Generation of intramolecular and intermolecular sulfenamides, sulfinamides, and sulfonamides by hypochlorous acid: a potential pathway for oxidative cross-linking of low-density lipoprotein by myeloperoxidase.

Oxidized low-density lipoprotein (LDL) is implicated in atherogenesis, and human atherosclerotic lesions contain LDL oxidized by myeloperoxidase, a heme protein secreted by activated phagocytes. Using hydrogen peroxide (H(2)O(2)), myeloperoxidase generates hypochlorous acid (HOCl), a powerful oxidant. We now demonstrate that HOCl produces sulfenamides, sulfinamides, and sulfonamides in model peptides, which suggests a potential mechanism for LDL oxidation and cross-linking. When we exposed the synthetic peptide PFKCG to HOCl, the peptide's thiol residue reacted rapidly, generating a near-quantitative yield of products. Tandem mass spectrometric analysis identified the products as the sulfenamide, sulfinamide, and sulfonamide, all formed by intramolecular cross-linking of the peptide's thiol and lysine residues. An intramolecular sulfinamide was also observed after the peptide PFRCG was exposed to HOCl, indicating that the guanidine group of arginine can also form a sulfur-nitrogen cross-link. The synthetic peptide PFVCG, which contains a free thiol residue but lacks nucleophilic amino acid side chains, formed an intermolecular sulfonamide when exposed to HOCl. Tandem mass spectrometric analysis of the dimer revealed that the free N-terminal amino group of one PFVCG molecule cross-linked with the thiol residue of another. This peptide also formed intermolecular sulfonamide cross-links with N(alpha)-acetyllysine after exposure to HOCl, demonstrating that the epsilon-amino group of a lysine residue can undergo a similar reaction. Moreover, human neutrophils used the myeloperoxidase-H(2)O(2) system to generate sulfinamides in model peptides containing lysine or arginine residues. Collectively, our observations raise the possibility that HOCl generated by myeloperoxidase contributes to intramolecular and intermolecular protein cross-linking in the artery wall. Myeloperoxidase might also use this mechanism to form sulfur-nitrogen cross-links in other inflammatory conditions.     

Spectroscopic characterization of thioredoxin covalently modified with monofunctional organoarsenical reagents

Thioredoxin upon reduction with mercaptoethylamine was subjected to covalent modification by the monofunctional organoarsenical reagents H2NPhAsO and HO(CH2)4AsCl2. The degree of modification was monitored by the percentage loss in free thiol content as measured by the reaction with the thiol reagent 5,5'-dithiobis(2-nitrobenzoic acid). The modification results in the formation of a stable 15-membered cyclic dithioarsenite ring that readily extrudes the arsenic moiety upon the addition of 2,3-dimercaptopropanol. The conformational effects of this modification were monitored by steady-state fluorescence and circular dichroism. On the basis of circular dichroic spectra, it appeared that the protein experiences no significant backbone conformational change from this modification. The degree of conformational change was found to be within the range observed upon reduction of the oxidized thioredoxin. Steady-state fluorescence revealed that the arsenicals caused strong quenching of the tryptophan fluorescence. Stern-Volmer titrations revealed that the quenching was a function of both the nature of the organic group and its covalent attachment to the "spatially close" thiols. The analysis of the spectroscopic results obtained with the arsenical reagents provides further insight into the nature of the conformational change that has been observed upon reduction of thioredoxin.     

Inhibition of protein hydroperoxide formation by protein thiols

Studies on plasma and cells exposed to hydroxyl and peroxyl radicals have indicated that there are few inhibitors of protein hydroperoxide formation. We have, however, observed a small variable lag period during bovine serum albumin (BSA) oxidation by 2-2' azo-bis-(2-methyl-propionamidine) HCl (AAPH) generated peroxyl radicals, where no protein hydroperoxide was formed. The addition of free cysteine to BSA during AAPH oxidation also produced a lag phase suggesting protein thiols could inhibit protein hydroperoxide formation. The selective reduction of thiols on BSA by beta-mercaptoethanol treatment caused the appearance of a lag period where no protein hydroperoxide was formed during the AAPH mediated oxidation. Increasing free thiol concentration on the BSA increased the lag period. Protein hydroperoxide formation began when the protein thiol concentration dropped below one thiol per BSA molecule. It is unlikely that the lag period is due to gross structural alteration of the reduced protein since blocking the free thiols with N-ethyl maleimide eliminated the lag in protein hydroperoxide formation. Protein thiols were found to be ineffective in inhibiting hydroxyl radical-mediated protein hydroperoxide formation during X-ray radiolysis. Evidence is given for protein thiol oxidation occurring via a free radical mediated chain reaction with both free cysteine and protein bound thiol. The data suggest that reduced protein thiol groups can inhibit protein hydroperoxide formation by scavenging peroxyl radicals.     

An ESR investigation of the reactions of glutathione, cysteine and penicillamine thiyl radicals: competitive formation of RSO., R., RSSR-., and RSS(.)

The reactions of the cysteine, glutathione and penicillamine thiyl radicals with oxygen and their parent thiols in frozen aqueous solutions have been elucidated through electron spin resonance spectroscopy. The major sulfur radicals observed are: (1) thiyl radicals, RS.; (2) disulfide radical anions. RSSR-.; (3) perthiyl radicals, RSS. and upon introduction of oxygen; (4) sulfinyl radicals, RSO., where R represents the remainder of the cysteine, glutathione or penicillamine moiety. The radical product observed depends on the pH, concentration of thiol, and presence or absence of molecular oxygen. We find that the sulfinyl radical is a ubiquitous intermediate in the free radical chemistry of these important biological compounds, and also show that peroxyl radical attack on thiols may lead to sulfinyl radicals. We elaborate the observed reaction sequences that lead to sulfinyl radicals, and, using 17O isotopic substitution studies, demonstrate that the oxygen atom in sulfinyl radicals originates from dissolved molecular oxygen. In addition, the glutathione thiyl radical is found to abstract hydrogen from the alpha-carbon position on the cysteine residue of glutathione to form a carbon-centered radical.     

Inhibition of protein hydroperoxide formation by protein thiols

Abstract

Studies on plasma and cells exposed to hydroxyl and peroxyl radicals have indicated that there are few inhibitors of protein hydroperoxide formation. We have, however, observed a small variable lag period during bovine serum albumin (BSA) oxidation by 2-2′ azo-bis-(2-methyl-propionamidine) HCl (AAPH) generated peroxyl radicals, where no protein hydroperoxide was formed. The addition of free cysteine to BSA during AAPH oxidation also produced a lag phase suggesting protein thiols could inhibit protein hydroperoxide formation. The selective reduction of thiols on BSA by β-mercaptoethanol treatment caused the appearance of a lag period where no protein hydroperoxide was formed during the AAPH mediated oxidation. Increasing free thiol concentration on the BSA increased the lag period. Protein hydroperoxide formation began when the protein thiol concentration dropped below one thiol per BSA molecule. It is unlikely that the lag period is due to gross structural alteration of the reduced protein since blocking the free thiols with N-ethyl maleimide eliminated the lag in protein hydroperoxide formation. Protein thiols were found to be ineffective in inhibiting hydroxyl radical-mediated protein hydroperoxide formation during X-ray radiolysis. Evidence is given for protein thiol oxidation occurring via a free radical mediated chain reaction with both free cysteine and protein bound thiol. The data suggest that reduced protein thiol groups can inhibit protein hydroperoxide formation by scavenging peroxyl radicals.     

A new bromine-containing reagent for cysteine modification

5-Bromo-2[(2-iodoacetyl)amino]benzenesulfonic acid (AIBSA), a reagent for modification of free of cysteine thiol groups in proteins and peptides, was synthesized. Rate constants of its interaction with thiol groups were determined. The presence of a bromine atom allows an easy identification of the AIBSA-labeled peptides in mass spectra due to the characteristic isotope distribution. The compound is stable in solution and under exposure to light.     

A new bromine-containing reagent for cysteine modification

5-Bromo-2[(2-iodoacetyl)amino]benzenesulfonic acid (AIBSA), a reagent for modification of free of cysteine thiol groups in proteins and peptides, was synthesized. Rate constants of its interaction with thiol groups were determined. The presence of a bromine atom allows an easy identification of the AIBSA-labeled peptides in mass spectra due to the characteristic isotope distribution. The compound is stable in solution and under exposure to light.     

Disulfide and secondary structures of recombinant human granulocyte colony stimulating factor

Molecular characteristics and secondary structures of recombinant methionyl human granulocyte colony stimulating factor produced by genetically engineered Escherichia coli are described. Limited radiolabeling of the protein with tritiated iodoacetate and determination of the labeled residue revealed that this recombinant protein contains only one free cysteine at position 17 which is not essential for activity. The free cysteine is inaccessible to modification unless the molecule is unfolded under denaturing conditions. The molecule forms two disulfide bridges which were assigned as Cys(36)-Cys(42) and Cys(64)-Cys(74) based on the results of isolation and characterization of disulfide-containing peptides obtained from a subtilisin digest of the intact protein. CD analyses and secondary structure prediction suggest that the molecule is abundant in alpha-helical structures.     

Free thiols of platelet thrombospondin. Evidence for disulfide isomerization

The free thiols of platelet thrombospondin (TSP) were derivatized with labeled N-ethylmaleimide (NEM) or iodoacetamide (IAM). When Ca2+ was chelated with EDTA, 2.9 mol of NEM or 2.6 mol of IAM reacted/mol of native TSP. No additional thiols were found after denaturation with urea. Since TSP has three apparently identical polypeptide chains, this suggests one free thiol/polypeptide chain. Ca2+ protected all of the thiols from reaction with IAM. In Ca2+ about half the thiols reacted normally with NEM and the others were unreactive, indicating that the thiols of TSP are not identical. The number of reactive thiols as a function of [Ca2+] revealed a sigmoidal curve with a transition midpoint of 207 microM. The ability of analogs of NEM to compete for derivatization of the thiols with labeled NEM was greater with larger, more hydrophobic agents. Gel electrophoretic separation of labeled TSP that had been partially digested with thrombin and trypsin indicated that some of the label was in the C-terminal tryptic fragment but that most was in the adjacent trypsin-sensitive region. After cyanogen bromide cleavage of the labeled and reduced protein, four labeled fractions were obtained from a gel filtration column. With subsequent combinations of tryptic digestion and reversed-phase high performance liquid chromatography, labeled peptides were purified from these four fractions, and the amino acid sequences were determined. Twelve labeled cysteines were identified, each with a specific radioactivity less than that of the thiol labeling reagent, indicating that only a fraction of that cysteine in a population of TSP molecules was a free thiol at the time of derivatization. While 2 labeled cysteines are in the non-repeating C-terminal portion of the molecule, the other 10 labeled cysteines are in the adjacent trypsin-sensitive type 3 repeats proposed (Lawler, J., and Hynes, R. O. (1986) J. Cell. Biol. 103, 1635-1648) as the calcium-binding region of the molecule. The disulfide bonds most sensitive to reduction by dithioerythritol were also stabilized by Ca2+, implying location in the Ca2(+)-sensitive part of the molecule. It is proposed that one equivalent of free thiol/polypeptide chain is distributed among 12 different cysteine residues through an intramolecular thioldisulfide isomerization.     

Mass spectrometric analysis of nitroxyl-mediated protein modification: comparison of products formed with free and protein-based cysteines

Although biologically active, nitroxyl (HNO) remains one of the most poorly studied NO(x). Protein-based thiols are suspected targets of HNO, forming either a disulfide or sulfinamide (RSONH2) through an N-hydroxysulfenamide (RSNHOH) addition product. Electrospray ionization mass spectrometry (ESI-MS) is used here to examine the products formed during incubation of thiol proteins with the HNO donor, Angeli's salt (AS; Na2N2O3). Only the disulfide, cystine, was formed in incubates of 15 mM free Cys with equimolar AS at pH 7.0-7.4. In contrast, the thiol proteins (120-180 microM), human calbindin D(28k) (HCalB), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and bovine serum albumin (BSA) gave four distinct types of derivatives in incubates containing 0.9-2.5 mM AS. Ions at M + n x 31 units were detected in the ESI mass spectra of intact HCalB (n = 1-5) and GAPDH (n = 2), indicating conversion of thiol groups on these proteins to RSONH2 (+31 units). An ion at M + 14 dominated the mass spectrum of BSA, and intramolecular sulfinamide cross-linking of Cys34 to one of its neighboring Lys or Arg residues would account for this mass increase. Low abundant M + 14 adducts were observed for HCalB, which additionally formed mixed disulfides when free Cys was present in the AS incubates. Cys149 and Cys153 formed an intramolecular disulfide in the AS/GAPDH incubates. Since AS also produces nitrite above pH 5 (HN2O3(-) --> HNO + NO2(-)), incubation with NaNO2 served to confirm that protein modification was HNO-mediated, and prior blocking with the thiol-specific reagent, N-ethylmaleimide, demonstrated that thiols are the targets of HNO. The results provide the first systematic characterization of HNO-mediated derivatization of protein thiols.     

Aminoethylation in model peptides reveals conditions for maximizing thiol specificity

Control of pH in aminoethylation reactions is critical for maintaining high selectivity towards cysteine modification. Measurement of aminoethylation rate constants by liquid chromatography mass spectrometry demonstrates reaction selectivity of cysteine>amino-terminus>histidine. Lysine and methionine were not reactive at the conditions used. For thiol modification, the acid/base property of the gamma-thialysine residue measured by NMR results in a 1.15 decrease in pK(a) (relative to a lysine residue). NMR confirms ethylene imine is the reactive intermediate for alkylation of peptide nucleophiles with bromoethylamine. Conversion of bromoethylamine into ethylene imine prior to exposure to the target thiol, provides a reagent that promotes selectivity by allowing precise control of reaction pH. Reaction selectivity plots of relative aminoethylation rates for cysteine, histidine, and N-terminus imine demonstrate increasing alkaline conditions favors thiol modification. When applied to protein modification, the conversion of bromoethylamine into ethylene imine and buffering at alkaline pH will allow optimal cysteine residue aminoethylation.     

The thermodynamics of thiol sulfenylation

Protein sulfenic acids are essential cysteine oxidations in cellular signaling pathways. The thermodynamics that drive protein sulfenylation are not entirely clear. Experimentally, sulfenic acid reduction potentials are hard to measure, because of their highly reactive nature. We designed a calculation method, the reduction potentials from electronic energies (REE) method, to give for the first time insight into the thermodynamic aspects of protein sulfenylation. The REE method is based on the correlation between reaction path-independent reaction energies and free energies of a series of analogous reactions. For human peroxiredoxin (Tpx-B), an antioxidant enzyme that forms a sulfenic acid on one of its active-site cysteines during reactive oxygen scavenging, we found that the reduction potential depends on the composition of the active site and on the protonation state of the cysteine. Interaction with polar residues directs the RSO(-)/RS(-) reduction to a lower potential than the RSOH/RSH reduction. A conserved arginine that thermodynamically favors the sulfenylation reaction might be a good candidate to favor the reaction kinetics. The REE method is not limited to thiol sulfenylation, but can be broadly applied to understand protein redox biology in general.     

The reaction of LipB, the octanoyl-[acyl carrier protein]:protein N-octanoyltransferase of lipoic acid synthesis, proceeds through an acyl-enzyme intermediate

The lipB gene of Escherichia coli encodes an enzyme (LipB) that transfers the octanoyl moiety of octanoyl-acyl carrier protein (octanoyl-ACP) to the lipoyl domains of the 2-oxo acid dehydrogenases and the H subunit of glycine cleavage enzyme. We report that the LipB reaction proceeds through an acyl-enzyme intermediate in which the octanoyl moiety forms a thioester bond with the thiol of residue C169. The intermediate was catalytically competent in that the octanoyl group of the purified octanoylated LipB was transferred either to an 87-residue lipoyl domain derived from E. coli pyruvate dehydrogenase or to ACP (in the reversal of the physiological reaction). The octanoylated LipB linkage was cleaved by thiol reagents and by neutral hydroxylamine, strongly suggesting a thioester bond. Separation and mass spectral analyses of the peptides of the unmodified and octanoylated proteins showed that each of the assigned peptides of the two proteins had identical masses, indicating that none of these peptides were octanoylated. However, the one major peptide that we failed to recover was that predicted to contain all three LipB cysteine residues. These three cysteine residues were therefore targeted for site-directed mutagenesis and only C169 was found to be essential for LipB function in vivo. The C169S protein had no detectable activity whereas the C169A protein retained trace activity. Surprisingly, both proteins lacking C169 formed an octanoyl-LipB species, although neither was catalytically competent. The octanoyl-LipB species formed by the C169S protein was resistant to neutral hydroxylamine treatment, consistent with formation of an ester linkage to the serine hydroxyl group. The octanoyl-C169A LipB species was probably acylated at C147. LipB species that lacked all three cysteine residues also formed a catalytically incompetent octanoyl adduct, indicating the presence of a reactive side chain other than a cysteine thiol that lies adjacent to the active site.     

The covalent binding of acetaminophen to protein. Evidence for cysteine residues as major sites of arylation in vitro

Covalent binding of the reactive metabolite of acetaminophen has been investigated in hepatic microsomal preparations from phenobarbital-pretreated mice. Low molecular weight thiols (cysteine and glutathione) were found to inhibit this binding, whereas several other amino acids which were tested did not. Bovine serum albumin (BSA), which contains a single free sulfhydryl group per molecule and which thus represents a macromolecular thiol compound, inhibited covalent binding of the reactive acetaminophen metabolite to microsomal protein in a concentration-dependent manner. The acetaminophen metabolite also became irreversibly bound to BSA in these experiments, although this binding was reduced by approx. 47% when the thiol function of BSA was selectively blocked prior to incubation. Covalent binding of the acetaminophen metabolite to bovine alpha s1-casein, a soluble protein which does not contain any cysteine residues, was found to occur to an extent of 37% of that which became bound to native BSA. These results were taken to indicate that protein thiol groups are major sites of covalent binding of the reactive metabolite of acetaminophen in vitro. The covalent binding characteristics of synthetic N-acetyl-p-benzoquinoneimine (NAPQI), the putative electrophilic intermediate produced during oxidative metabolism of acetaminophen, paralleled closely those of the reactive species generated metabolically. These findings support the contention that NAPQI is indeed the reactive arylating metabolite of acetaminophen which binds irreversibly to protein.     

Formation of cyclic imide-like structures upon the treatment of calmodulin and a calmodulin peptide with heat

Protein cyclic imide is the putative intermediate in the formation of sites of carboxyl-methylation in eukaryotic proteins. Conditions known to induce the formation of a cyclic imide in model peptides have been applied to a protein, calmodulin. Heating of calmodulin in the dry state at 100 degrees C for 24 h after lyophilization from a pH 2.0 or pH 6.0 solution produces derivatives with altered chromatographic properties in anion-exchange HPLC. At pH 6.0, complete activity of calmodulin was retained. Analysis with Fourier transform infrared (FTIR)-photoacoustic spectroscopy demonstrated the presence of a new structure in the calmodulin molecule consistent with modification of carboxylic acid groups. The conversion of calmodulin is dependent upon the absence of Ca2+ (the presence of 1 mM ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid). A peptide analogous to the calcium binding regions of calmodulin, Asp-Lys-Asp-Gly-Asn-Gly-Thr-Ile-Thr-Thr-Lys-Glu, is also converted, upon heating, to chromatographically different forms in reversed-phase chromatography. This process is also dependent upon the absence of calcium. Sequence analysis of the peptide derivatives reveals a second amino terminus, implicating peptide bond hydrolysis in the product. A dipeptide, Asp-Gly, known to form a cyclic imide structure under similar conditions is also hydrolyzed during sequence analysis consistent with cleavage occurring at the position of the cyclic imide structure. Asp3 is suggested to be the site of cyclic imide formation in the calmodulin peptide. The presence of a cyclic imide structure is also confirmed by the application of FTIR-photoacoustic spectroscopy. These data suggest that cyclic imide formation in calmodulin has been induced, possibly at one, or more, of the calcium binding loops of the protein. These modification reactions may provide a basis for future investigations of cyclic imide formation in proteins.     

Involvement of cysteine residues and domain interactions in the reversible unfolding of lipoxygenase-1

Urea-induced unfolding of lipoxygenase-1 (LOX1) at pH 7.0 was followed by enzyme activity, spectroscopic measurements, and limited proteolysis experiments. Complete unfolding of LOX1 in 9 M urea in the presence of thiol reducing or thiol modifying reagents was observed. The aggregation and oxidative reactions prevented the reversible unfolding of the molecule. The loss of enzyme activity was much earlier than the structural loss of the molecule during the course of unfolding, with the midpoint concentrations being 4.5 and 7.0 M for activity and spectroscopic measurements, respectively. The equilibrium unfolding transition could be adequately fitted to a three-state, two-step model (N left arrow over right arrow I left arrow over right arrow U) and the intermediate fraction was maximally populated at 6.3 M urea. The free energy change (DeltaG(H(2)O)) for the unfolding of native (N) to intermediate (I) was 14.2 +/- 0.28 kcal/mol and for the intermediate to the unfolded state (U) was 11.9 +/- 0.12 kcal/mol. The ANS binding measurements as a function of urea concentration indicated that the maximum binding of ANS was in 6.3 M urea due to the exposure of hydrophobic groups; this intermediate showed significant amount of tertiary structure and retained nearly 60% of secondary structure. The limited proteolysis measurements showed that the initiation of unfolding was from the C-terminal domain. Thus, the stable intermediate observed could be the C-terminal domain unfolded with exposed hydrophobic domain-domain interface. Limited proteolysis experiments during refolding process suggested that the intermediate refolded prior to completely unfolded LOX1. These results confirmed the role of cysteine residues and domain-domain interactions in the reversible unfolding of LOX1. This is the first report of the reversible unfolding of a very large monomeric, multi-domain protein, which also has a prosthetic group.     

Studying the S-nitrosylation of model peptides and eNOS protein by mass spectrometry.

Oxidative addition of a nitric oxide (NO) molecule to the thiol group of cysteine residues is a physiologically important post-translational modification that has been implicated in several metabolic and pathophysiological events. Our previous studies have indicated that S-nitrosylation can result in the disruption of the endothelial NO synthase (eNOS) dimer. It has been suggested that for S-nitrosylation to occur, the cysteine residue must be flanked by hydrophilic residues either in the primary structure or in the spatial proximity through appropriate conformation. However, this hypothesis has not been confirmed. Thus, the objective of this study was to determine if the nature of the amino acid residues that flank the cysteine in the primary structure has a significant effect on the rate and/or specificity of S-nitrosylation. To accomplish this, we utilized several model peptides based on the eNOS protein sequence. Some of these peptides contained point mutations to allow for different combinations of amino acid properties (acidic, basic, and hydrophobic) around the cysteine residue. To ensure that the results obtained were not dependent on the nitrosylation procedure, several common S-nitrosylation techniques were used and S-nitrosylation followed by mass spectrometric detection. Our data indicated that all peptides independent of the amino acids surrounding the cysteine residue underwent rapid S-nitrosylation. Thus, there does not appear to be a profound effect of the primary sequence of adjacent amino acid residues on the rate of cysteine S-nitrosylation at least at the peptide levels. Finally, our studies using recombinant human eNOS confirm that Cys98 undergoes S-nitrosylation. Thus, our data validate the importance of Cys98 in regulating eNOS dimerization and activity, and the utility of mass spectroscopy to identify cysteine residues susceptible to S-nitrosoylation.     

植物蛋白质S-亚硝基化修饰的检测与分析

S-亚硝基化是一种重要的蛋白质翻译后修饰方式, 是指一氧化氮(NO)基团共价连接至靶蛋白特定半胱氨酸残基的自由巯基, 从而形成S-亚硝基硫醇(SNO)的过程。S-亚硝基化修饰广泛存在于各有机体中, 通过改变蛋白质生化活性、稳定性、亚细胞定位以及蛋白质-蛋白质相互作用等机制而调控不同的生物学过程或信号通路。在蛋白质S-亚硝基化检测分析方法中, 最为广泛使用的是生物素转化法(biotin switch assay), 其基本原理是首先封闭未被修饰的自由巯基, 进而将被修饰的SNO基团特异地还原为自由巯基并使用生物素将其特异标记。被生物素标记的半胱氨酸残基(即被修饰位点)可进一步通过蛋白质免疫印迹和/或质谱等方法进行检测分析。该文详细描述了植物蛋白质样品的体内和体外生物素转化法的实验流程, 并对实验过程中的注意事项进行了讨论。     

植物蛋白质S-亚硝基化修饰的检测与分析

S-亚硝基化是一种重要的蛋白质翻译后修饰方式, 是指一氧化氮(NO)基团共价连接至靶蛋白特定半胱氨酸残基的自由巯基, 从而形成S-亚硝基硫醇(SNO)的过程。S-亚硝基化修饰广泛存在于各有机体中, 通过改变蛋白质生化活性、稳定性、亚细胞定位以及蛋白质-蛋白质相互作用等机制而调控不同的生物学过程或信号通路。在蛋白质S-亚硝基化检测分析方法中, 最为广泛使用的是生物素转化法(biotin switch assay), 其基本原理是首先封闭未被修饰的自由巯基, 进而将被修饰的SNO基团特异地还原为自由巯基并使用生物素将其特异标记。被生物素标记的半胱氨酸残基(即被修饰位点)可进一步通过蛋白质免疫印迹和/或质谱等方法进行检测分析。该文详细描述了植物蛋白质样品的体内和体外生物素转化法的实验流程, 并对实验过程中的注意事项进行了讨论。