Effect of methionine oxidation of a recombinant monoclonal antibody on the binding affinity to protein A and protein G

Oxidation of methionine (Met) residues is one of the most common protein degradation pathways. Two Met residues, Met256 and Met432, of a recombinant fully human monoclonal IgG1 antibody have been shown to be susceptible to oxidation. Met256 and Met432 are located in the antibody CH2-CH3 interface and in close proximity to protein A and protein G binding sites. The effect of oxidation of these susceptible Met residues on the binding to protein A and protein G was investigated in the current study. Incubation of the antibody with 5% tert-butyl hydroperoxide (tBHP) resulted in a nearly complete oxidation of Met256 and Met432, while incubation with 1% tBHP resulted in mixed populations of the antibody with different degrees of Met oxidation. Oxidation of Met256 and Met432 resulted in earlier elution of the antibody from protein A and protein G columns when eluted with a gradient of decreasing pH. Analysis by ELISA and surface plasmon resonance (SPR) revealed decreased binding affinity of the oxidized antibody to protein A and protein G. It is therefore concluded that oxidation of the Met256 and Met432 residues of the recombinant monoclonal antibody altered its interaction with protein A and protein G resulting in a decrease in binding affinity.     

Structure and stability changes of human IgG1 Fc as a consequence of methionine oxidation

The Fc region has two highly conserved methionine residues, Met 33 (C(H)3 domain) and Met 209 (C(H)3 domain), which are important for the Fc's structure and biological function. To understand the effect of methionine oxidation on the structure and stability of the human IgG1 Fc expressed in Escherichia coli, we have characterized the fully oxidized Fc using biophysical (DSC, CD, and NMR) and bioanalytical (SEC and RP-HPLC-MS) methods. Methionine oxidation resulted in a detectable secondary and tertiary structural alteration measured by circular dichroism. This is further supported by the NMR data. The HSQC spectral changes indicate the structures of both C(H)2 and C(H)3 domains are affected by methionine oxidation. The melting temperature (Tm) of the C(H)2 domain of the human IgG1 Fc was significantly reduced upon methionine oxidation, while the melting temperature of the C(H)3 domain was only affected slightly. The change in the C(H)2 domain T m depended on the extent of oxidation of both Met 33 and Met 209. This was confirmed by DSC analysis of methionine-oxidized samples of two site specific methionine mutants. When incubated at 45 degrees C, the oxidized Fc exhibited an increased aggregation rate. In addition, the oxidized Fc displayed an increased deamidation (at pH 7.4) rate at the Asn 67 and Asn 96 sites, both located on the C(H)2 domain, while the deamidation rates of the other residues were not affected. The methionine oxidation resulted in changes in the structure and stability of the Fc, which are primarily localized to the C(H)2 domain. These changes can impact the Fc's physical and covalent stability and potentially its biological functions; therefore, it is critical to monitor and control methionine oxidation during manufacturing and storage of protein therapeutics.     

Oxidation of methionine residues in antithrombin. Effects on biological activity and heparin binding

Commercially available human plasma-derived preparations of the serine protease inhibitor antithrombin (AT) were shown to contain low levels of oxidation, and we sought to determine whether oxidation might be a means of regulating the protein's inhibitory activity. A recombinant form of AT, with similarly low levels of oxidation as purified, was treated with hydrogen peroxide in order to study the effect of oxidation, specifically methionine oxidation, on the biochemical properties of this protein. AT contains two adjacent methionine residues near the reactive site loop cleaved by thrombin (Met314 and Met315) and two exposed methionines that border on the heparin binding region of AT (Met17 and Met20). In forced oxidations with hydrogen peroxide, the methionines at 314 and 315 were found to be the most susceptible to oxidation, but their oxidation did not affect either thrombin-inhibitory activity or heparin binding. Methionines at positions 17 and 20 were significantly oxidized only at higher concentrations of peroxide, at which point heparin affinity was decreased. However at saturating heparin concentrations, activity was only marginally decreased for these highly oxidized samples of AT. Structural studies indicate that highly oxidized AT is less able to undergo the complete conformational change induced by heparin, most probably due to oxidation of Met17. Since this does not occur in less oxidized, and presumably more physiologically relevant, forms of AT such as those found in plasma preparations, oxidation does not appear to be a means of controlling AT activity.     

Chemical modifications in therapeutic protein aggregates generated under different stress conditions

In this study, we characterized the chemical modifications in the monoclonal antibody (IgG(2)) aggregates generated under various conditions, including mechanical, chemical, and thermal stress treatment, to provide insight into the mechanism of protein aggregation and the types of aggregate produced by the different stresses. In a separate study, additional biophysical characterization was performed to arrange these aggregates into a classification system (Joubert, M. K., Luo, Q., Nashed-Samuel, Y., Wypych, J., and Narhi, L. O. (2011) J. Biol. Chem. 286, 25118-25133). Here, we report that different aggregates possessed different types and levels of chemical modification. For chemically treated samples, metal-catalyzed oxidation using copper showed site-specific oxidation of Met(246), His(304), and His(427) in the Fc portion of the antibody, which might be attributed to a putative copper-binding site. For the hydrogen peroxide-treated sample, in contrast, four solvent-exposed Met residues in the Fc portion were completely oxidized. Met and/or Trp oxidation was observed in the mechanically stressed samples, which is in agreement with the proposed model of protein interaction at the air-liquid interface. Heat treatment resulted in significant deamidation but almost no oxidation, which is consistent with thermally induced aggregates being generated by a different pathway, primarily by perturbing conformational stability. These results demonstrate that chemical modifications are present in protein aggregates; furthermore, the type, locations, and severity of the modifications depend on the specific conditions that generated the aggregates.     

A novel approach to investigate the effect of methionine oxidation on pharmacokinetic properties of therapeutic antibodies

Preserving the chemical and structural integrity of therapeutic antibodies during manufacturing and storage is a major challenge during pharmaceutical development. Oxidation of Fc methionines Met252 and Met428 is frequently observed, which leads to reduced affinity to FcRn and faster plasma clearance if present at high levels. Because oxidation occurs in both positions simultaneously, their individual contribution to the concomitant changes in pharmacokinetic properties has not been clearly established. A novel pH-gradient FcRn affinity chromatography method was applied to isolate three antibody oxidation variants from an oxidized IgG1 preparation based on their FcRn binding properties. Physico-chemical characterization revealed that the three oxidation variants differed predominantly in the number of oxMet252 per IgG (0, 1, or 2), but not significantly in the content of oxMet428. Corresponding to the increase in oxMet252 content, stepwise reduction of FcRn affinity in vitro, as well as faster clearance and shorter terminal half-life, in huFcRn-transgenic mice were observed. A single Met252 oxidation per antibody had no significant effect on pharmacokinetics (PK) compared with unmodified IgG. Importantly, only molecules with both heavy chains oxidized at Met252 exhibited significantly faster clearance. In contrast, Met428 oxidation had no apparent negative effect on PK and even led to somewhat improved FcRn binding and slower clearance. This minor effect, however, seemed to be abrogated by the dominant effect of Met252 oxidation. The novel approach of functional chromatographic separation of IgG oxidation variants followed by physico-chemical and biological characterization has yielded the first experimentally-backed explanation for the unaltered PK properties of antibody preparations containing relatively high Met252 and Met428 oxidation levels.     

A novel approach to investigate the effect of methionine oxidation on pharmacokinetic properties of therapeutic antibodies

Preserving the chemical and structural integrity of therapeutic antibodies during manufacturing and storage is a major challenge during pharmaceutical development. Oxidation of Fc methionines Met252 and Met428 is frequently observed, which leads to reduced affinity to FcRn and faster plasma clearance if present at high levels. Because oxidation occurs in both positions simultaneously, their individual contribution to the concomitant changes in pharmacokinetic properties has not been clearly established. A novel pH-gradient FcRn affinity chromatography method was applied to isolate three antibody oxidation variants from an oxidized IgG1 preparation based on their FcRn binding properties. Physico-chemical characterization revealed that the three oxidation variants differed predominantly in the number of oxMet252 per IgG (0, 1, or 2), but not significantly in the content of oxMet428. Corresponding to the increase in oxMet252 content, stepwise reduction of FcRn affinity in vitro, as well as faster clearance and shorter terminal half-life, in huFcRn-transgenic mice were observed. A single Met252 oxidation per antibody had no significant effect on pharmacokinetics (PK) compared with unmodified IgG. Importantly, only molecules with both heavy chains oxidized at Met252 exhibited significantly faster clearance. In contrast, Met428 oxidation had no apparent negative effect on PK and even led to somewhat improved FcRn binding and slower clearance. This minor effect, however, seemed to be abrogated by the dominant effect of Met252 oxidation. The novel approach of functional chromatographic separation of IgG oxidation variants followed by physico-chemical and biological characterization has yielded the first experimentally-backed explanation for the unaltered PK properties of antibody preparations containing relatively high Met252 and Met428 oxidation levels.     

Functional assessment of antibody oxidation by native mass spectrometry

Oxidation of methionine (Met) residues is one of several chemical degradation pathways for recombinant IgG1 antibodies. Studies using several methodologies have indicated that Met oxidation in the constant IgG1 domains affects in vitro interaction with human neonatal Fc (huFcRn) receptor, which is important for antibody half-life. Here, a completely new approach to investigating the effect of oxidative stress conditions has been applied. Quantitative ultra-performance liquid chromatography mass spectrometry (MS) peptide mapping, classical surface plasmon resonance and the recently developed FcRn column chromatography were combined with the new fast-growing approach of native MS as a near native state protein complex analysis in solution. Optimized mass spectrometric voltage and pressure conditions were applied to stabilize antibody/huFcRn receptor complexes in the gas phase for subsequent native MS experiments with oxidized IgG1 material. This approach demonstrated a linear correlation between quantitative native MS and IgG-FcRn functional analysis.

In our study, oxidation of the heavy chain Met-265 resulted in a stepwise reduction of mAb3/huFcRn receptor complex formation. Remarkably, a quantitative effect of the heavy chain Met-265 oxidation on relative binding capacity was only detected for doubly oxidized IgG1, whereas IgG1 with only one oxidized heavy chain Met-265 was not found to significantly affect IgG1 binding to huFcRn. Thus, mono-oxidized IgG1 heavy chain Met-265 most likely does not represent a critical quality attribute for pharmacokinetics.     

In vitro methionine oxidation of Escherichia coli-derived human stem cell factor: effects on the molecular structure, biological activity, and dimerization.

The effect of oxidation of the methionine residues of Escherichia coli-derived recombinant human stem cell factor (huSCF) to methionine sulfoxide on the structure and activity of SCF was examined. Oxidation was performed using hydrogen peroxide under acidic conditions (pH 5.0). The kinetics of oxidation of the individual methionine residues was determined by quantitation of oxidized and unoxidized methionine-containing peptides, using RP-HPLC of Asp-N endoproteinase digests. The initial oxidation rates for Met159, Met-1, Met27, Met36, and Met48 were 0.11 min-1, 0.098 min-1, 0.033 min-1, 0.0063 min-1, and 0.00035 min-1, respectively, when SCF was incubated in 0.5% H2O2 at room temperature. Although oxidation of these methionines does not affect the secondary structure of SCF, the oxidation of Met36 and Met48 affects the local structure as indicated by CD and fluorescence spectroscopy. The 295-nm Trp peak in the near-UV CD is decreased upon oxidation of Met36, and lost completely following the oxidation of Met48, indicating that the Trp44 environment is becoming significantly less rigid than it is in native SCF. Consistent with this result, the fluorescence spectra revealed that Trp44 becomes more solvent exposed as the methionines are oxidized, with the hydrophobicity of the Trp44 environment decreasing significantly. The oxidations of Met36 and Met48 decrease biological activity by 40% and 60%, respectively, while increasing the dissociation rate constant of SCF dimer by two- and threefold. These results imply that the oxidation of Met36 and Met48 affects SCF dimerization and tertiary structure, and decreases biological activity.     

Free-energy simulations of the oxidation of c-terminal methionines in calmodulin

In the course of aging or under conditions of oxidative stress, methionine residues of calmodulin undergo oxidation, leading to loss of biological activity of the protein. We have performed free-energy simulations of the effects of C-terminal methionine side-chain oxidation on the properties of calmodulin. The simulation results indicate that oxidation should have a destabilizing effect on all three protein functional states: calcium free, calcium loaded, and with both calcium and target peptide bound. Because the different states are destabilized by different amounts, this leads to a more complex pattern in the observable effects on protein thermal stability, calcium affinity, and binding of a target peptide. The influence of oxidation on the free energy of CaM unfolding is estimated by comparing the free-energy cost of oxidizing a Met residue in a Gly-Met-Gly peptide and in the protein. The protein thermal stability of the oxidized forms is lowered by a moderate amount 1-3 kcal/mol, in qualitative agreement with experimental results of 0.3 kcal/mol. The calculated changes in affinity for calcium and for the target peptide show opposing trends. Oxidation at position 144 is predicted to enhance peptide binding and weaken calcium binding, whereas oxidation at 145 weakens peptide binding and enhances affinity for calcium. The lower affinity of Met 145-oxidized calmodulin toward the target peptide correlates with experimentally observed lowering of calmodulin-activated Ca-ATPase activity when oxidized calmodulin from aged rat brains is used. Thus, our simulations suggest that Met 145 is the oxidation site in the C-terminal fragment of calmodulin. The microscopic mechanism behind the calculated free energy changes appears to be a greater affinity for water of the oxidized Met side-chain relative to normal Met. Structures with Met exposed to solvent had consistently lower free energies than those with buried Met sidechains.     

HIC resolution of an IgG1 with an oxidized Trp in a complementarity determining region

Susceptibility of tryptophan (Trp) in a complementarity-determining region (CDR) to oxidation is a significant issue for recombinant monoclonal antibody (mAb) therapeutics due to the clinical efficacy and stability concerns. Here we present a case study using hydrophobic interaction chromatography (HIC) to separate an oxidized Trp containing population of an IgG1. The best separation was achieved using dual Dionex ProPac HIC-10 columns, and the oxidized Trp population was isolated as a separated pre-peak. Peptide map analysis revealed that the oxidized Trp is located in a heavy chain CDR. In addition, the HIC method was capable of monitoring the oxidation status of the CDR Trp, as the oxidation rate of the CDR Trp measured by HIC directly correlated with the results of the peptide maps. The same method conditions were also capable of separating oxidized methionine (Met) and isomerization/deamidation products, which co-elute as another pre-peak at a different retention time from the oxidized Trp species. These observations indicate that the HIC procedure can be utilized to monitor the oxidative status of the CDR Trp in the IgG1.     

Hydroxyl radical oxidation of cytochrome c by aerobic radiolysis

The reaction of radiolytically generated *OH with cytochrome c was investigated by mass spectrometry. Tryptic digestion and characterization of the oxidized peptides by MALDI-TOF and ESI tandem mass spectrometry identified eight different amino acid residues with oxidized side chains with no cleavage of the protein detected. Solvent-accessible aromatic and methionine residues are the most susceptible to oxidation by *OH. These results support the careful use of *OH in characterizing protein surfaces. Dose-response studies identified the residues most prone to oxidation to be Phe-36, Phe-46, and Met-80. Hydroxylation of Phe-36 and Phe-46 should serve as indicators of the presence of *OH in the mitochondrial intermembrane space. Using solutions containing 50 at.% (18)O, our study also provides a novel method of determining the source of oxygen during *OH-mediated oxidation of proteins and contributes to identification of the modified residue type, with Phe>Tyr>Met in (18)O incorporation. During aerobic radiolysis, UV-vis spectroscopy indicates that ferrocytochrome c reaches a steady state concomitant with reduction of the heme.     

The oxidation produced by hydrogen peroxide on Ca-ATP-G-actin

We report here that in vitro exposure of monomeric actin to hydrogen peroxide leads to a conversion of 6 of the 16 methionine residues to methionine sulfoxide residues. Although the initial effect of H2O2 on actin is the oxidation of Cys374, we have found that Met44, Met47, Met176, Met190, Met269, and Met355 are the other sites of the oxidative modification. Met44 and Met47 are the methionyl sites first oxidized. The methionine residues that are oxidized are not simply related to their accessibility to the external medium and are found in all four subdomains of actin. The conformations of subdomain 1, a region critical for the functional binding of different actin-binding proteins, and subdomain 2, which plays important roles in the polymerization process and stabilization of the actin filament, are changed upon oxidation. The conformational changes are deduced from the increased exposure of hydrophobic residues, which correlates with methionine sulfoxide formation, from the perturbations in tryptophan fluorescence, and from the decreased susceptibility to limited proteolysis of oxidized actin.     

Identification and characterization of oxidation and deamidation sites in monoclonal rat/mouse hybrid antibodies

Oxidation of methionine residues and deamidation of asparagine residues are the major causes of chemical degradation of biological pharmaceuticals. The mechanism of these non-enzymatic chemical reactions has been studied in great detail. However, the identification and quantification of oxidation and deamidation sites in a given protein still remains a challenge. In this study, we identified and characterized several oxidation and deamidation sites in a rat/mouse hybrid antibody. We evaluated the effects of the sample preparation on oxidation and deamidation levels and optimized the peptide mapping method to minimize oxidation and deamidation artifacts. Out of a total number of 18 methionine residues, we identified six methionine residues most susceptible to oxidation. We determined the oxidation rate of the six methionine residues using 0.05% H₂O₂ at different temperatures. Methionine residue 256 of the mouse heavy chain showed the fastest rate of oxidation under those conditions with a half life of approximately 200 min at 4 °C and 27 min at 37 °C. We identified five asparagine residues prone to deamidation under accelerated conditions of pH 8.6 at 37 °C. Kinetic characterization of the deamidation sites showed that asparagine residue 218 of the rat heavy chain exhibited the fastest rate of deamidation with a half live of 1.5 days at pH 8.6 and 37 °C. Analysis of antibody isoforms using free flow electrophoresis showed that deamidation is the major cause of the charged variants of this rat/mouse hybrid antibody.     

Chemical modification and 1H-NMR studies on the receptor-binding region of human interleukin 6

Oxidation of the Met residues of human interleukin 6 (IL-6) molecule has been performed. Reactivity of Met for the oxidation reaction was found to decrease in the order of Met50, Met118, Met185, Met162, and Met68. Chemical modifications involving oxidation and carboxypeptidase A digestion of IL-6 have led to the assignments of the methyl proton resonances of Met162 and Met185, respectively. The hydroxynitrobenzyl chromophore attached to Trp158 in the IL-6 molecule showed a different absorption spectrum when the labeled IL-6 was bound to the soluble IL-6 receptor. This result indicates that Trp158 is near the receptor-binding region in IL-6. On the basis of the 1H-NMR and chemical modification data, it has been concluded that Trp158 is in spatial proximity to Met162, His165 and Met185. The receptor-binding activity decreased with an increase in the number of oxidized Met residues. Of these five Met residues, Met162 was the residue in which the receptor-binding activity decreased in the most parallel degree with that of the oxidation reaction.     

Site-specific methionine sulfoxide formation is the structural basis of chromatographic heterogeneity of apolipoproteins A-I, C-II, and C-III.

ApoA-I and apoC-II are eluted in two isoforms and apoC-III2 is eluted in three isoforms by reversed phase high performance liquid chromatography (HPLC). The structural basis of these nongenetic heterogeneities was unravelled using HPLC of proteolytic peptides and time-of-flight secondary ion mass spectrometry (TOF-SIMS). In apoA-I, the chromatographic microheterogeneity was caused by the formation of methionine sulfoxides (MetSO). However, only residues Met112 and Met148 were found oxidized, whereas Met86 was unaffected and also resistant towards artificial oxidation. To assess whether and to what extent amino acid substitutions in apoA-I might affect methionine sulfoxidation, the tryptic peptides of 13 different mutant apoA-I proteins from 24 heterozygous apoA-I variant carriers were analyzed by HPLC. In normal apoA-I, the ratios MetSO112/Met112 and MetSO148/Met148 were highly variable. By contrast, the relative ratio of oxidation of methionine residues 112 and 148 was constant. The amino acid changes Lys107----Met, Lys107----O, Glu139----Gly, Glu147----Val, and Pro165----Arg resulted in the preferential oxidation of Met112, and Asp103----Asn resulted in a preferential oxidation of Met148; whereas Pro3----Arg, Pro3----His, Pro4----Arg, Asp89----Glu, Ala158----Asp, Glu198----Lys, and Asp213----Gly had no impact. ApoC-II and apoC-III isoforms differed by the oxidation of the two methionine residues in these proteins. Whereas in apoC-II both methionine residues were oxidized in parallel, in apoC-III the two methionine residues differed in their susceptibility towards oxidation. We conclude that the formation of MetSO depends on the molecular microenvironment within a protein.     

Characterization of specifically oxidized apolipoproteins in mildly oxidized high density lipoprotein

Atherosclerosis is a state of heightened oxidative stress. Oxidized LDL is present in atherosclerotic lesions and used as marker for coronary artery disease, although in human lesions lipids associated with HDL are as oxidized as those of LDL. Here we investigated specific changes occurring to apolipoprotein A-I (apoA-I) and apoA-II, as isolated HDL and human plasma undergo mild, chemically induced oxidation, or autoxidation. During such oxidation, Met residues in apoA-I and apoA-II become selectively and consecutively oxidized to their respective Met sulfoxide (MetO) forms that can be separated by HPLC. Placing plasma at -20 degrees C prevents autoxidation, whereas metal chelators and butylated hydroxytoluene offer partial protection. Independent of the oxidation conditions, apoA-I and apoA-II (dimer) with two MetO residues accumulate as relatively stable oxidation products. Compared to controls, serum samples from subjects with the endothelial cell nitric oxide synthase a/b genotype that is associated with increased coronary artery disease contain increased concentrations of apoA-I with two MetO residues. Our results show that during the early stages, oxidation of HDL gives rise to specifically oxidized forms of apoA-I and apoA-II, some of which may be useful markers of in vivo HDL oxidation, and hence potentially atherosclerosis.     

Ozone-induced damage of fibrinogen molecules: identification of oxidation sites by high-resolution mass spectrometry

Fibrinogen is highly susceptible to oxidation compared to other plasma proteins. Fibrinogen oxidation damages its structure and affects the protein function. Ozone-induced oxidative modifications of the fibrinogen Aα, Bβ, and γ polypeptide chains upon addition of various amounts of the oxidiser were studied by mass spectrometry. Amino acid residues located on all three chains and main structural parts of the protein were revealed to be involved in oxidation. The αC-connector was shown to be most vulnerable to oxidation as compared to other structural parts while the E region turned out to be the most protected area of the protein. For the first time, it was established that numerous amino acid residues responsible for the conversion of fibrinogen to fibrin remain unaffected upon fibrinogen oxidation. The data obtained in this study indicate that none of the identified residues, which are considered crucial for the binding of both hole “a” and hole “b” to knob “A” and knob “B”, respectively, as well as those responsible for the thrombin binding to fibrinogen E region, have been subjected to chemical alterations under moderate oxidation. The data on fibrinogen oxidation acquired in the current study enable one to assume that some of the structural fibrinogen parts and easily oxidisable residues could be endowed with antioxidant properties. New findings presented here could be essential for the detection of adaptive molecular mechanisms capable of mitigating the detrimental action of reactive oxygen species (ROS) on the functioning of oxidatively damaged fibrinogen. Data are available via ProteomeXchange with identifier PXD012046.

• Highlights

• Various oxidative modifications were detected in fibrinogen by mass spectrometry

• αC-connector has been shown to be most susceptible to oxidation

• E region proved to be least vulnerable to the action of the oxidising agent

• Some of the Met residues in the fibrinogen structure could operate as ROS scavengers

     

Inhibition of palmityl carnitine oxidation in rat liver mitochondria by tert-butyl hydroperoxide

Mitochondria as an energy generating cell device are very sensitive to oxidative damage. Our previous findings obtained in hepatocytes demonstrated that Complex I of the respiratory chain is more sensitive to oxidative damage than other respiratory chain complexes. We present additional data on isolated mitochondria showing that palmityl carnitine oxidation is strongly depressed at a low (200 microM) tert-butyl hydroperoxide (tBHP) concentration, while oxidation of the flavoprotein-dependent substrate - succinate is not affected and neither is ATP synthesis inhibited by tBHP. In the presence of tBHP, the respiratory control index for palmityl carnitine oxidation is strongly depressed, but when succinate is oxidized the respiratory control index remains unaffected. Our findings thus indicate that flavoprotein-dependent substrates could be an important nutritional factor for the regeneration process in the necrotic liver damaged by oxidative stress.     

Relationship between protein structure and methionine oxidation in recombinant human alpha 1-antitrypsin

alpha 1-Antitrypsin is a metastable and conformationally flexible protein that belongs to the serpin family of protease inhibitors. Although it is known that methionine oxidation in the protein's active site results in a loss of biological activity, there is little specific knowledge regarding the reactivity of each of the protein's methionine residues. In this study, we have used peptide mapping to study the oxidation kinetics of each of alpha 1-antitrypsin's methionines in alpha 1-AT((C232S)) as well as M351L and M358V mutants. These kinetic studies establish that Met1, Met226, Met242, Met351, and Met358 are reactive with hydrogen peroxide at neutral pH and that each reactive methionine is oxidized in a bimolecular, rather than coupled, mechanism. Analysis of Met226, Met351, and Met358 oxidation provides insights regarding the structure of alpha 1-antitrypsin's active site that allow us to relate conformation to experimentally observed reactivity. The relationship between solution pH and methionine oxidation was also examined to evaluate methionine reactivity under conditions that perturb the native structure. Methionine oxidation data show that at pH 5, global conformational changes occur that alter the oxidation susceptibility of each of alpha 1-antitrypsin's 10 methionine residues. Between pH 6 and 9, however, more localized conformational changes occur that affect primarily the reactivity of Met242. In sum, this work provides a detailed analysis of methionine oxidation in alpha 1-antitrypsin and offers new insights into the protein's solution structure.     

Tyrosinase-catalyzed grafting of sericin peptides onto chitosan and production of protein-polysaccharide bioconjugates

The capability of Agaricus bisporus tyrosinase to catalyze the oxidation of tyrosine residues of silk sericin was studied under homogeneous reaction conditions, by using sericin peptides purified from industrial wastewater as the substrate. Tyrosinase was able to oxidize about 57% of sericin-bound tyrosine residues. The reaction rate was higher than with silk fibroin, but lower than with other silk-derived model peptides, i.e. tryptic and chymotryptic soluble peptide fractions of silk fibroin, suggesting that the size and the molecular conformation of the substrate influenced the kinetics of the reaction. The concentration of tyrosine in oxidized sericin samples decreased gradually with increasing the enzyme-to-substrate ratio. The average molecular weight of sericin peptides significantly increased by oxidation, indicating that cross-linking occurred via self-condensation of o-quinones and/or coupling with the free amine groups of lysine and, probably, with sulfhydryl groups of cysteine. The high temperature shift of the main thermal transitions observed in the differential scanning calorimetry curves confirmed the formation of peptide species with higher molecular weight and higher thermal stability. Fourier transform-infrared spectra of oxidized sericin samples showed slight changes related to the loss of tyrosine and formation of oxidation products. Oxidized sericin peptides were able to undergo non-enzymatic coupling with chitosan. Infrared spectra provided clear evidence of the formation of sericin-chitosan bioconjugates under homogeneous reaction conditions. Spectral changes in the NH stretching region seem to support the formation of bioconjugates via the Michael addition mechanism.