Effects of Polyaminocarboxylate Metal Chelators on Iron-thiolate Induced Oxidation of Methionine- and Histidine-Containing Peptides

Purpose. Site-specific protein oxidation induced by prooxidant/metal/ oxygen has been recognized as one of the major degradation pathways of protein pharmaceuticals. Polyaminocarboxylate (PAC) metal chelators are commonly employed to prevent metal-catalyzed oxidation, for they sequester metals. However, studies have indicated that iron chelates may still be catalytically active due to their specific coordination geometry. The purpose of this study was to investigate how PAC chelators affect prooxidant/metal/oxygen-catalyzed oxidation of peptides containing histidine (His) and methionine (Met). Methods. PACs were applied to a model oxidizing system, dithiothreitol/iron/oxygen, which was shown to promote the oxidation of Met to Met sulfoxide in the two model peptides, GGGMGGG and GHGMGGG. Results. PAC chelators did not suppress the peptide oxidation but significantly changed the product pattern. In particular, the yield of Met sulfoxide dropped significantly, while a number of other products emerged, including oxidation products from the N-terminus and His (if present). Overall, the oxidation became rather non-selective in the presence of PACs. The oxidation kinetics were significantly accelerated by nitrilotriacetate (NTA), ethylenediaminediacetate (HDDA), and ethylenediaminetetraacetate (EDTA), but they were slowed down by ethyl-enebis(oxyethylenenitrilo)tetraacetate (EGTA) and diethylenetriaminepentaacetate (DTPA). Meanwhile the PAC chelators were also observed to undergo degradation. Scavengers of hydrogen peroxide or hydroxyl radicals exerted only partial inhibition on the peptide oxidation. Conclusions. The results of this study are rationalized by the abilities of PAC chelators (i) to extract iron from potential binding sites of the peptides to impair site-specific oxidation, and (ii) to promote the formation of ROS different from the species formed at the peptide metal-binding sites.     

The Kinetics of Relaxin Oxidation by Hydrogen Peroxide

In this study, hydrogen peroxide was used to study the oxidation of rhRlx under various conditions. Oxidation of rhRlx occurred at both of the two methionines on the B chain, Met B(4) and Met B(25), as expected from the three-dimensional structure of the molecule, which shows that these two residues are located on the surface of the molecule and exposed to solvent. The reaction produced three different oxidized forms of rhRlx containing either Met B(4) sulfoxide, Met B(25) sulfoxide, or both residues oxidized. The corresponding sulfone was not formed under these conditions. The oxidation at the two methionines proceeded independently from each other but Met B(25) was oxidized at a significantly faster rate than Met B(4). The fact that the rate of oxidation at Met B(25) was identical to the rate of oxidation of free methionine and that of two model peptides mimicking the residues around Met B(4) and Met B(25) suggests that the lower reactivity at Met B(4) was due to steric hindrance, and at least in this case, neighboring groups do not influence the oxidation kinetics of methionine residues. The reaction was independent of pH, ionic strength, and buffer concentration in the range studied. The enthalpy of activation for the reaction was approximately 10–14 kcal mol^–1, with an entropy of activation of the order of –30 cal K^–1 mol^–1. These data are consistent with previously published mechanisms for organic sulfide oxidation by alkyl hydroperoxides.     

Oxidation of Human Insulin-like Growth Factor I in Formulation Studies: Kinetics of Methionine Oxidation in Aqueous Solution and in Solid State

Purpose. The aim of this work was to study the kinetics of oxidation of methionine in human Insulin-like Growth Factor I (hIGF-I)¹ in aqueous solution and in the solid state by the aid of quantification of oxygen. Methods. The oxidized form of hIGF-I was characterized by tryptic peptide analysis, RP-HPLC and FAB-MS and quantified by RP-HPLC. The oxygen content was quantified polarographically by a Clark-type electrode. Results. Second-order kinetics with respect to amount of protein and dissolved oxygen was found to be appropriate for the oxidation of methionine in hIGF-I. The rate constants ranged from 1 to 280 M^–1 month^–l and had an activation energy of 95 (+/–4) kJ/mole. Light exposure, storage temperature and oxygen content were found to have a considerable impact on the oxidation rates. No significant difference in reaction rates was found for the oxidation of hIGF-I in aqueous solution or in the solid state. A method for decreasing the oxygen content in aqueous solution without purging is described. Conclusions. Polarographic quantification of dissolved oxygen makes it possible to establish the kinetics for oxidation of proteins. The oxidation of methionine in hIGF-I appears to follow second-order kinetics.     

Chemical Pathways of Peptide Degradation. V. Ascorbic Acid Promotes Rather than Inhibits the Oxidation of Methionine to Methionine Sulfoxide in Small Model Peptides

The effect of primary structure and external conditions on the oxidation of methionine to methionine sulfoxide by the ascorbate/Fe³⁺ system was studied in small model peptides. Degradation kinetics and yield of sulfoxide formation were dependent on the concentration of ascorbate and H⁺, with a maximum rate observed at pH 6–7. Phosphate buffer significantly accelerated the peptide degradation compared to Tris, HEPES, and MOPS buffers; however, the formation of sulfoxide was low. The oxidation could not be inhibited by the addition of EDTA. Other side products besides sulfoxide were observed, indicating the existence of various other pathways. The influence of methionine location at the C terminus, at the N terminus, and in the middle of the sequence was investigated. The presence of histidine in the sequence markedly increased the degradation rate as well as the sulfoxide production. The histidine catalysis of methionine oxidation occurred intramolecularly with a maximum enhancement of the oxidation rate and sulfoxide production when one residue was placed between the histidine and the methionine residue.     

Mechanisms of potentiation of Angiotensin II-induced contractile response of isolated rat aorta by hydrogen peroxide and tert-butyryl hydroperoxide

Objective:

To study the mechanism involved in hydrogen peroxide (H₂O₂) or tert-butyl hydroperoxide (t-BHP)-induced potentiation of the Ang II-mediated contraction of isolated rat thoracic aorta.

Materials and Methods:

Thoracic aorta was isolated from the Sprauge dawley rats (300–320 gm), cut spirally and response to Ang II (5 × 10⁻⁸M) was taken in the absence and presence of H₂O₂ (10⁻⁶M) and t-BHP (10⁻⁵M). To explore the probable mechanism of H₂O₂ and t-BHP-induced potentiation of Ang II-mediated contractile response, different blockers such as losartan (AT₁ receptor blocker; 1 μM), catalase (H₂O₂ scavenger; 500 U/ml), lercanidipine (L-type calcium channel blocker; 1 μM), geinistein (tyrosine kinase inhibitor; 100 μM), and indomethacin (cyclo-oxygenase inhibitor; 10 μM) were used.

Results:

In spiral preparation of rat thoracic aorta, H₂O₂ (10⁻⁶M) and t-BHP (10⁻⁵M) did not produce the contraction as such. However, when they are added simultaneously with Ang II (5 × 10⁻⁸ M), they potentiated the contractile response of the Ang II. Catalase (500 U/ml) partially antagonized the Ang-II-induced contraction, as well as antagonized the potentiation induced by H₂O₂. Losartan (1 μM) and lercanidipine (1 μM) antagonized the Ang II-induced contractile response without affecting H₂O₂ (10⁻⁶M)-mediated potentiation. Geinistein (100 μM) antagonized H₂O₂ (10⁻⁶M)-mediated potentiation, but it slightly decreased the Ang II response. Losartan (1 μM) and lercanidipine (1 μM) and Geinistein (100 μM) antagonized the Ang II-induced contractile response but not t-BHP-mediated potentiation. Indomethacin antagonized t-BHP-mediated potentiation without affecting much of Ang II response.

Conclusion:

From the above-mentioned results, we can reasonably conclude that H₂O₂ and t-BHP potentiated the contraction induced by the Ang II. H₂O₂-induced potentiation of Ang II response may be mediated through tyrosine kinase activation and t-BHP through the activation of cyclo-oxygenase enzyme.     

Chemical Pathways of Peptide Degradation. VIII. Oxidation of Methionine in Small Model Peptides by Prooxidant/Transition Metal Ion Systems: Influence of Selective Scavengers for Reactive Oxygen Intermediates

In the presence of oxygen, Fe(III), and an appropriate electron donor (e.g. ascorbic acid, dithiothreitol), the oxidation of methionine residues to methionine sulfoxides in small model peptides can be induced. It is shown in this study that these oxidations can be retarded by catalase in a pH-dependent manner, by some hydroxyl radical scavengers, and by azide. In contrast, superoxide dismutase has only a minimal effect, indicating that the superoxide radical does not contribute significantly to the oxidation of the methionine residue. The experimental results can be interpreted by invoking hydrogen peroxide as the major oxidizing species at pH 7, whereas the involvement of free hydroxyl radicals seems to be negligible. Other reactive oxygen intermediates such as iron-bound hydroperoxy, or site-specifically generated reactive oxygen species may be actively involved in the oxidation of methionine residues at pH > 7.     

Relationships Between Histological and Functional Indices of Acute Chemically Induced Nephrotoxicity

Relationships Between Histological and Functional Indices ofAcute Chemically Induced Nephrotoxicity. Miyajima, H., Hewitt,W.R., Côté, M.G., and Plaa, G.L. (1983). Fundam.Appl. Toxicol. 3: 543–551. Acute renal injury was producedin rats with K₂Cr₂O₇ (5–40 mg/kg, sc) HgCl₂ (0.5–5.0mg/kg, sc) or cephaloridine (0.5–3.0 g/kg, sc). Histological(percentage of normal, degenerated or necrotic cells) and functionalindices (relative kidney weight, renal cortical slice accumulationof organic ions, and blood urea nitrogen content) were evaluated48 hours later. The relative sensitivity of each of these indiceswas determined for each nephrotoxicant. Renal cortical accumulationof organic ions appeared to be the most sensitive of the functionalparameters. A quantitative histological evaluation was foundto be as sensitive an indicator of nephrotoxicity as organicion accumulation. Alterations in each of the functional indiceswere significantly correlated with changes in renal histology.     

Metal-Catalyzed Oxidation of Brain-Derived Neurotrophic Factor (BDNF): Analytical Challenges for the Identification of Modified Sites

Purpose. We examined the metal-catalyzed oxidation of brain-derivedneurotrophic factor (BDNF) using the Cu(II)/ascorbate/O₂ modeloxidative system. Methods. Electrospray ionization mass spectrometry, peptide mappingand amino acid analysis were utilized to determine the nature of thecovalent modification induced by the metal-catalyzed oxidative system.Additionally, analytical ultracentrifugation, the Bradford assay, circulardichroism and ANSA dye-binding were used to determine the natureof any conformational changes induced by the oxidation. Results. Exposure of BDNF to the Cu(II)/ascorbate/O₂ system led tothe modification of ca. 35% of Met⁹² to its sulfoxide, and to subsequentconformational changes. The proteolytic digestion procedure wassensitive to this conformational change, and was unable to detect themodification. Chemical digestion with CNBr, however, was not sensitive tothis change, and allowed for the identification of the site ofmodification. Conclusions. The modification of Met⁹² to its sulfoxide rendered theoxidized BDNF inaccessible to proteolytic digestion, due toconformational changes associated with the oxidation.     

Oxidation of Recombinant Human Interleukin-2 by Potassium Peroxodisulfate

Purpose. The oxidation of recombinant human interleukin-2 (rhIL-2) by potassium peroxodisulfate (KPS) with or without N,N,N,N-tetramethylethylenediamine (TEMED), which are used for the preparation of dextran-based hydrogels, was investigated. Methods. The oxidation of (derivatives of) methionine, tryptophan, histidine and tyrosine, as well as rhIL-2 was investigated. Both the oxidation kinetics (RP-HPLC) and the nature of the oxidation products (mass spectrometry) were studied as a function of the KPS and TEMED concentration, and the presence of a competitive antioxidant, methionine. Results. Under conditions relevant for the preparation of rhIL-2 loaded hydrogels, only methionine and tryptophan derivatives were susceptible to oxidation by KPS. The oxidation of these compounds was inhibited once TEMED was present, suggesting that the peroxodisulfate anion, rather than the radicals formed in the presence of TEMED, is the oxidative species. KPS only induced oxidation of the four methionines present in rhIL-2, whereas the tryptophan residue remained unaffected. The radicals, formed after KPS decomposition by TEMED, induced some dimerization of rhIL-2. The oxidation of rhIL-2 could be substantially reduced by the addition of methionine, or by pre-incubation of KPS with TEMED. Conclusions. Only the methionine residues in rhIL-2 are oxidized by KPS. The extent of oxidation can be minimized by a proper selection of the reaction conditions.     

过氧化氢氧化降解法制备低分子玻璃酸

目的制备低分子玻璃酸 (HA)。方法过氧化氢氧化降解法。结果随着过氧化氢浓度增加 ,反应温度的升高 ,降解速率加快。中性条件下HA的氧化降解速率较快 ,而酸性或碱性时却较慢。为了方便降解过程的可控性 ,过氧化氢浓度选 0 .0 5 % ,反应温度定为 5 0℃ ,反应pH为中性。随着HA相对分子质量的降低 ,运动黏度迅速下降 ,而糖醛酸含量基本不变。不同过氧化氢浓度降解时 ,低分子HA收率基本相同。结论过氧化氢氧化降解法可用于制备低分子HA。     

Effect of Iron Oxide Nanoparticles on the Oxidation and Secondary Structure of Growth Hormone

Oxidation of therapeutic proteins (TPs) can lead to changes in their pharmacokinetics, biological activity and immunogenicity. Metal impurities such as iron are known to increase oxidation of TPs, but nanoparticulate metals have unique physical and chemical properties compared to the bulk material or free metal ions. Iron oxide nanoparticles (IONPs) may originate from equipment used in the manufacturing of TPs or from needles during injection. In this study, the impact of IONPs on oxidation of a model protein, rat growth hormone (rGH), was investigated under chemical stress. Hydrogen peroxide (H₂O₂)- and 2,2′-azobis (2-methylpropionamidine) dihydrochloride oxidized methionine residues of rGH, but unexpectedly, oxidation was suppressed in the presence of IONPs compared to a phosphate buffer control. Fourier transform infrared spectroscopy indicated splitting of the α-helical absorbance band in the presence of IONPs, whereas circular dichroism spectra showed a reduced α-helical contribution with increasing temperature for both rGH and rGH-IONP mixtures. The results collectively indicate that IONPs can increase the chemical stability of rGH by altering the kinetics and preference of amino acid residues that are oxidized, although the changes in protein secondary structure by IONPs may lead to alterations of physical stability.     

Oxidation of Recombinant Human Parathyroid Hormone: Effect of Oxidized Position on the Biological Activity

Purpose. To determine the oxidation products of recombinant human parathyroid hormone (rhPTH) treated with H₂O₂, the amino acid residue oxidized, and the biological activity of the oxidation products. Methods. Oxidized residues were determined by CNBr cleavage, trypsin digestion and subsequent fast atom bombardment mass spectrometry. The biological activity of each oxidized rhPTH was examined in rat osteosarcoma cell adenylate cyclase assay. Results. Three oxidized products were isolated, namely, Met at position 8 (Met8) sulfoxide, Met at position 18 (Met 18) sulfoxide and both positions Met sulfoxide. It appears that the Met8 and Met 18 oxidized forms are intermediates in the generation of the Met doubly oxidized form. All oxidized forms possessed reduced biological activity, more so for oxidation at Met8 than at Met 18. Conclusions. The region around Met8 is important for the activity of the parathyroid hormone.     

Comparison of CYP2D6 Content and Metoprolol Oxidation Between Microsomes Isolated from Human Livers and Small Intestines

Purpose. To assess the role of intestinal CYP2D6 in oral first-pass drug clearance by comparing the enzyme content and catalytic activity of a prototype CYP2D6 substrate, metoprolol, between microsomes prepared from human intestinal mucosa and from human livers. Methods. Microsomes were prepared from a panel of 31 human livers and 19 human intestinal jejunal mucosa. Microsomes were also obtained from the jejunum, duodenum and ileum of four other human intestines to assess regional distribution of intestinal CYP2D6. CYP2D6 content (pmole/mg microsomal protein) was determined by Western blot. CYP2D6 activity was measured by -hydroxylation and O-demethylation of metoprolol. Results. Kinetic studies with microsomes from select livers (n = 6) and jejunal mucosa (n = 5) yielded K_M estimates of 26 ± 9 M and 44 ± 17 M, respectively. The mean V_max (per mg protein) for total formation of -OH-M and ODM was 14-fold higher for the liver microsomes compared to the jejunal microsomes. Comparisons across intestinal regions showed that CYP2D6 protein content and catalytic activity were in the order of jejunum > duodenum > ileum. Excluding the poor metabolizer genotype donors, CYP2D6 content varied 13-and 100-fold across the panels of human livers (n = 31) and jejunal mucosa (n = 19), respectively. Metoprolol -hydroxylation activity and CYP2D6 content were highly correlated in the liver microsomes (r = 0.84, p < 0.001) and jejunal microsomes (r = 0.75, p < 0.05). Using the well-stirred model, the mean microsomal intrinsic clearance (i.e., V_max/K_M) for the livers and jejunum were scaled to predict their respective in vivo organ intrinsic clearance and first-pass extraction ratio. Hepatic and intestinal first-pass extractions of metoprolol were predicted to be 48% and 0.85%, respectively. Conclusions. A much lower abundance and activity of CYP2D6 are present in human intestinal mucosa than in human liver. Intestinal mucosal metabolism contributes minimally to the first-pass effect of orally administered CYP2D6 substrates, unless they have exceptionally high microsomal intrinsic clearances and/or long residence time in the intestinal epithelium.     

Effects of Excipients on the Hydrogen Peroxide-Induced Oxidation of Methionine Residues in Granulocyte Colony-Stimulating Factor

No HeadingPurpose. The objective of this study was to elucidate the different mechanisms of action of different excipients on the oxidation of Met¹, Met¹²², Met¹²⁷, and Met¹³⁸ in granulocyte colony-stimulating factor (G-CSF) by using hydrogen peroxide as the oxidant.Methods. The oxidation of Met¹, Met¹²⁷, and Met¹³⁸ was quantified by peptide mapping analysis. The oxidation of Met¹²² has biphasic oxidation kinetics with a faster second phase. Therefore, the oxidation of Met¹²² was quantified by two different methods: peptide mapping analysis for the first phase of oxidation and direct reverse-phase HPLC for the second phase of oxidation.Results. The current work reveals that the preferential excluding excipients sorbitol, sucrose, and trehalose, in the concentration range 0–30% (w/v), and the preferential binding excipients urea and guanidine hydrochloride, in the concentration range 0–0.8 M, do not affect the oxidation of methionine residues in G-CSF at pH 4.5. The chelating agents citrate and EDTA have different effects on the rates of oxidation of methionine residues in G-CSF. At low concentrations, citrate decreases the rates, while at high concentrations, citrate increases the rates. EDTA decreases the rates of oxidation of methionine residues in G-CSF, such that its effect becomes more and more as its concentration is increased from 0 to 200 mM. The efficacy of EDTA on the rates of oxidation of the four methionine residues in G-CSF follows the order Met¹²² > Met¹²⁷ > Met¹³⁸ > Met¹.Conclusions. Our results indicate that EDTA can protect the methionine residues in G-CSF against oxidation induced by hydrogen peroxide. The more exposed the methionine residue is, the more difficult it is to be protected by EDTA. The mechanism may be due to the specific ion binding of EDTA to proteins.     

Adrenocorticotropin 57, Synthesis and biological activity of ostrich and turkey hormones*

Synthesis of ostrich and turkey corticotropin (ACTH) has been accomplished by the solid-phase method. Each was identical to the natural hormone in high performance liquid chromatography. Relative potencies in a lipolytic assay in isolated rabbit fat cells were: human ACTH, 100; ostrich ACTH, 53; turkey ACTH, 28. In isolated rat fat cells relative lipolytic potencies were: human ACTH, 100; ostrich ACTH, 2; turkey ACTH, 13. It was concluded that lipolytic potency is sensitive to alterations in structure throughout the entire length of the ACTH sequence in the rat fat cell assay.     

The Solid State Oxidation of Methionine Containing Peptide: A Preliminary Study Using Time of Flight Secondary Ion Mass Spectrometry

Purpose. A surface sensitive mass spectrometric technique: Time ofFlight Secondary Ion Mass Spectrometry (ToF-SIMS) was introducedto study the solid state instability of a methionine containing peptidecaused by the oxidation of the methionine residue. Methods. The oxidation of a neuropeptide Methinonine-Enkephalin(ME) in air and under UV acceleration was studied by ToF-SIMS. Results. The apparent oxidation rate is defined by the peak ratio ofoxidized molecular ion over unoxidized molecular ion. ME is oxidizedat a faster rate to its sulfoxide derivative in the UV accelerated oxidationenvironment than in lab air. The calibration curve for evaluating theionization probability ratio of the oxidized deprotonated molecular iondivided by the unoxidized deprotonated molecular ion was obtained.This could be used to extract the real oxidation rate of ME in thesolid state. Conclusions. The preliminary results showed that ToF-SIMS with simplesample handling, fast data acquisition, together with excellentsurface sensitivity and detection limit could be an applicable and convenienttool to study peptide reactions in the solid state such as oxidationand deamidation process.     

Protective effect of medicinal plant extracts on biomarkers of oxidative stress in erythrocytes

Plants are universally recognized as a vital part of the world’s natural heritage and up to 80% of the population rely on plants for their primary healthcare. Varieties of medicinal plants are recognized as a source of natural antioxidants that can protect from oxidative stress, thus playing an important role in chemoprevention of diseases. In the present investigation, 22 extracts from different parts of eight medicinal plants (Punica granatum Linn. (Punicaceae), Caesalpinia bonducella Flem. (Fabaceae), Hibiscus subdariffa Linn. [(Malvaceae), Moringa oleifera Lam. (Moringaceae), Garcinia indica Linn. (Clusiaceae), Emblica officinalis Gaertn. (Euphorbiaceae), Momordica charantia Linn. (Cucurbitaceae), and Matricaria chamomilla Linn. (Asteraceae)] were screened for their protection against oxidative stress in erythrocytes induced by hydrogen peroxide (2?mM) and tert-butyl hydroperoxide (0.01?mM). The effect was also compared with known antioxidants and flavonoids. Subjecting erythrocytes to oxidative stress by incubation with hydrogen peroxide and tert-butyl hydroperoxide caused a significant alteration in reduced glutathione (GSH) and malondialdehyde (MDA) concentration compared to the control. Our results show that medicinal plant extracts protect erythrocytes from hydrogen peroxide and tert-butyl hydroperoxide induced oxidative stress; known antioxidant (vitamin C, E, and β-carotene) and flavonoid (quercetin) also showed a similar protective effect. Our observations may, in part, suggest the use of the spent/waste parts of medicinal plants. This could be an economically viable source of natural and potent antioxidants effective against complications arising from oxidative stress. The results may also improve the ethanopharmacological knowledge of medicinal plants.     

2种光源对体外3T3细胞光毒性试验结果的比较

目的 比较2种光源对体外3T3细胞光毒性试验结果的影响。方法 参照化学品体外3T3中性红摄取光毒性试验指导原则（OECD 432）,采用模拟阳光光源和紫外光源对6种参考物质进行试验。结果 6种参考物质在2种光源照射后其光刺激因子和平均光效应均接近OECD 432中的参考值,各个物质在无光和有光下的IC₅₀值也相近。结论 2种光源对体外3T3细胞光毒性试验结果基本无影响。     

Effects of Antioxidants on the Hydrogen Peroxide-Mediated Oxidation of Methionine Residues in Granulocyte Colony-Stimulating Factor and Human Parathyroid Hormone Fragment 13-34

No HeadingPurpose. The effects and mechanisms of different antioxidants, methionine, glutathione, acetylcysteine, and ascorbic acid (AscH₂), on the oxidation of methionine residues in granulocyte colony-stimulating factor (G-CSF) and human parathyroid hormone fragment 13-34 (hPTH 13-34) by hydrogen peroxide (H₂O₂) were quantified and analyzed.Methods. The rates of oxidation of methionine residues in G-CSF were determined by peptide mapping analyses, and the oxidation of methionine residue in hPTH 13-34 was quantified by reverse-phase HPLC.Results. At pH 4.5, free methionine reduces, glutathione and acetylcysteine have no obvious effect on, and AscH₂ promotes the rates of oxidation of methionine residues in G-CSF. The H₂O₂-induced oxidation rate constants for free methionine, acetylcysteine, and glutathione at pH 4.5 were measured to be 32.07, 1.00, and 1.63 M^-1h^-1, respectively, while the oxidation rate constant for Met¹, the most readily oxidizable methionine residue in G-CSF, is 13.95 M^–1h^–1. Therefore, the different effects of free methionine, acetylcysteine, and glutathione on the rates of oxidation of methionine residues in G-CSF are consistent with their different reactivity toward oxidation by H₂O₂. By using hPTH 13-34, the effect of AscH₂ on the H₂O₂-induced oxidation of methionine residue was quantified, and the mechanisms involved were proposed. Because of the presence of trace transition metal ions in solution, at low concentrations, AscH₂ is prone to be a prooxidant, increasing the hydroxyl radical (OH) production rate via Fenton-type reactions. In addition to peroxide oxidation, these radicals lead to the degradation of hPTH 13-34 to smaller peptide fragments. At high concentrations, AscH₂ tends to act as an OH scavenger. EDTA inhibits OH production and thus eliminates the degradation of hPTH 13-34 by forming complexes with transition metal ions. However, the rate of oxidation of the methionine residue in hPTH 13-34 increases as the concentration of AscH₂ is increased from 0 to 200 mM, and the reason for this is still not clear.Conclusions. Our results demonstrate that free methionine is an effective antioxidant to protect G-CSF against methionine oxidation at pH 4.5. Acetylcysteine and glutathione are not effective antioxidants at pH 4.5. Their oxidation rates at different pH values imply that they would be much more effective antioxidants than free methionine at alkaline conditions. AscH₂ is a powerful electron donor. It acts as a prooxidant in the conditions in this study and is unlikely to prevent oxidation by H₂O₂ in protein formulation, whether or not EDTA is present.     

Oxidation of Human Insulin-Like Growth Factor I in Formulation Studies,II. Effects of Oxygen,Visible Light,and Phosphate on Methionine Oxidation in Aqueous Solution and Evaluation of Possible Mechanisms

Purpose. The oxidation of methionine in human Insulin-like Growth Factor I (hIGF-I) in aqueous solution was studied with respect to oxygen, visible light and sodium phosphate. Methods. Aqueous solutions of hIGF-I were prepared with different amounts of phosphate and dissolved oxygen. The solutions were stored either in darkness or exposed to artificial visible light. The oxidized hIGF-I was quantified by RP-HPLC. A two level full factorial experimental design, with two levels of each of the three factors studied, was used. Results. Oxidation was found to be positively correlated with light, oxygen content and, interestingly, phosphate. The increasing effect of phosphate on the oxidation appears not to originate from metal contaminants. The influence of both oxygen and phosphate increased with time. The pH dependence of oxidation indicated the formation of a phosphorylated sulfonium ion as an oxidation intermediate. A significant interaction effect between phosphate and visible light suggested participation of radicals. Conclusions. Factorial experiments provide a valuable tool when studying complex mechanisms with interacting factors. The oxidation of methionine in hIGF-I is significantly affected by light but also by the presence of phosphate buffer.