Identification of methionine sulfoxide diastereomers in immunoglobulin gamma antibodies using methionine sulfoxide reductase enzymes.

Light-induced formation of singlet oxygen selectively oxidizes methionines in the heavy chain of IgG2 antibodies. Peptide mapping has indicated the following sensitivities to oxidation: M252 > M428 > M397. Irrespective of the light source, formulating proteins with the free amino acid methionine limits oxidative damage. Conventional peptide mapping cannot distinguish between the S- and R-diastereomers of methionine sulfoxide (Met[O]) formed in the photo-oxidized protein because of their identical polarities and masses. We have developed a method for identification and quantification of these diastereomers by taking advantage of the complementary stereospecificities of the methionine sulfoxide reductase (Msr) enzymes MsrA and MsrB, which promote the selective reduction of S- and R-diastereomers of Met(O), respectively. In addition, an MsrBA fusion protein that contains both Msr enzyme activities permitted the quantitative reduction of all Met(O) diastereomers. Using these Msr enzymes in combination with peptide mapping, we were able to detect and differentiate diastereomers of methionine sulfoxide within the highly conserved heavy chain of an IgG2 that had been photo-oxidized, as well as those in an IgG1 oxidized with peroxide. The rapid identification of the stereospecificity of methionine oxidation by Msr enzymes not only definitively differentiates Met(O) diastereomers, which previously has been indistinguishable using traditional techniques, but also provides an important tool that may contribute to understanding of the mechanisms of protein oxidation and development of new formulation strategies to stabilize protein therapeutics.

Accumulation of succinimide in a recombinant monoclonal antibody in mildly acidic buffers under elevated temperatures.

PURPOSE: The purpose of this paper was to identify the location of a succinimide and determine the rate of its formation and hydrolysis in a recombinant human monoclonal IgG2 antibody aged in mildly acidic buffers at elevated temperatures. MATERIALS AND METHODS: Cation exchange (CEX) HPLC separated multiple Main Peaks and high levels (up to 50%) of basic variants, the identification of which was an analytical challenge and required several complementary techniques. The relative abundance of the CEX basic variants was used to quantify the percentage of succinimide and to study the rates of its formation and hydrolysis. RESULTS: Mass decrease by approximately 18 Da for intact antibodies from the CEX basic fractions suggested succinimide formation from aspartic acid as the major modification. Reversed-phase HPLC/MS of the reduced and trypsin-digested samples detected an isoaspartate 30 (isoD30) in the light chain peptide A25-R37. Direct evidence that isoD30 was from succinimide was obtained by performing succinimide hydrolysis in H2(18)O followed by tryptic digestion in H2(16)O. CONCLUSIONS: Succinimide formation increased as pH became more acidic, whereas its hydrolysis was faster as pH became neutral and alkaline. Succinimide hydrolysis in a denatured sample was estimated to have completed in less than 2 h, but approximately three days for a similar pH but without denaturant. These observations suggest that protein conformation affects succinimide hydrolysis.

18O labeling method for identification and quantification of succinimide in proteins.

We have developed a new method for identification and quantification of succinimide in proteins. The method utilizes 18O water to monitor succinimide hydrolysis. 18O-labeled isoaspartic acid and aspartic acid peptides were produced by hydrolysis of a succinimide-containing protein in 18O water (H218O) followed by tryptic digestion in regular water (H216O). The peptides that had 18O incorporated were 2 Da heavier than their 16O native counterparts. The mass difference was detected and quantified by electrospray time-of-flight mass spectrometry. The amount of 18O incorporation into the isoaspartic acid- and aspartic acid-containing peptides was used to quantify the amount of succinimide present in the native sample. The method was applied to analyze a degraded recombinant monoclonal antibody, which exhibited the accumulation of succinimide after storage in mildly acidic buffers at elevated temperatures for a few weeks. We unambiguously identified amino acid residue 30 located in the antibody light chain as the site of aspartic acid isomerization. At this site, there were 20% isoaspartic acid and 80% aspartic acid detected by peptide mapping in the degraded sample (8 weeks, 45 degrees C, pH 5.0). Hydrolysis in 18O water showed that 80% of the isoaspartic acid and 6% of the aspartic acid had 18O incorporated. The only explanation of 18O incorporation was the presence of succinimide in the sample. Together, a total of 21% (0.8x20% isoaspartic acid+0.06x80% aspartic acid) of aspartic acid residue 30 was found to be present in the form of succinimide in this degraded sample. As a control, the same sample, analyzed using regular 16O water did not show any incorporation of 18O water. By monitoring the amount of 18O-labeled isoaspartic acid and aspartic acid over time under both denaturing and native conditions at pH 8.2, we found that, at denaturing conditions, succinimide at light chain residue 30 hydrolyzed very rapidly (in less than 5 s), but slower (succinimide half-life of approximately 6 h) under native conditions. We also found that, under denaturing conditions, succinimide hydrolyzed at an isoaspartic acid/aspartic acid ratio of 3.5:1, but hydrolyzed almost exclusively to aspartic acid under native conditions. This finding indicates that protein structure plays an important role in the kinetics of succinimide hydrolysis as well as in the generation of the hydrolysis products isoaspartic acid and aspartic acid.

Crystal structure of the dioxygen-bound heme oxygenase from Corynebacterium diphtheriae: implications for heme oxygenase function.

HmuO, a heme oxygenase of Corynebacterium diphtheriae, catalyzes degradation of heme using the same mechanism as the mammalian enzyme. The oxy form of HmuO, the precursor of the catalytically active ferric hydroperoxo species, has been characterized by ligand binding kinetics, resonance Raman spectroscopy, and x-ray crystallography. The oxygen association and dissociation rate constants are 5 microm(-1) s(-1) and 0.22 s(-1), respectively, yielding an O(2) affinity of 21 microm(-1), which is approximately 20 times greater than that of mammalian myoglobins. However, the affinity of HmuO for CO is only 3-4-fold greater than that for mammalian myoglobins, implying the presence of strong hydrogen bonding interactions in the distal pocket of HmuO that preferentially favor O(2) binding. Resonance Raman spectra show that the Fe-O(2) vibrations are tightly coupled to porphyrin vibrations, indicating the highly bent Fe-O-O geometry that is characteristic of the oxy forms of heme oxygenases. In the crystal structure of the oxy form the Fe-O-O angle is 110 degrees, the O-O bond is pointed toward the heme alpha-meso-carbon by direct steric interactions with Gly-135 and Gly-139, and hydrogen bonds occur between the bound O(2) and the amide nitrogen of Gly-139 and a distal pocket water molecule, which is a part of an extended hydrogen bonding network that provides the solvent protons required for oxygen activation. In addition, the O-O bond is orthogonal to the plane of the proximal imidazole side chain, which facilitates hydroxylation of the porphyrin alpha-meso-carbon by preventing premature O-O bond cleavage.

The crystal structures of the ferric and ferrous forms of the heme complex of HmuO, a heme oxygenase of Corynebacterium diphtheriae.

Crystal structures of the ferric and ferrous heme complexes of HmuO, a 24-kDa heme oxygenase of Corynebacterium diphtheriae, have been refined to 1.4 and 1.5 A resolution, respectively. The HmuO structures show that the heme group is closely sandwiched between the proximal and distal helices. The imidazole group of His-20 is the proximal heme ligand, which closely eclipses the beta- and delta-meso axis of the porphyrin ring. A long range hydrogen bonding network is present, connecting the iron-bound water ligand to the solvent water molecule. This enables proton transfer from the solvent to the catalytic site, where the oxygen activation occurs. In comparison to the ferric complex, the proximal and distal helices move closer to the heme plane in the ferrous complex. Together with the kinked distal helix, this movement leaves only the alpha-meso carbon atom accessible to the iron-bound dioxygen. The heme pocket architecture is responsible for stabilization of the ferric hydroperoxo-active intermediate by preventing premature heterolytic O-O bond cleavage. This allows the enzyme to oxygenate selectively at the alpha-meso carbon in HmuO catalysis.

Solution 1H NMR investigation of the active site molecular and electronic structures of substrate-bound, cyanide-inhibited HmuO, a bacterial heme oxygenase from Corynebacterium diphtheriae.

The molecular structure and dynamic properties of the active site environment of HmuO, a heme oxygenase (HO) from the pathogenic bacterium Corynebacterium diphtheriae, have been investigated by (1)H NMR spectroscopy using the human HO (hHO) complex as a homology model. It is demonstrated that not only the spatial contacts among residues and between residues and heme, but the magnetic axes that can be related to the direction and magnitude of the steric tilt of the FeCN unit are strongly conserved in the two HO complexes. The results indicate that very similar contributions of steric blockage of several meso positions and steric tilt of the attacking ligand are operative. A distal H-bond network that involves numerous very strong H-bonds and immobilized water molecules is identified in HmuO that is analogous to that previously identified in hHO (Li, Y., Syvitski, R. T., Auclair, K., Wilks, A., Ortiz de Montellano, P. R., and La Mar, G. N. (2002) J. Biol. Chem. 277, 33018-33031). The NMR results are completely consistent with the very recent crystal structure of the HmuO.substrate complex. The H-bond network/ordered water molecules are proposed to orient the distal water molecule near the catalytically key Asp(136) (Asp(140) in hHO) that stabilizes the hydroperoxy intermediate. The dynamic stability of this H-bond network in HmuO is significantly greater than in hHO and may account for the slower catalytic rate in bacterial HO compared with mammalian HO.