Protein heteroconjugation by the peroxidase-catalyzed tyrosine coupling reaction

Combining different proteins can integrate the functions of each protein to produce novel protein conjugates with wider ranges of applications. We have previously introduced a peptide containing tyrosine residues (Y-tag) at the C-terminus of Escherichia coli alkaline phosphatase (BAP). The tyrosine residues in the Y-tag were efficiently recognized by horseradish peroxidase (HRP) and were site-specifically cross-linked with each other to yield BAP homoconjugates. In this study, the HRP-catalyzed tyrosine coupling reaction was used for protein heteroconjugation. Streptavidin (SA) was selected as the conjugation partner for BAP. The Y-tag (GGGGY) was genetically introduced to the C-terminus of SA. Prior to heteroconjugation, the reactivity of the Y-tagged SA was examined. The Y-tagged SA cross-linked to form an SA homoconjugate upon HRP treatment, whereas wild-type SA remained essentially intact. In the heteroconjugation reaction of BAP and SA, the Y-tagged BAP and SA were efficiently cross-linked with each other upon HRP treatment. The functions of the BAP-SA conjugates were evaluated by measuring the BAP enzymatic activity on a biotin-coated plate. The BAP-SA conjugate tethered to the plate showed BAP enzymatic activity, indicating that both BAP and SA retained their functions following heteroconjugation. The BAP-SA conjugate prepared from both Y-tagged BAP and SA showed the highest enzymatic activity on the biotin-coated plates. This result illustrates the advantage of the protein conjugation reaction in which multiple numbers of proteins can be conjugated at the same time.     

Control of a tyrosyl radical mediated protein cross-linking reaction by electrostatic interaction

Herein, we demonstrate the control of protein heteroconjugation via a tyrosyl coupling reaction by using electrostatic interaction. Aspartic acid and arginine were introduced to a tyrosine containing peptide tag (Y-tag) to provide electrostatic charge. Designed negatively or positively charged Y-tags were tethered to the C-terminus of Escherichia coli alkaline phosphatase (BAP) and streptavidin (SA), and these model proteins were subjected to horseradish peroxidase (HRP) treatment. The negatively charged Y-tags showed low reactivity due to repulsive interactions between the Y-tags with the negatively charged BAP and SA. In contrast, the positively charged Y-tags showed high reactivity, indicating that the electrostatic interaction between Y-tags and proteins significantly affects the tyrosyl radical mediated protein cross-linking. From the heteroconjugation reaction of BAP and SA, the SA with the positively charged Y-tags exhibited favorable cross-linking toward negatively charged BAP, and the BAP-SA conjugates prepared from BAP with GY-tag (GGGGY) and SA with RYR-tag (RRYRR) had the best performance on a biotin-coated microplate. Encompassing the reactive tyrosine residue with arginine residues reduced the reactivity against HRP, enabling the modulation of cross-linking reaction rates with BAP-GY. Thus, by introducing a proper electrostatic interaction to Y-tags, it is possible to kinetically control the heteroconjugation behavior of proteins, thereby maximizing the functions of protein heteroconjugates.     

Site-specific cross-linking of proteins through tyrosine hexahistidine tags

The genetic addition of hexahistidine (H(6)) tags is widely used to isolate recombinant proteins by immobilized metal-affinity chromatography (IMAC). Addition of a tyrosine residue to H(6) tags enabled proteins to be covalently cross-linked under mild conditions in a manner similar to the natural, site-specific cross-linking of tyrosines into dityrosine. A series of seven hexahistidine tags with tyrosines placed in various positions (H(6)Y tags) were added to the amino terminus of the I28 immunoglobulin domain of the human cardiac titin. The H(6)Y-tagged I28 dimerized in the presence of excess Ni(2+) with a K(D) of 200 microM. Treatment of Ni(2+)-dimerized H(6)Y-I28 with an oxidant, monoperoxyphthalic acid (MMPP) or sodium sulfite, resulted in covalent protein multimerization through chelated Ni(2+)-catalyzed cross-linking of the Y residues engineered into the H(6) tag. The protein oligomerization was observed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS PAGE). The presence of dityrosine in the cross-linked proteins was confirmed by fluorescence emission at 410 nm. Proteins lacking the Y residue in the H(6) tag treated with the same oxidative conditions did not cross-link or exhibit dityrosine fluorescence, despite the presence of an endogenous Y residue. The method may have potential uses in other protein conjugation applications such as protein labeling and interfacial immobilization of proteins on artificial surfaces.     

Oxidative modification of nucleoside diphosphate kinase and its identification by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Nucleoside diphosphate kinase (NDPK, Nm23) has been implicated as a multifunctional protein. However, the regulatory mechanism of NDPK is poorly understood. We have examined the modification of NDPK in oxidative stresses. We found that oxidative stresses including diamide and H(2)O(2) treatment cause disulfide cross-linking of NDPK inside cells. This cross-linking was reversible in response to mild oxidative stress, and irreversible to strong stress. This suggests that disulfide cross-linked NDPK may be a possible mechanism in the modification of cellular regulation. To confirm this idea, oxidative modification of NDPK has been performed in vitro using purified human NDPK H(2)O(2) inactivated the nucleoside diphosphate (NDP) kinase activity of NDPK by producing intermolecular disulfide bonds. Disulfide cross-linking of NDPK also dissociated the native hexameric structure into a dimeric form. The oxidation sites were identified by the analysis of tryptic peptides of oxidized NDPK, using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS). Intermolecular cross-linking between Cys109-Cys109, which is highly possible based on the X-ray crystal structure of NDPK-A, and oxidations of four methionine residues were identified in H(2)O(2)-treated NDPK. This cross-linkng was confirmed using mutant C109A (NDPK-A(C109A)) which had similar enzymatic activity as a wild NDPK-A. Mutant NDPK-A(C109A) was not cross-linked and was not easily denatured by the oxidant. Therefore, enzymatic activity and the quaternary structure of NDPK appear to be regulated by cross-linking with oxidant. These findings suggest one of the regulatory mechanisms of NDPK in various cellular processes.     

Novel inter-protein cross-link identified in the GGH-ecotin D137Y dimer

In the presence of a suitable oxidizing agent, the Ni(II) complex of glycyl-glycyl-histidine (GGH) mediates efficient and specific oxidative protein cross-linking. The fusion of GGH to the N terminus of a protein allows for the cross-linking reagent to be delivered in a site-specific fashion, making this system extremely useful for analyzing protein-protein contacts in complicated mixtures of biomolecules. Tyrosine residues have been postulated to be the primary amino acid target of this reaction, and using the dimeric serine protease inhibitor ecotin, we previously demonstrated that engineering a tyrosine at the protein interface of a dimer dramatically increased cross-linking efficiency. Cross-linking increased four-fold for GGH-ecotin D137Y in comparison to wild-type GGH-ecotin, presumably through bityrosine formation at the dimer interface. Here we report the first complete structural analysis of the cross-linked GGH-ecotin D137Y dimer. Using a combination of mass spectrometric and chemical derivatization methods, a sole novel cross-link between the N-terminal glycine residues and the engineered tyrosine at position 137 has been characterized. The dimer cross-link is localized to a single site without other protein modifications, but different reaction pathways produce structurally related products. We propose a mechanism that involves covalent bond formation between the protein backbone and a dopaquinone moiety derived from a specific tyrosine residue. This finding establishes that it is not necessary to have two tyrosine residues within close proximity in the protein interface to obtain high protein cross-linking yields, and suggests that the cross-linking reagent may be of more general utility than previously thought.     

Enzymatic preparation of streptavidin-immobilized hydrogel using a phenolated linear poly(ethylene glycol)

Hybrid gels constructed from proteins and polymers have attracted a wide range of attention in the field of biomedicine and bioengineering. We report herein the enzymatic preparation of polymer–protein hybrid hydrogels composed of terminally bis-functionalized linear poly(ethylene glycol) (PEG) and streptavidin (SA). PEG was conjugated with tyramine to introduce terminal phenolic hydroxyl (Ph-OH) groups. A peptide tag containing a tyrosine residue (G₄Y-tag) was genetically introduced at the C-terminus of SA. The Ph-OH-modified PEG and G₄Y-tagged SA (SA-G₄Y) were treated by horseradish peroxidase (HRP) in the presence of hydrogen peroxide (H₂O₂) to yield (PEG-Ph-OH)–(SA-G₄Y) hybrid gels. Biotinylated enhanced green fluorescent protein (biotin-EGFP) was selectively captured in the obtained hybrid gels, indicating that SA-G₄Y retained its biological function. The amount of biotin-EGFP immobilized in the hybrid gels depended on the concentration of SA-G₄Y. In addition, biotinylated bacterial alkaline phosphatase (biotin-BAP) was immobilized in the hybrid gel. The immobilized biotin-BAP exhibited more than 95% of the initial activity after 5 rounds of recycling. The results suggest the facile functionalization of the hybrid gel with a variety of biotinylated functional molecules.     

Copper mediates dityrosine cross-linking of Alzheimer's amyloid-beta

We have previously reported that amyloid Abeta, the major component of senile plaques in Alzheimer's disease (AD), binds Cu with high affinity via histidine and tyrosine residues [Atwood, C. S., et al. (1998) J. Biol. Chem. 273, 12817-12826; Atwood, C. S., et al. (2000) J. Neurochem. 75, 1219-1233] and produces H(2)O(2) by catalyzing the reduction of Cu(II) or Fe(III) [Huang, X., et al. (1999) Biochemistry 38, 7609-7616; Huang, X., et al. (1999) J. Biol. Chem. 274, 37111-37116]. Incubation with Cu induces the SDS-resistant oligomerization of Abeta [Atwood, C. S., et al. (2000) J. Neurochem. 75, 1219-1233], a feature characteristic of neurotoxic soluble Abeta extracted from the AD brain. Since residues coordinating Cu are most vulnerable to oxidation, we investigated whether modifications of these residues were responsible for Abeta cross-linking. SDS-resistant oligomerization of Abeta caused by incubation with Cu was found to induce a fluorescence signal characteristic of tyrosine cross-linking. Using ESI-MS and a dityrosine specific antibody, we confirmed that Cu(II) (at concentrations lower than that associated with amyloid plaques) induces the generation of dityrosine-cross-linked, SDS-resistant oligomers of human, but not rat, Abeta peptides. The addition of H2O2 strongly promoted Cu-induced dityrosine cross-linking of Abeta1-28, Abeta1-40, and Abeta1-42, suggesting that the oxidative coupling is initiated by interaction of H2O2 with a Cu(II) tyrosinate. The dityrosine modification is significant since it is highly resistant to proteolysis and is known to play a role in increasing structural strength. Given the elevated concentration of Cu in senile plaques, our results suggest that Cu interactions with Abeta could be responsible for causing the covalent cross-linking of Abeta in these structures.     

PHGPx and spermatogenesis

PHGPx of rat sperm mitochondrial capsule is cross-linked and inactive. The enzyme is in part released in an active form by mercaptoethanol. Treatment with H(2)O(2) of reduced and solubilised capsule proteins, in the absence of any added reductant, results in: i) H(2)O(2) consumption which depends on the presence of both, PHGPx activity and protein thiols; ii) protein thiol oxidation with a stoichiometry of 2 equivalents of thiol per mole of hydroperoxide and, iii) PHGPx inactivation and cross-linking. SDS-PAGE analysis of monobromobimane-labeled proteins, following incubation with H(2)O(2), shows that the oxidation takes place in specific bands in the area of 20~kDa. It is concluded that the protein thiol peroxidase activity of PHGPx is responsible for cross-linking proteins in the mammalian sperm capsule and accounts for the selenium dependency of spermatogenesis.     

Oxidative modification of cytochrome c by hydrogen peroxide

Oxidative alteration of mitochondrial cytochrome c has been linked to disease and is one of the causes of pro-apoptotic events. We have investigated the modification of cytochrome c by H2O2. When cytochrome c was incubated with H2O2, oligomerization of the protein increased and the formation of carbonyl derivatives and dityrosine was stimulated. Radical scavengers prevented these effects suggesting that free radicals are implicated in the H2O2-mediated oligomerization. Oligomerization was significantly inhibited by the iron chelator, deferoxamine. During incubation of deoxyribose with cytochrome c and H2O2, damage to the deoxyribose occurred in parallel with the release of iron from cytochrome c. When cytochrome c that had been exposed to H2O2 was analyzed by amino acid analysis, the tyrosine, histidine and methionine residues proved to be particularly sensitive. These results suggest that H2O2-mediated cytochrome c oligomerization is due to oxidative damage resulting from free radicals generated by a combination of the peroxidase activity of cytochrome c and the Fenton reaction of free iron released from the oxidatively-damaged protein.     

3-Bromotyrosine and 3,5-dibromotyrosine are major products of protein oxidation by eosinophil peroxidase: potential markers for eosinophil-dependent tissue injury in vivo

Detection of specific reaction products is a powerful approach for dissecting out pathways that mediate oxidative damage in vivo. Eosinophil peroxidase (EPO), an abundant protein secreted from activated eosinophils, has been implicated in promoting oxidative tissue injury in conditions such as asthma, allergic inflammatory disorders, cancer, and helminthic infections. This unique heme protein amplifies the oxidizing potential of H2O2 by utilizing plasma levels of Br- as a cosubstrate to form potent brominating agents. Brominated products might thus serve as powerful tools for identifying sites of eosinophil-mediated tissue injury in vivo; however, structural identification and characterization of specific brominated products formed during EPO-catalyzed oxidation have not yet been reported. Here we explore the role of EPO and myeloperoxidase (MPO), a related leukocyte protein, in promoting protein oxidative damage through bromination and demonstrate that protein tyrosine residues serve as endogenous traps of reactive brominating species forming stable ring-brominated adducts. Exposure of the amino acid L-tyrosine to EPO, H2O2, and physiological concentrations of halides (100 mM Cl-, 相似文献   

Role of hydrogen peroxide in sperm capacitation and acrosome reaction

The generation of reactive oxygen species (ROS) has been implicated in the regulation of sperm capacitation and acrosome reaction; however, the mechanisms underlying this regulation remain unclear. To examine the cellular processes involved, we studied the effect of different concentrations of hydrogen peroxide (H(2)O(2)) on protein tyrosine phosphorylation under various conditions. Treatment of spermatozoa with H(2)O(2) in medium without heparin caused a time- and dose-dependent increase in protein tyrosine phosphorylation of at least six proteins in which maximal effect was seen after 2 h of incubation with 50 microM H(2)O(2). At much higher concentrations of H(2)O(2) (0.5 mM), there is significant reduction in the phosphorylation level, and no protein tyrosine phosphorylation is observed at 5 mM H(2)O(2) after 4 h of incubation. Exogenous NADPH enhanced protein tyrosine phosphorylation similarly to H(2)O(2). These two agents, but not heparin, induced Ca(2+)-dependent tyrosine phosphorylation of an 80-kDa protein. Treatment with H(2)O(2) (50 microM) caused approximately a twofold increase in cAMP, which is comparable to the effect of bicarbonate, a known activator of soluble adenylyl cyclase in sperm. This report suggests that relatively low concentrations of H(2)O(2) are beneficial for sperm capacitation, but that too high a concentration inhibits this process. We also conclude that H(2)O(2) activates adenylyl cyclase to produce cAMP, leading to protein kinase A-dependent protein tyrosine phosphorylation.     

Oxidative protein cross-linking reactions involving L-tyrosine in transforming growth factor-beta1-stimulated fibroblasts

The mechanisms by which ligand-stimulated generation of reactive oxygen species in nonphagocytic cells mediate biologic effects are largely unknown. The profibrotic cytokine, transforming growth factor-beta1 (TGF-beta1), generates extracellular hydrogen peroxide (H2O2) in contrast to intracellular reactive oxygen species production by certain mitogenic growth factors in human lung fibroblasts. To determine whether tyrosine residues in fibroblast-derived extracellular matrix (ECM) proteins may be targets of H2O2-mediated dityrosine-dependent cross-linking reactions in response to TGF-beta1, we utilized fluorophore-labeled tyramide, a structurally related phenolic compound that forms dimers with tyrosine, as a probe to detect such reactions under dynamic cell culture conditions. With this approach, a distinct pattern of fluorescent labeling that seems to target ECM proteins preferentially was observed in TGF-beta1-treated cells but not in control cells. This reaction required the presence of a heme peroxidase and was inhibited by catalase or diphenyliodonium (a flavoenzyme inhibitor), similar to the effect on TGF-beta1-induced dityrosine formation. Exogenous addition of H2O2 to control cells that do not release extracellular H2O2 produced a similar fluorescent labeling reaction. These results support the concept that, in the presence of heme peroxidases in vivo, TGF-beta1-induced H2O2 production by fibroblasts may mediate oxidative dityrosine-dependent cross-linking of ECM protein(s). This effect may be important in the pathogenesis of human fibrotic diseases characterized by overexpression/activation of TGF-beta1.     

Pulcherosine, a novel tyrosine-derived, trivalent cross-linking amino acid from the fertilization envelope of sea urchin embryo

The normally hardened and aminotriazole-induced soft fertilization envelopes (FEs) of the sea urchin Hemicentrotus pulcherrimus and two other species were isolated and investigated for component proteins and cross-linking amino acids. From the acid hydrolysate of the hard FE of H. pulcherrimus, we isolated by reversed-phase high-performance liquid chromatography a novel fluorescent compound as well as dityrosine and trityrosine, the major tyrosine-derived cross-linking amino acids. These three compounds were also isolated from the reaction products of the tyrosine/horseradish peroxidase/H2O2 system. The structure of the novel compound, designated "pulcherosine", was determined to be 5-[4"-(2-carboxy-2-aminoethyl)phenoxy]-3,3'-dityrosine. With respect to the position of diphenyl ether bond between the tyrosine and dityrosine moieties, it is an isomer of isotrityrosine found in Ascaris cuticle collagen [Fujimoto et al. (1981) Biochem. Biophys. Res. Commun. 99, 637-643]. Isotrityrosine was not found in either of the above systems as a major component. The contents of tyrosine, dityrosine, trityrosine, and pulcherosine in the hard FE of H. pulcherrimus were estimated as 255, 5.5, 2.1, and 1.3 residues, respectively, per 10,000 total amino acid residues, while in the soft FE, those of tyrosine and dityrosine were 305 and 0.25 residues, respectively, and trityrosine and pulcherosine were only traces. The molar ratio of dityrosine, trityrosine, and pulcherosine in the hard FE was 100:38:24, while that for tyrosine/horseradish peroxidase/H2O2 reaction products was 100:3:8, respectively.     

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.     

The oxidation of cytochrome c peroxidase by hydrogen peroxide. Characterization of products.

H2O2 reacts with cytochrome c peroxidase in a variety of ways. The initial reaction produces cytochrome c peroxidase Compound I. If more than a 10-fold excess of H2O2 is added to the enzyme, a portion of the H2O2 will react with Compound I to produce molecular oxygen. The remainder oxidizes the heme group and various amino acid residues in the protein. If less than a 10-fold excess of H2O2 is added to the enzyme, essentially all the H2O2 is utilized by oxidation of amino acid residues in the protein. The oxidation of the amino acid residues by H2O2 substantially modifies the reactivity of cytochrome c peroxidase. The modification of reactivity could be the direct result of amino acid oxidation or an indirect result caused by a perturbation of the protein structure at the active site. The products oxidized at pH 8 lose their ability to react with H2O2. The products oxidized at pH4 react with H2O2 but their reactivity toward Fe(CN)4-6 is substantially reduced.     

Effects of interchain disulfide cross-links on the trypsin cleavage pattern and conformation of myosin subfragment 2

The ability of 5,5'-dithiobis(2-nitrobenzoate) (Nbs2) to produce interchain disulfide cross-links in both the long and short forms of myosin subfragment 2 (S2) and the conformational effects of these cross-links have been investigated. Short S2 (residues 3-287) contains two pairs of Cys residues at positions 66 and 108, and long S2 (residues 1-440) contains an additional pair at position 410. The reaction kinetics of each form of S2 with Nbs2 was biphasic. During the fast kinetic phase the reaction resulted in un-cross-linked species having Nbs-blocked Cys. During the slow phase disulfide-cross-linked species were formed via interchain S-Nbs/SH exchange. For short S2, Cys-66 appeared to react without forming disulfide cross-links, and the Cys- 108 pair reacted with partial cross-linking. For long S2, the Cys-66 pair appeared to react with partial cross-linking, and the Cys pairs at 108 and 410 reacted with complete cross-linking. Mild tryptic digestion of disulfide-cross-linked long S2, under conditions that resulted in partial production of short S2 from un-cross-linked LS2, produced peptides T1a and T1b (residues 1 to approximately 360), with one and two disulfide cross-links, respectively. Further digestion of cross-linked long S2 or cross-linked short S2 resulted in the same shorter fragment, T2, with an NH2-terminus beginning at 103 consistent with a sequence of residues 103-287. Circular dichroism studies on long S2 indicated that the presence of disulfide cross-links changed the thermal unfolding profile of the helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chorion peroxidase-mediated NADH/O(2) oxidoreduction cooperated by chorion malate dehydrogenase-catalyzed NADH production: a feasible pathway leading to H(2)O(2) formation during chorion hardening in Aedes aegypti mosquitoes

A specific chorion peroxidase is present in Aedes aegypti and this enzyme is responsible for catalyzing chorion protein cross-linking through dityrosine formation during chorion hardening. Peroxidase-mediated dityrosine cross-linking requires H(2)O(2), and this study discusses the possible involvement of the chorion peroxidase in H(2)O(2) formation by mediating NADH/O(2) oxidoreduction during chorion hardening in A. aegypti eggs. Our data show that mosquito chorion peroxidase is able to catalyze pH-dependent NADH oxidation, which is enhanced in the presence of Mn(2+). Molecular oxygen is the electron acceptor during peroxidase-catalyzed NADH oxidation, and reduction of O(2) leads to the production of H(2)O(2), demonstrated by the formation of dityrosine in a NADH/peroxidase reaction mixture following addition of tyrosine. An oxidoreductase capable of catalyzing malate/NAD(+) oxidoreduction is also present in the egg chorion of A. aegypti. The cooperative roles of chorion malate/NAD(+)oxidoreductase and chorion peroxidase on generating H(2)O(2) with NAD(+) and malate as initial substrates were demonstrated by the production of dityrosine after addition of tyrosine to a reaction mixture containing NAD(+) and malate in the presence of both malate dehydrogenase fractions and purified chorion peroxidase. Data suggest that chorion peroxidase-mediated NADH/O(2) oxidoreduction may contribute to the formation of the H(2)O(2) required for chorion protein cross-linking mediated by the same peroxidase, and that the chorion associated malate dehydrogenase may be responsible for the supply of NADH for the H(2)O(2) production.     

Assembly of nematode cuticle: role of hydrophobic interactions in CUT-2 cross-linking

CUT-2 is a component of cuticlin, the highly cross-linked, insoluble residue of the cuticle of the nematode Caenorhabditis elegans. A recombinant fragment of CUT-2, produced in E. coli, can be cross-linked in vitro by horse radish peroxidase via dityrosine formation to give large molecular species [1]. In this paper it is shown that the formation of CUT-2 polymers is greatly favoured over that of CUT-2 oligomers as no low molecular weight intermediates, dimers or trimers can be detected even when the cross-linking reaction is slowed or interrupted before completion. This suggests that recombinant CUT-2 forms large non-covalent complexes that are the only competent substrate for cross-linking. The inhibition of cross-linking by urea and the behavior of recombinant CUT-2 in size-exclusion chromatography under a variety of conditions suggest that hydrophobic interactions are important in the formation and stabilization of these complexes. The complexes are excellent substrates for cross-linking but react poorly with free tyrosine. In contrast, a soluble recombinant CUT-2 is a poor substrate for cross-linking but can efficiently react with free tyrosine.     

The myoglobin protein radical. Coupling of Tyr-103 to Tyr-151 in the H2O2-mediated cross-linking of sperm whale myoglobin

Sperm whale metmyoglobin, which has tyrosine residues at positions 103, 146, and 151, dimerizes in the presence of H2O2. Equine metmyoglobin, which lacks Tyr-151, and red kangaroo metmyoglobin, which lacks Tyr-103 and Tyr-151, do not dimerize in the presence of H2O2. The dityrosine content of the sperm whale myoglobin dimer shows that it is primarily held together by dityrosine cross-links, although more tyrosine residues are lost than are accounted for by dityrosine formation. Digestion of the myoglobin dimer with chymotrypsin yields a peptide with the fluorescence spectrum of dityrosine. The amino acid composition, amino acid sequence, and mass spectrum of the peptide show that cross-linking involves covalent bond formation between Tyr-103 of one myoglobin chain and Tyr-151 of the other. Replacement of the prosthetic group of sperm whale myoglobin with zinc protoporphyrin IX prevents H2O2-induced dimerization even when intact horse metmyoglobin is present in the incubation. This suggests that the tyrosine radicals required for the dimerization reaction are generated by intra- rather than intermolecular electron transfer to the ferryl heme. Rapid electron transfer from Tyr-103 to the ferryl heme followed by slower electron transfer from Tyr-151 to Tyr-103 is most consistent with the present results.     

Characteristics of chemiluminescence observed in the horseradish peroxidase-hydrogen peroxide-tyrosine system.

Electrolysis or horseradish peroxidase (HRP)-catalyzed oxidation of tyrosine and bityrosine in aqueous solution at pH 7.4 resulted in light emission in the visible region. Electrolysis of tyrosine emitted light which peaked at 490 nm and was almost completely quenched by superoxide dismutase (SOD), while emission by bityrosine peaked at 530 nm. In the HRP-H(2)O(2)-tyrosine system the oxidation-reduction of tyrosine emitted light with two prominent peaks, 490 and 530 nm, and was not quenched by SOD. The phenoxyl neutral radical of the tyrosine in HRP-H(2)O(2)-tyrosine system was detected by electron spin resonance (ESR) spectrometry using tert-nitrosobutane as a spin trap; the spin adduct was found to adhere to the HRP molecule during the enzymatic reaction. Further, bityrosine was detected in the HRP-H(2)O(2)-tyrosine reaction system. Changes in absorption spectra of HRP and chemiluminescence intensities during HRP-catalyzed oxidation of tyrosine suggest that for photon emission compound III is a candidate superoxide donor to the phenoxyl cation radical of tyrosine on the enzyme molecule. The luminescence observed in this study might be originated from at least two exciplexes involved with the tyrosine cation radical (Tyr(*+)) and the bityrosine cation radical (BT(*+))