methods. The method was evaluated with both sheathless and sheathflow CE-MS ion sources.

BIOMEMS-768 DNA Sequencer

The Whitehead Institute has developed an automated DNA sequencer that will go into final Genome Center testing during the summer of 2001. The system comprises a total of 768 separation channels distributed over two plates. The working elements are 50-cm × 25-cm, 384-lane microfabricated glass elements, which undergo alternating electrophoresis and regeneration under use with an exchangeable sieving matrix. The microfluidic and sample transfer devices needed to service the plates are integrated into the same compact instrument. Concurrently with the instrument development we have developed all the protocols, materials and surface preparations to achieve matrix-limited separations of single-stranded DNA in the microfabricated plate format.