Hydrogen exchange mass spectrometry reveals protein interfaces and distant dynamic coupling effects during the reversible self-association of an IgG1 monoclonal antibody

There is a need for new analytical approaches to better characterize the nature of the concentration-dependent, reversible self-association (RSA) of monoclonal antibodies (mAbs) directly, and with high resolution, when these proteins are formulated as highly concentrated solutions. In the work reported here, hydrogen exchange mass spectrometry (HX-MS) was used to define the concentration-dependent RSA interface, and to characterize the effects of association on the backbone dynamics of an IgG1 mAb (mAb-C). Dynamic light scattering, chemical cross-linking, and solution viscosity measurements were used to determine conditions that caused the RSA of mAb-C. A novel HX-MS experimental approach was then applied to directly monitor differences in local flexibility of mAb-C due to RSA at different protein concentrations in deuterated buffers. First, a stable formulation containing lyoprotectants that permitted freeze-drying of mAb-C at both 5 and 60 mg/mL was identified. Upon reconstitution with RSA-promoting deuterated solutions, the low vs. high protein concentration samples displayed different levels of solution viscosity (i.e., approx. 1 to 75 mPa.s). The reconstituted mAb-C samples were then analyzed by HX-MS. Two specific sequences covering complementarity-determining regions CDR2H and CDR2L (in the variable heavy and light chains, respectively) showed significant protection against deuterium uptake (i.e., decreased hydrogen exchange). These results define the major protein-protein interfaces associated with the concentration-dependent RSA of mAb-C. Surprisingly, certain peptide segments in the V_H domain, the constant domain (C_H2), and the hinge region (C_H1-C_H2 interface) concomitantly showed significant increases in local flexibility at high vs. low protein concentrations. These results indicate the presence of longer-range, distant dynamic coupling effects within mAb-C occurring upon RSA.     

Charge-mediated Fab-Fc interactions in an IgG1 antibody induce reversible self-association,cluster formation,and elevated viscosity

Concentration-dependent reversible self-association (RSA) of monoclonal antibodies (mAbs) poses a challenge to their pharmaceutical development as viable candidates for subcutaneous delivery. While the role of the antigen-binding fragment (Fab) in initiating RSA is well-established, little evidence supports the involvement of the crystallizable fragment (Fc). In this report, a variety of biophysical tools, including hydrogen exchange mass spectrometry, are used to elucidate the protein interface of such non-covalent protein-protein interactions. Using dynamic and static light scattering combined with viscosity measurements, we find that an IgG1 mAb (mAb-J) undergoes RSA primarily through electrostatic interactions and forms a monomer-dimer-tetramer equilibrium. We provide the first direct experimental mapping of the interface formed between the Fab and Fc domains of an antibody at high protein concentrations. Charge distribution heterogeneity between the positively charged interface spanning complementarity-determining regions CDR3H and CDR2L in the Fab and a negatively charged region in C_H3/Fc domain mediates the RSA of mAb-J. When arginine and NaCl are added, they disrupt RSA of mAb-J and decrease the solution viscosity. Fab-Fc domain interactions between mAb monomers may promote the formation of large transient antibody complexes that ultimately cause increases in solution viscosity. Our findings illustrate how limited specific arrangements of amino-acid residues can cause mAbs to undergo RSA at high protein concentrations and how conserved regions in the Fc portion of the antibody can also play an important role in initiating weak and transient protein-protein interactions.     

Mitigation of reversible self-association and viscosity in a human IgG1 monoclonal antibody by rational,structure-guided Fv engineering

Undesired solution behaviors such as reversible self-association (RSA), high viscosity, and liquid-liquid phase separation can introduce substantial challenges during development of monoclonal antibody formulations. Although a global mechanistic understanding of RSA (i.e., native and reversible protein-protein interactions) is sufficient to develop robust formulation controls, its mitigation via protein engineering requires knowledge of the sites of protein-protein interactions. In the study reported here, we coupled our previous hydrogen-deuterium exchange mass spectrometry findings with structural modeling and in vitro screening to identify the residues responsible for RSA of a model IgG1 monoclonal antibody (mAb-C), and rationally engineered variants with improved solution properties (i.e., reduced RSA and viscosity). Our data show that mutation of either solvent-exposed aromatic residues within the heavy and light chain variable regions or buried residues within the heavy chain/light chain interface can significantly mitigate RSA and viscosity by reducing the IgG's surface hydrophobicity. The engineering strategy described here highlights the utility of integrating complementary experimental and in silico methods to identify mutations that can improve developability, in particular, high concentration solution properties, of candidate therapeutic antibodies.     

Correlations between changes in conformational dynamics and physical stability in a mutant IgG1 mAb engineered for extended serum half-life

This study compares the local conformational dynamics and physical stability of an IgG1 mAb (mAb-A) with its corresponding YTE (M255Y/S257T/T259E) mutant (mAb-E), which was engineered for extended half-life in vivo. Structural dynamics was measured using hydrogen/deuterium (H/D) exchange mass spectrometry while protein stability was measured with differential scanning calorimetry (DSC) and size exclusion chromatography (SEC). The YTE mutation induced differences in H/D exchange kinetics at both pH 6.0 and 7.4. Segments covering the YTE mutation sites and the FcRn binding epitopes showed either subtle or no observable differences in local flexibility. Surprisingly, several adjacent segments in the C_H2 and distant segments in the V_H, C_H1, and V_L domains had significantly increased flexibility in the YTE mutant. Most notable among the observed differences is increased flexibility of the 244–254 segment of the C_H2 domain, where increased flexibility has been shown previously to correlate with decreased conformational stability and increased aggregation propensity in other IgG1 mAbs (e.g., presence of destabilizing additives as well as upon de-glycosylation or methionine oxidation). DSC analysis showed decreases in both thermal onset (T_onset) and unfolding (T_m1) temperatures of 7°C and 6.7°C, respectively, for the C_H2 domain of the YTE mutant. In addition, mAb-E aggregated faster than mAb-A under accelerated stability conditions as measured by SEC analysis. Hence, the relatively lower physical stability of the YTE mutant correlates with increased local flexibility of the 244–254 segment, providing a site-directed mutant example that this segment of the C_H2 domain is an aggregation hot spot in IgG1 mAbs.     

Correlations between changes in conformational dynamics and physical stability in a mutant IgG1 mAb engineered for extended serum half-life

This study compares the local conformational dynamics and physical stability of an IgG1 mAb (mAb-A) with its corresponding YTE (M255Y/S257T/T259E) mutant (mAb-E), which was engineered for extended half-life in vivo. Structural dynamics was measured using hydrogen/deuterium (H/D) exchange mass spectrometry while protein stability was measured with differential scanning calorimetry (DSC) and size exclusion chromatography (SEC). The YTE mutation induced differences in H/D exchange kinetics at both pH 6.0 and 7.4. Segments covering the YTE mutation sites and the FcRn binding epitopes showed either subtle or no observable differences in local flexibility. Surprisingly, several adjacent segments in the C_H2 and distant segments in the V_H, C_H1, and V_L domains had significantly increased flexibility in the YTE mutant. Most notable among the observed differences is increased flexibility of the 244–254 segment of the C_H2 domain, where increased flexibility has been shown previously to correlate with decreased conformational stability and increased aggregation propensity in other IgG1 mAbs (e.g., presence of destabilizing additives as well as upon de-glycosylation or methionine oxidation). DSC analysis showed decreases in both thermal onset (T_onset) and unfolding (T_m1) temperatures of 7°C and 6.7°C, respectively, for the C_H2 domain of the YTE mutant. In addition, mAb-E aggregated faster than mAb-A under accelerated stability conditions as measured by SEC analysis. Hence, the relatively lower physical stability of the YTE mutant correlates with increased local flexibility of the 244–254 segment, providing a site-directed mutant example that this segment of the C_H2 domain is an aggregation hot spot in IgG1 mAbs.     

Biosynthèse de la cellulose bacterienne deutériée: étude par R. M. N. du taux d'incorporation et de la localisation du deutérium

The use of the NMR spectra (250 MHz) of cellulose triacetate allows the determination of the percentage of deuterium bonded to each of the six carbon atoms of the monomer residue (except for H_?1 and one of the protons bonded to C₆ where the signals overlap). Deuterated derivatives of D -glucose and/or deuterated water were used for the biosynthesis of bacterial cellulose by Acetobacter xylinum. Analysis of NMR spectra of acetylated samples gives the following results. About 90% of the protons linked to C₁ and C₆ come from the D -glucose used in the nutrition medium, whereas 10% are exchanged with other sources of protons. Over 40% of the protons linked to C₂, C₃, C₄, and C₅ arise from the water of the nutrition medium. Discrepancies between results of biosynthesis from deuterated water and from deuterated D -glucose can only be explained if more than one enzymatic process is involved in the biosynthesis of bacterial cellulose.     

Properties ofEscherichia coli grown in deuterated media

The effects on a number of parameters of transferringEscherichia coli between protonated and deuterated media were studied; these included growth, oxygen consumption and the synthesis of DNA, RNA, total protein, and β-galactosidase. Similar measurements were made on cells fully adapted to growth on deuterated media. The amino acid compositions of deuterated and protonated cellular protein were similar, but in deuterated cells the ratio protein: DNA was doubled. Deutero- and protio-β-galactosidase had similarK _M values and turnover numbers in D₂O and H₂O. The kinetics of β-galactosidase synthesis were not changed by deuteration, but it was found that lower concentrations of inducer were required to achieve particular levels of induction. Brief exposure to inducer in one medium, followed by removal of inducer and expression of enzyme-forming-potential in either D₂O or H₂O, showed that mRNA synthesized by deuterated cells was translated equally well in both media. mRNA synthesized by protonated cells was translated about twice as efficiently in H₂O. Inducible strains (but not a regulator constitutive) lost the capacity to synthesize enzymically active β-galactosidase after more than 100 generations in D₂O-acetate. The defect persisted when such cells were grown in H₂O-acetate, but enzyme activity was restored by growth in H₂O-glycerol. The failure to produce active enzyme was not due to a failure of the induction mechanism; gel electrophoresis revealed the presence of an inactive protein species. The nature of adaptation to deuteration is discussed.     

Differences in structure and stability between normal and deuterated proteins (phycocyanin)

Differential scanning microcalorimetry was used to investigate the enthalpy (ΔH_d) and the temperature (t_d) of thermal denaturation of normal and deuterated phycocyanins isolated from two blue-green algae, Plectonema calothricoides and Phormidium luridum. Values of t_d in deuterated proteins are about 5°C lower than those in normal proteins. The magnitudes of ΔH_d in deuterated proteins are 18–36% lower than in normal proteins. The heatcapacity change (ΔC_p) in protein unfolding is essentially the same (2 kcal/mol/K) for deuterated and normal proteins within the experimental error. At close to physiological temperature (27°C), the differences in thermodynamic functions in the native and denatured states are much higher in normal proteins than in deuterated proteins. CD was employed to evaluate both the secondary structures and urea denaturation of these two types of proteins. In P. luridum, deuterated protein is about 8% higher in α-helix content; in P. calothricoides it is not significantly higher. Deuterated proteins are less resistant to the denaturant urea than are normal proteins: the denaturant concentration at the midpoint of the denaturation curve is 0.6–1.2 mol/L lower in the deuterated proteins. The apparent free energies of unfolding of deuterated proteins at zero denaturant concentration are 1.1–1.5 kcal/mol less than for normal proteins.     

A strategy to obtain backbone resonance assignments of deuterated proteins in the presence of incomplete amide 2H/1H back-exchange

Replacement of non-exchangeable protons by deuterons has become a standard tool in structural studies of proteins on the order of 30–40 kDa to overcome problems arising from rapid ¹H and ¹³C transverse relaxation. However, ¹H nuclei are required at exchangeable sites to maintain the benefits of proton detection. Protein expression in D₂O-based media containing deuterated carbon sources yields protein deuterated in all positions. Subsequent D/H-exchange is commonly used to reintroduce protons in labile positions. Since this strategy may fail for large proteins with strongly inhibited exchange we propose to express the protein in fully deuterated algal lysate medium in 100% H₂O. As a side-effect partial C protonation occurs in a residue-type dependent manner. Samples obtained by this protocol are suitable for complementary ¹H^N- and ¹H-based triple resonance experiments allowing complete backbone resonance assignments in cases where back-exchange of amide protons is very slow after expression in D₂O and refolding of chemically denatured protein is not feasible. This approach is explored using a 35-kDa protein as a test case. The degree of C protonation of individual amino acids is determined quantitatively and transverse relaxation properties of ¹H^N and ¹⁵N nuclei of the partially deuterated protein are investigated and compared to the fully protonated and perdeuterated species. Based on the deviations of assigned chemical shifts from random coil values its solution secondary structure can be established.     

A simple protocol for the production of highly deuterated proteins for biophysical studies

Highly deuterated protein samples expand the biophysics and biological tool kit by providing, among other qualities, contrast matching in neutron diffraction experiments and reduction of dipolar spin interactions from normally protonated proteins in magnetic resonance studies, impacting both electron paramagnetic resonance and NMR spectroscopy. In NMR applications, deuteration is often combined with other isotopic labeling patterns to expand the range of conventional NMR spectroscopy research in both solution and solid-state conditions. However, preparation of deuterated proteins is challenging. We present here a simple, effective, and user-friendly protocol to produce highly deuterated proteins in Escherichia coli cells. The protocol utilizes the common shaker flask growth method and the well-known pET system (which provides expression control via the T7 promotor) for large-scale recombinant protein expression. One liter expression typically yields 5 to 50 mg of highly deuterated protein. Our data demonstrate that the optimized procedure produces a comparable quantity of protein in deuterium (²H₂O) oxide M9 medium compared with that in ¹H₂O M9 medium. The protocol will enable a broader utilization of deuterated proteins in a number of biophysical techniques.     

Backbone resonance assignments of the <Emphasis Type="Italic">Escherichia coli</Emphasis> 62 kDa protein,Hsp31

Dimeric Hsp31 protein was first characterized as a holding chaperone of Escherichia coli (E. coli), and has been suggested as having protease activity due to the presence of a potential catalytic triad, Cys185, His186, and Asp214. However, it has recently been reported that Hsp31 displays a relatively strong glyoxalase III activity that can decompose reactive carbonyl species (methylglyoxal and glyoxal) in the absence of additional cofactor. Hsp31 is a representative member of the DJ-1/ThiJ/PfpI protein superfamily, and the importance of DJ-1 protein in Parkinson’s disease has been well known. The structural flexibility of the long loop region, which encompasses from the P- to the A-domain, is important for the chaperone activity of Hsp31. The backbone chemical shifts (CSs) would be useful for studying the structural changes of Hsp31 that are critical for the holding chaperone activity, and also for deciphering the switching mechanism between the glyoxalase III and the chaperone. Here, we report the backbone CSs (H^N, N, CO, C_α, and C_β) of the deuterated Hsp31 protein (62 kDa). The CS analysis showed that the predicted regions of secondary structures are in good agreement with those observed in the previous crystal structure of Hsp31.     

H<Subscript>2</Subscript>O<Subscript>2</Subscript> regulates root system architecture by modulating the polar transport and redistribution of auxin

The accumulation and redistribution of the plant hormone auxin plays a crucial role in root development and patterning. Plants can alter their root system architecture (RSA) to adapt to different biotic and abiotic stresses. In addition, reactive oxygen species (ROS), such as H₂O₂, are known to increase in plants undergoing stress. Here, we present evidence that H₂O₂ can regulate auxin accumulation and redistribution through modulating polar auxin transport, leading to changes in RSA. Plants exposed to different concentrations of H₂O₂ formed a highly branched root system with abundant lateral roots and a shorter primary root. Monitoring of the auxin responsive DR5::GUS indicated that auxin accumulation decreased in lateral root primordia (LRP) and emerging lateral root tips. In addition, polar auxin transport, including both basipetal and acropetal transport modulated by AUX1 and PIN protein carriers, was involved in the process. Taken together, our results suggest that H₂O₂ could regulate plastic RSA by perturbing polar auxin transport as a means of modulating the accumulation and distribution of auxin.     

New syntheses of deuterated protoporphyrin-IX derivatives for heme protein nmr studies

An efficient total synthesis of 1,5-di(trideuteromethyl)protoporphyrin-IX (3) dimethyl ester from monopyrrole precursors is described, the synthesis proceeding through crystalline tripyrrene and a,c-biladiene salt intermediates. The 2- and 4-vinyl groups in (3) are formed from the corresponding (2-chloroethyl) substituents by way of base-promoted dehydrochlorination. In protio solvents, this synthetic step is shown to exchange out preferentially deuterons in the 1-methyl group, and this observation is exploited in an efficient synthesis of the 1,3-di(trideuteromethyl)protoporphyrin-IX (22) dimethyl ester from 2,4-diacetyldeuteroporphyrin-IX (20) dimethyl ester (which is in turn accessible from commercially available protoporphyrin-IX (5)). Thus, basic exchange in deuterated solvent of (20) gives the deuterated analog, which after reduction and dehydration gives the 1,3-di(trideuteromethyl)protoporphyrin-IX analog (22), in which the vinyl H₂ and propionic CH₂·CO functions have also become deuterated.     

Structural analysis of kinetic folding intermediates for a TIM barrel protein, indole-3-glycerol phosphate synthase, by hydrogen exchange mass spectrometry and Gō model simulation

The structures of partially folded states appearing during the folding of a (βα)₈ TIM barrel protein, the indole-3-glycerol phosphate synthase from Sulfolobus solfataricus (sIGPS), was assessed by hydrogen exchange mass spectrometry (HX-MS) and Gō model simulations. HX-MS analysis of the peptic peptides derived from the pulse-labeled product of the sub-millisecond folding reaction from the urea-denatured state revealed strong protection in the (βα)₄ region, modest protection in the neighboring (βα)_1-3 and (βα)₅β₆ segments and no significant protection in the remaining N and C-terminal segments. These results demonstrate that this species is not a collapsed form of the unfolded state under native-favoring conditions nor is it the native state formed via fast-track folding. However, the striking contrast of these results with the strong protection observed in the (βα)_2-5β₆ region after 5 s of folding demonstrates that these species represent kinetically distinct folding intermediates that are not identical as previously thought. A re-examination of the kinetic folding mechanism by chevron analysis of fluorescence data confirmed distinct roles for these two species: the burst-phase intermediate is predicted to be a misfolded, off-pathway intermediate, while the subsequent 5 s intermediate corresponds to an on-pathway equilibrium intermediate. Comparison with the predictions using a C^α Gō model simulation of the kinetic folding reaction for sIGPS shows good agreement with the core of the structure offering protection against exchange in the on-pathway intermediate(s). Because the native-centric Gō model simulations do not explicitly include sequence-specific information, the simulation results support the hypothesis that the topology of TIM barrel proteins is a primary determinant of the folding free energy surface for the productive folding reaction. The early misfolding reaction must involve aspects of non-native structure not detected by the Gō model simulation.     

The critical role of arginine residues in the binding of human monoclonal antibodies to cardiolipin

Previously we reported that the variable heavy chain region (V_H) of a human beta₂ glycoprotein I-dependent monoclonal antiphospholipid antibody (IS4) was dominant in conferring the ability to bind cardiolipin (CL). In contrast, the identity of the paired variable light chain region (V_L) determined the strength of CL binding. In the present study, we examine the importance of specific arginine residues in IS4V_H and paired V_L in CL binding. The distribution of arginine residues in complementarity determining regions (CDRs) of V_H and V_L sequences was altered by site-directed mutagenesis or by CDR exchange. Ten different 2a2 germline gene-derived V_L sequences were expressed with IS4V_H and the V_H of an anti-dsDNA antibody, B3. Six variants of IS4V_H, containing different patterns of arginine residues in CDR3, were paired with B3V_L and IS4V_L. The ability of the 32 expressed heavy chain/light chain combinations to bind CL was determined by ELISA. Of four arginine residues in IS4V_H CDR3 substituted to serines, two residues at positions 100 and 100 g had a major influence on the strength of CL binding while the two residues at positions 96 and 97 had no effect. In CDR exchange studies, V_L containing B3V_L CDR1 were associated with elevated CL binding, which was reduced significantly by substitution of a CDR1 arginine residue at position 27a with serine. In contrast, arginine residues in V_L CDR2 or V_L CDR3 did not enhance CL binding, and in one case may have contributed to inhibition of this binding. Subsets of arginine residues at specific locations in the CDRs of heavy chains and light chains of pathogenic antiphospholipid antibodies are important in determining their ability to bind CL.     

Synthesis of deuterium-labelled analogues of NLRP3 inflammasome inhibitor MCC950

This study describes the syntheses of di, tetra and hexa deuterated analogues of the NOD-like receptor pyrin domain-containing protein 3 (NLRP3) inflammasome inhibitor MCC950. In di and tetra deuterated analogues, deuteriums were incorporated into the 1,2,3,5,6,7-hexahydro-s-indacene moiety, whereas in the hexa deuterated MCC950 deuteriums were incorporated into the 2-(furan-3-yl)propan-2-ol moiety. The di deuterated MCC950 analogue was synthesised from 4-amino-3,5,6,7-tetrahydro-s-indacen-1(2H)-one 5. Tetra deuterated analogues were synthesised in 10 chemical steps starting with 5-bromo-2,3-dihydro-1H-inden-1-one 9, whereas the hexa deuterated analogue was synthesised in four chemical steps starting with ethyl-3-furoate 24. All of the compounds exhibited similar activity to MCC950 (IC₅₀?=?8?nM). These deuterated analogues are useful as internal standards in LC-MS analyses of biological samples from in vivo studies.     

Shear viscosity and thermal conductivity of quadrupolar real fluids from molecular simulation

In the present work, equilibrium molecular dynamics was used with the Green-Kubo formalism to simultaneously calculate shear viscosity and thermal conductivity of ten real fluids, i.e. F₂, N₂, O₂, CO₂, C₂H₆, C₂H₄, C₂F₆, C₃H₄, C₃H₆ and SF₆. The fluids were consistently described by the two-center Lennard–Jones plus point quadrupole (2CLJQ) pair potential, whose parameters were adjusted to vapor–liquid equilibria only [J. Phys. Chem. B, 2001, 105, 12126–12133]. The predicted shear viscosities and thermal conductivities show an overall average deviation of only about 10% from correlations of experimental data where comparison was possible.

At low temperature and high density state points, the Green–Kubo integral for shear viscosity shows slow convergence. This problem can be overcome by a new approach developed in the present work. It is based on the adjustment of a suitable function describing the long time behavior of the autocorrelation function and yields reliable results without the need of excessively long simulation runs.     

Bispecific antibodies with Fab-arms featuring exchanged antigen-binding constant domains

Monoclonal antibodies can acquire the property of engagement of a second antigen via fusion methods or modification of their CDR loops, but also by modification of their constant domains, such as in the mAb² format where a set of mutated amino acid residues in the C_H3 domains enables a high-affinity specific interaction with the second antigen. We tested the possibility of introducing multiple binding sites for the second antigen by replacing the Fab C_H1/C_L domain pair with a pair of antigen-binding C_H3 domains in a model scaffold with trastuzumab variable domains and VEGF-binding C_H3 domains. Such bispecific molecules were produced in a “Fab-like” format and in a full-length antibody format. Novel constructs were of expected molecular composition using mass spectrometry. They were expressed at a high level in standard laboratory conditions, purified as monomers with Protein A and gel filtration and were of high thermostability. Their high-affinity binding to both target antigens was retained. Finally, the Her2/VEGF binding domain-exchanged bispecific antibody was able to mediate a potentiated surface Her2-internalization effect on the Her2-overexpressing cell line SK-BR-3 due to improved level of cross-linking with the endogenously secreted cytokine. To conclude, bispecific antibodies with Fabs featuring exchanged antigen-binding C_H3 domains offer an alternative solution in positioning and valency of antigen binding sites.     

Relative stability of the α-helix of deuterated poly(γ-benzyl-L-glutamate)

The coil-to-helix transition temperatures of hydrogen bearing and deuterated poly(γ-benzyl-L -glutamate) in 1,3-dichlorotetrafluoroacetone/H₂O and/D₂O mixtures, respectively, have been determined. Together with previously obtained data for the conformational transition of this polypeptide in normal and deuterated dichloroacetic acid, these results have been used in an analysis of the effect of deuterium substitution on the intrinsic stability of the α-helical form of poly(γ-benzyl-L -glutamate). The findings, consistent for both solvent systems, showed that the deuterated polypeptide is some 5% more stable than the normal protonated poly(γ-benzyl-L -glutamate), while the polypeptide-active solvent interaction enthalpy is also slightly increased by deuterium substitution in the respective molecules. A consideration of available data for poly(β-benzyl-L -aspartate) reveals an anomaly with respect to the present analysis.