Evaluation of Proteolytic Digestion Efficiency in Hydrogen Exchange-Mass Spectrometry Experiments Using the Digestible Peptide Score.

In a hydrogen exchange-mass spectrometry (HX-MS) experiment, the enzymatic proteolysis of the deuterated protein is an essential step. Often the differences in the performance between different digestion protocols or between immobilized protease columns can be challenging to evaluate. To compare differences in the performance of immobilized protease columns, a new digestion efficiency metric known as digestible peptide scoring (DPS) was developed and is presented in this work. The measured response fraction of substance P peptide is used to assign a value between 0% and 100% based on the fraction of substance P digested by the enzyme, using angiotensin II as an undigested internal standard. In this work, the DPS approach was tested using multiple immobilized pepsin batches prepared using different protocols. The results demonstrate the repeatability of DPS values for batches prepared using the same conditions and the ability of the DPS evaluations to provide unique values when the immobilization conditions were altered. Protein digestions obtained with a higher scoring column were better than digestions obtained using a lower scoring column. The DPS evaluation is simple and quickly provides an unambiguous assessment which can be used to evaluate an immobilized enzyme column's suitability prior to performing an experiment, to track performance over a column's lifetime, to optimize protease immobilization protocols specifically for the quench conditions of a particular experiment, and to optimize the digestion conditions.

Understanding the Effects of Site-Specific Light Chain Conjugation on Antibody Structure Using Hydrogen Exchange-Mass Spectrometry (HX-MS).

Antibody drug conjugates (ADCs) represent one of the fastest growing classes of cancer therapeutics. Drug incorporation through site-specific conjugation in ADCs leads to uniform drug load and distribution. These site-specific modifications may have an impact on ADC quality attributes including protein higher order structure (HOS), which might impact safety and efficacy. In this study, we conducted a side-by-side comparison between the conjugated and unconjugated mAb. In the ADC, the linker-pyrrolobenzodiazepine was site specifically conjugated to an engineered unpaired C215 residue within the Fab domain of the light chain. Differential scanning calorimetry (DSC) and differential scanning fluorimetry (DSF) indicated a decrease in thermal stability for the CH2 transition of the ADC. Size exclusion chromatography (SEC) analysis showed that conjugation of the mAb resulted in earlier aggregation onset and increased aggregation propensity after 4 weeks at 40 °C. Differential hydrogen-exchange mass spectrometry (HX-MS) indicated that upon conjugation, light chain residues 150-155 and 197-204, close to the conjugation site, showed significantly faster HX kinetics, suggesting an increase in backbone flexibility within this region, while heavy chain residues 32-44 exhibited significantly slower kinetics, suggesting distal stabilization of the mAb backbone.

Identification of Agitation-Induced Unfolding Events Causing Aggregation of Monoclonal Antibodies Using Hydrogen Exchange-Mass Spectrometry.

Due to significant safety tolerances on maximum levels of visible and sub-visible particles in parenterally dosed drug products like monoclonal antibodies (mAbs), particle formation rates must be determined during development and minimized. Agitation stress, encountered during transportation and manufacturing, increases particle formation rates in a protein and formulation dependent fashion in a phenomenon thought to be partially mediated by mAb adsorption to the continuously regenerating air-water interface that results from agitation. The goal of this study was to explore the structural dynamics of three mAbs with variable sensitivity to agitation to develop a mechanistic understanding of exactly what occurs at the air-water interface that leads to aggregation and particle formation. We observed preferential orientation at the interface and subsequent cooperative unfolding for the molecule which aggregates most extensively under agitation, and also that the magnitude of destabilization appears to scale with particle formation rates. We also show that polysorbate, a widely-used excipient in parenteral formulations to protect against particle formation, eliminates interface-induced destabilization. This study provides direct evidence that local unfolding events resulting from interface exposure precede particle formation and may play a causal role in the process.

Interaction of Aluminum-adjuvanted Recombinant P[4] Protein Antigen With Preservatives: Storage Stability and Backbone Flexibility Studies.

Eight antimicrobial preservatives used in parenteral multidose formulations (thimerosal, 2-phenoxy ethanol, phenol, benzyl alcohol, m-cresol, chlorobutanol, methyl paraben, propyl paraben) were examined for their effects on the storage stability (4 °C, 25 °C) of an Alhydrogel® (AH) adjuvanted formulation of the non-replicating rotavirus vaccine (NRRV) recombinant P[4] protein antigen. The stability of AH-adsorbed P[4] was monitored for antigen-antibody binding, conformational stability, and antigen-adjuvant interaction via competitive ELISA, DSC, and SDS-PAGE, respectively. There was an unexpected correlation between increasing storage stability of the AH-adsorbed P[4] and preservative hydrophobicity (log P) (e.g., the parabens and chlorobutanol were least destabilizing). We used hydrogen exchange-mass spectrometry (HX-MS) to better understand the destabilizing effects of temperature and preservative on backbone flexibility of AH-adsorbed P[4]. Thimerosal addition immediately increased the backbone flexibility across much of the AH-adsorbed P[4] protein backbone (except the N-terminal P2 region and residues G17-Y38), and further increase in P[4] backbone flexibility was observed after storage (4 °C, 4 weeks). HX-MS analysis of AH-adsorbed P[4] stored for 4 weeks at 25 °C revealed structural alterations in some regions of the epitope involved in P[4] specific mAb binding. These combined results are discussed in terms of a generalized workflow for multi-dose vaccine formulation development for recombinant protein antigens.

Mechanism of Thimerosal-Induced Structural Destabilization of a Recombinant Rotavirus P[4] Protein Antigen Formulated as a Multi-Dose Vaccine.

In a companion paper, a two-step developability assessment is presented to rapidly evaluate low-cost formulations (multi-dose, aluminum-adjuvanted) for new subunit vaccine candidates. As a case study, a non-replicating rotavirus (NRRV) recombinant protein antigen P[4] was found to be destabilized by the vaccine preservative thimerosal, and this effect was mitigated by modification of the free cysteine (C173S). In this work, the mechanism(s) of thimerosal-P[4] protein interactions, along with subsequent effects on the P[4] protein's structural integrity, are determined. Reversible complexation of ethylmercury, a thimerosal degradation byproduct, with the single cysteine residue of P[4] protein is demonstrated by intact protein mass analysis and biophysical studies. A working mechanism involving a reversible S-Hg coordinate bond is presented based on the literature. This reaction increased the local backbone flexibility of P[4] within the helical region surrounding the cysteine residue and then caused more global destabilization, both as detected by HX-MS. These effects correlate with changes in antibody-P[4] binding parameters and alterations in P[4] conformational stability due to C173S modification. Epitope mapping by HX-MS demonstrated involvement of the same cysteine-containing helical region of P[4] in antibody-antigen binding. Future formulation challenges to develop low-cost, multi-dose formulations for new recombinant protein vaccine candidates are discussed.

Multifaceted assessment of rituximab biosimilarity: The impact of glycan microheterogeneity on Fc function.

Biosimilars are poised to reduce prices and increase patient access to expensive, but highly effective biologic products. However, questions still remain about the degree of similarity and scarcity of information on biosimilar products from outside of the US/EU in the public domain. Thus, as an independent entity, we performed a comparative analysis between the innovator, Rituxan® (manufactured by Genentech/Roche), and a Russian rituximab biosimilar, Acellbia® (manufactured by Biocad). We evaluated biosimilarity of these two products by a variety of state-of-the-art analytical mass spectrometry techniques, including tandem MS mapping, HX-MS, IM-MS, and intact MS. Both were found to be generally similar regarding primary and higher order structure, though differences were identified in terms of glycoform distribution levels of C-terminal Lys, N-terminal pyroGlu, charge variants and soluble aggregates. Notably, we confirmed that the biosimilar had a higher level of afucosylated glycans, resulting in a stronger FcγIIIa binding affinity and increased ADCC activity. Taken together, our work provides a comprehensive comparison of Rituxan® and Acellbia®.

Modulating Antibody Structure and Function through Directed Mutations and Chemical Rescue.

Monoclonal antibody therapeutics have revolutionized the treatment of diseases such as cancer and autoimmune disorders, and also serve as research reagents for diverse and unparalleled applications. To extend their utility in both contexts, we have begun development of tunable antibodies, whose activity can be controlled by addition of a small molecule. Conceptually, we envision that incorporating cavity-forming mutations into an antibody can disrupt its structure, thereby reducing its affinity for antigen; addition of a small molecule may then restore the active structure, and thus rescue antigen binding. As a first proof of concept toward implementing this strategy, we have incorporated individual tryptophan to glycine mutations into FITC-E2, an anti-fluorescein single-chain variable fragment (scFv). We find that these can disrupt the protein structure and diminish antigen binding, and further that both structure and function can be rescued by addition of indole to complement the deleted side chain. While the magnitude of the affinity difference triggered by indole is modest in this first model system, it nonetheless provides a framework for future mutation/ligand pairs that may induce more dramatic responses. Disrupting and subsequently rescuing antibody activity, as exemplified by this first example, may represent a new approach to "design in" fine-tuned control of antibody activity for a variety of future applications.

Quantifying Protection in Disordered Proteins Using Millisecond Hydrogen Exchange-Mass Spectrometry and Peptic Reference Peptides.

The extent and location of transient structure in intrinsically disordered proteins (IDPs) provide valuable insights into their conformational ensembles and can lead to a better understanding of coupled binding and folding. Millisecond amide hydrogen exchange (HX) can provide such information, but it is difficult to quantify the degree of transient structuring. One reason is that transiently disordered proteins undergo HX at rates only slightly slower than the rate of amide HX by an unstructured random coil, the chemical HX rate. In this work, we evaluate several different methods of obtaining an accurate model for the chemical HX rate suitable for millisecond hydrogen exchange mass spectrometry (HX-MS) analysis of disordered proteins: (1) calculations using the method of Englander [Bai, Y., et al. (1993) Proteins 17, 75-86], (2) measurement of HX in the presence of 6 M urea or 3 M guanidinium chloride, and (3) measurement of HX by peptide fragments derived directly from the proteins of interest. First, using unstructured model peptides and disordered domains of the activator for thyroid and retinoid receptors and the CREB binding protein as the model IDPs, we show that the Englander method has slight inaccuracies that lead to underestimation of the chemical exchange rate. Second, HX-MS measurements of model peptides show that HX rates are changed dramatically by high concentrations of the denaturant. Third, we find that measurements of HX by reference peptides from the proteins of interest provide the most accurate approach for quantifying the extent of transient structure in disordered proteins by millisecond HX-MS.

Soft interactions and volume exclusion by polymeric crowders can stabilize or destabilize transient structure in disordered proteins depending on polymer concentration.

The effects of macromolecular crowding on the transient structure of intrinsically disordered proteins is not well-understood. Crowding by biological molecules inside cells could modulate transient structure and alter IDP function. Volume exclusion theory and observations of structured proteins suggest that IDP transient structure would be stabilized by macromolecular crowding. Amide hydrogen exchange (HX) of IDPs in highly concentrated polymer solutions would provide valuable insights into IDP transient structure under crowded conditions. Here, we have used mass spectrometry to measure HX by a transiently helical random coil domain of the activator of thyroid and retinoid receptor (ACTR) in solutions containing 300 g L-1 and 400 g L-1 of Ficoll, a synthetic polysaccharide, using a recently-developed strong cation exchange-based cleanup method [Rusinga, et al., Anal Chem 2017;89:1275-1282]. Transiently helical regions of ACTR exchanged faster in 300 g L-1 Ficoll than in dilute buffer. In contrast, one transient helix exchanged more slowly in 400 g L-1 Ficoll. Nonspecific interactions destabilize ACTR helicity in 300 g L-1 Ficoll because ACTR engages with the Ficoll polymer mesh. In contrast, 400 g L-1 Ficoll is a semi-dilute solution where ACTR cannot engage the Ficoll mesh. At this higher concentration, volume exclusion stabilizes ACTR helicity because ACTR is compacted in interstitial spaces between Ficoll molecules. Our results suggest that the interplay between nonspecific interactions and volume exclusion in different cellular compartments could modulate IDP function by altering the stability of IDP transient structures. Proteins 2017; 85:1468-1479. © 2017 Wiley Periodicals, Inc.

Automated Strong Cation-Exchange Cleanup To Remove Macromolecular Crowding Agents for Protein Hydrogen Exchange Mass Spectrometry.

Measuring amide hydrogen exchange (HX) of intrinsically disordered proteins (IDPs) in solutions containing high concentrations of macromolecular crowding agents would give new insights into the structure and dynamics of these proteins under crowded conditions. High concentrations of artificial crowders, required to simulate cellular crowding, introduce overwhelming interferences to mass spectrometry (MS) analysis. We have developed a fully automated, dual-stage online cleanup that uses strong cation-exchange (SCX) followed by reversed-phase desalting to remove Ficoll, a synthetic polymer, for HX-MS analysis of proteins under crowded conditions. We tested the efficiency of our method by measuring the HX-MS signal intensities of myoglobin peptides from crowded samples containing 300 g L-1 Ficoll and from uncrowded samples. Although there was loss of abundance relative to uncrowded myoglobin analyzed using conventional HX-MS, 97% coverage of the myoglobin sequence was still obtained. Control HX-MS experiments using unstructured peptides labeled at pD 4.0 under crowded and uncrowded conditions confirmed that Ficoll does not alter chemical exchange and that the same extent of HX is achieved in uncrowded solutions as in solutions containing 300 g L-1 of predeuterated Ficoll. We validated our method by measuring HX of CBP, the intrinsically disordered nuclear coactivator binding domain of CREB binding protein (UniProt CBP_MOUSE P45481 ), residues 2059-2117, at pD 6.5 under crowded and uncrowded conditions. Ficoll induced both protection and deprotection from HX in different regions of CBP, with the greatest deprotection occurring at the edges of helices. These results are consistent with previous observation of IDPs under the influence of synthetic polymers.

Analysis of overlapped and noisy hydrogen/deuterium exchange mass spectra.

Noisy and overlapped mass spectrometry data hinder the sequence coverage that can be obtained from hydrogen deuterium exchange analysis, and places a limit on the complexity of the samples that can be studied by this technique. Advances in instrumentation have addressed these limits, but as the complexity of the biological samples under investigation increases, these problems are re-encountered. Here we describe the use of binomial distribution fitting with asymmetric linear squares regression for calculating the accurate deuterium content for mass envelopes of low signal or that contain significant overlap. The approach is demonstrated with a test data set of HIV Env gp140 wherein inclusion of the new analysis regime resulted in obtaining exchange data for 42 additional peptides, improving the sequence coverage by 11%. At the same time, the precision of deuterium uptake measurements was improved for nearly every peptide examined. The improved processing algorithms also provide an efficient method for deconvolution of bimodal mass envelopes and EX1 kinetic signatures. All these functions and visualization tools have been implemented in the new version of the freely available software, HX-Express v2.

Mapping unstructured regions and synergistic folding in intrinsically disordered proteins with amide H/D exchange mass spectrometry.

Mapping the structured and disordered regions and identifying disorder-to-order transitions are essential to understanding intrinsically disordered proteins (IDPs). One technique that can provide such information is H/D exchange coupled with mass spectrometry (H/D-MS). To explore the feasibility of H/D-MS for mapping disordered and ordered regions in IDPs, we undertook a systematic evaluation of an unstructured protein, a molten globular protein, and the well-folded complex of the two proteins. Most segments of the unstructured protein, ACTR (activator of thyroid and retinoid receptors, NCOA3_HUMAN, residues 1018-1088), exchange at rates consistent with its assignment as an unstructured protein, but there is slight protection in regions that become helical in the ACTR-CBP complex. The molten globular protein, CBP (the nuclear coactivator binding domain of the CREB binding protein, CBP_MOUSE, residues 2059-2117), is moderately protected from exchange, and the protection is nearly uniform across the length of the protein. The uniformity arises because of rapid interconversion between an ensemble of folded conformers and an ensemble of unstructured conformers. Rapid interconversion causes the H/D exchange kinetics to be dominated by exchange by molecules in unstructured conformations. For the folded ACTR-CBP complex, the exchange data provide a qualitatively accurate description of the complex. Our results provide a useful framework to use in the interpretation of H/D-MS data of intrinsically disordered proteins.

An efficient and inexpensive refrigerated LC system for H/D exchange mass spectrometry.

Loss of deuterium label during the LC step in amide hydrogen/deuterium exchange mass spectrometry (H/D-MS) is minimized by maintaining an acidic mobile phase pH and low temperature (pH 2.5, 0 °C). Here we detail the construction and performance of a low-cost, thermoelectrically refrigerated enclosure to house high-performance liquid chromatography (HPLC) components and cool mobile phases. Small volume heat exchangers rapidly decrease mobile phase temperature and keep the temperature stable to ±0.2 °C. Using a superficially porous reversed-phase column, we obtained excellent chromatographic performance in the separation of peptides with a median peak width of 4.4 s. Average deuterium recovery was 80.2% with an average relative precision of 0.91%.

A repulsive electrostatic mechanism for protein export through the type III secretion apparatus.

Many Gram-negative bacteria initiate infections by injecting effector proteins into host cells through the type III secretion apparatus, which is comprised of a basal body, a needle, and a tip. The needle channel is formed by the assembly of a single needle protein. To explore the export mechanisms of MxiH needle protein through the needle of Shigella flexneri, an essential step during needle assembly, we have performed steered molecular dynamics simulations in implicit solvent. The trajectories reveal a screwlike rotation motion during the export of nativelike helix-turn-helix conformations. Interestingly, the channel interior with excessive electronegative potential creates an energy barrier for MxiH to enter the channel, whereas the same may facilitate the ejection of the effectors into host cells. Structurally known basal regions and ATPase underneath the basal region also have electronegative interiors. Effector proteins also have considerable electronegative potential patches on their surfaces. From these observations, we propose a repulsive electrostatic mechanism for protein translocation through the type III secretion apparatus. Based on this mechanism, the ATPase activity and/or proton motive force could be used to energize the protein translocation through these nanomachines. A similar mechanism may be applicable to macromolecular channels in other secretion systems or viruses through which proteins or nucleic acids are transported.

The use of acetone as a substitute for acetonitrile in analysis of peptides by liquid chromatography/electrospray ionization mass spectrometry.

The recent worldwide shortage of acetonitrile has prompted interest in alternative solvents for liquid chromatography/mass spectrometry (LC/MS). In this work, acetone was substituted for acetonitrile in the separation of a peptide mixture by reversed-phase high-performance liquid chromatography (RP-HPLC) and in the positive electrospray ionization mass spectrometry (ESI-MS) of individual peptides. On both C12 and C18 stationary phases, the substitution of acetone for acetonitrile as the organic component of the mobile phase did not alter the gradient elution order of a five-peptide retention standard, but did increase peak width, shorten retention times, and increase peak tailing. Positive ESI mass spectra were obtained for angiotensin I, bradykinin, [Leu(5)]-enkephalin, and somatostatin 14 dissolved in both acetonitrile/water/formic acid (25%/75%/0.1%) and acetone/water/formic acid (25%/75%/0.1%). Under optimized ESI-MS conditions, the mass spectral response of [Leu(5)]-enkephalin was increased two-fold when the solvent contained acetone. The substitution of acetone for acetonitrile resulted in only slight changes in the responses of the remaining peptides. A higher capillary voltage was required for optimum response when acetone was used. Compared with acetonitrile/water/formic acid (50/50/0.1%), more interfering species below m/z = 140 were found in the ESI-MS spectra of acetone/water/formic acid (50/50/0.1%).

Functional characterization and conformational analysis of the Herpesvirus saimiri Tip-C484 protein.

Tyrosine kinase interacting protein (Tip) of Herpesvirus saimiri (HVS) activates the lymphoid-specific member of the Src family kinase Lck. The Tip:Lck interaction is essential for transformation and oncogenesis in HVS-infected cells. As there are no structural data for Tip, hydrogen-exchange mass spectrometry was used to investigate the conformation of a nearly full-length form (residues 1-187) of Tip from HVS strain C484. Disorder predictions suggested that Tip would be mostly unstructured, so great care was taken to ascertain whether recombinant Tip was functional. Circular dichroism and gel-filtration analysis indicated an extended, unstructured protein. In vitro and in vivo binding and kinase assays confirmed that purified, recombinant Tip interacted with Lck, was capable of activating Lck kinase activity strongly and was multiply phosphorylated by Lck. Hydrogen-exchange mass spectrometry of Tip then showed that the majority of backbone amide hydrogen atoms became deuterated after only 10 s of labeling. Such a result suggested that Tip was almost totally unstructured in solution. Digestion of deuterium-labeled Tip revealed some regions with minor protection from exchange. Overall, it was found that, although recombinant Tip is still functional and capable of binding and activating its target Lck, it is largely unstructured.

Altered dynamics in Lck SH3 upon binding to the LBD1 domain of Herpesvirus saimiri Tip.

The Tip protein from Herpesvirus saimiri interacts with the SH3 domain from the Src-family kinase Lck via a proline-containing sequence termed LBD1. Src-family kinase SH3 domains related to Lck have been shown to be dynamic in solution and partially unfold under physiological conditions. The rate of such partial unfolding is reduced by viral protein binding. To determine if the Lck SH3 domain displayed similar behavior, the domain was investigated with hydrogen exchange and mass spectrometry. Lck SH3 was found to be highly dynamic in solution. While other SH3 domains require as much as 10,000 sec to become totally deuterated, Lck SH3 became almost completely labeled within 200 sec. A partial unfolding event involving 8-10 residues was observed with a half-life of approximately 10 sec. Tip LBD1 binding did not cause gross structural changes in Lck SH3 but globally stabilized the domain and reduced the rate of partial unfolding by a factor of five. The region of partial unfolding in Lck SH3 was found to be similar to that identified for other SH3 domains that partially unfold. Although the sequence conservation between Lck SH3 and other closely related SH3 domains is high, the dynamics do not appear to be conserved.