Reactivity of peptidyl-tyrosine to hydroxylation and cross-linking

doi:10.1110/ps.44201

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Reactivity of peptidyl-tyrosine to hydroxylation and cross-linking

Luis A. Burzio¹ and J. Herbert Waite²

¹ Surgical Sealants, Inc., Woburn, Massachusetts 01801, USA
² Marine Sciences Institute, MCDB Department, University of California, Santa Barbara, California 93106, USA

Reprint requests to: Luis A. Burzio, Surgical Sealants, Inc., 150 New Boston Street, Woburn, MA 01801, USA; e-mail: burzio{at}surgicalsealants.com; fax: (781) 937-8180.

(RECEIVED October 18, 2000; FINAL REVISION January 4, 2001; ACCEPTED January 5, 2001)

Article and publication are at www.proteinscience.org/cgi/doi/10.1110/ps.44201.

Abstract

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Tyrosine residues of neuroendocrine peptides are frequentlythe targets of oxidation reactions, one of which involves hydroxylationto peptidyl-3, 4-dihydroxy-phenyl-L-alanine (DOPA). The reactivityin vitro of peptidyl-DOPA in two neuroendocrine peptides, aneurotensin fragment (pELYENK) and proctolin (RYLPT), was investigatedusing ultraviolet-visible scanning spectrophotometry and matrix-assistedlaser desorption ionization mass spectrometry following oxidationby tyrosinase and periodate. The peptides form covalently coupleddimers and trimers, and their masses are consistent with thepresence of diDOPA cross-links. Lysine does not appear to participatein multimer formation because it is efficiently recovered infragmentation ladders using subtilisin. While multimer formationin the neurotensin-derived peptide can be blocked effectivelyby adding N-acetyl-DOPA-ethylester to the reaction medium, theDOPA ethylester couples itself four to five times to each peptide.

Keywords: Neuroendocrine; tyrosine; DOPA peptides; cross-linking; tyrosinase

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Tyrosine residues play a commanding role in the structure-activityrelationships of many neuropeptides. ß-Opioid peptidessuch as endorphin, antidiuretics (oxytocin, vasopressin), proctolin,neurotensin, angiotensin, and dynorphin, for example, all containkey tyrosine residues that tolerate little modification withoutloss of activity (e.g., Schröder and Hempel 1965). Peptidyltyrosine is well-tailored to be a target of intermolecular recognition:hydrophobic, ionic (as the deprotonated phenolate), hydrogenbonding, ${pi}$ - ${pi}$ (Burley and Petsko 1985) and ${pi}$ -cation (Minoux and Chipot 1999)interactions all contrive to ensure many opportunitiesfor highly specific interaction with receptors (Hofstädter et al. 1999).Given its tendency for one- and two-electron oxidations,however, the presence of tyrosine also marks those peptidesand proteins bearing it with liability. Such oxidations canlead to loss of function through undesirable halogenation (Chowdhury et al. 1995),nitration (Busby and Gan 1975), hydroxylation(Gieseg et al. 1993; Cohen et al. 1998), and dityrosine formation(Souza et al. 2000; Michon et al. 1997).

We are interested here in exploring the reaction pathway ofpeptidyl tyrosine following its hydroxylation to peptidyl-3,4-dihydroxy-phenyl-L-alanine (DOPA) in two neuropeptide sequences:neurotensin (Vincent et al. 1999) and proctolin (Konopinska and Rosinski 1999).DOPA is a major by-product in several proteinsfollowing hydroxyl radical attack (Cohen et al. 1998) or prolongedirradiation by ultraviolet (UV) light (Kato et al. 1995). DOPAformation, per se, may or may not compromise function of theneuropeptide. In proctolin, for example, the DOPA analog hashigher activity than proctolin in certain target cell lines(Konopinska and Rosinski 1999). However, the facile oxidationof DOPA peptides leads to complications far beyond peptide function.Oxidation products of DOPA have been implicated in DNA damage(Spencer et al. 1994), excitotoxin formation (Newcomer et al. 1995),neuronal apoptosis (Walkinshaw and Waters 1995), andformation of pathoneuronal inclusions (Montine et al. 1995).Having said this, it must be added that the oxidation chemistryof DOPA is quite complicated, and often there has been morespeculation than fact about the specific oxidation productsinvolved. The most common naturally occurring DOPA-containingproteins are adhesives used by marine invertebrates (Waite 1990).In the course of maturation, these proteins become oxidized.Until recently, there has been some controversy regarding thechemical pathway of maturation (Rzepecki and Waite 1990). Muchof this was put to rest by the noninvasive, nondestructive detectionof diDOPA formation using solid-state nuclear magnetic resonance(McDowell et al. 1999). The present study attempts to determinewhether diDOPA formation is limited specifically to marine adhesiveproteins or has a broader relevance to oxidized tyrosine-containingproteins generally. Our results suggest the latter.

Results

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Tyrosine residues in model neuropeptides can be converted toDOPA residues in several ways including hydroxyl radical attack,UV irradiation and with enzymes. Tyrosinase-catalyzed DOPA formationwas chosen here because it is certainly the gentlest and mostspecific method. In vitro oxidation of the DOPA-analogs of neurotensinN6 and proctolin leads to rapid multimer formation as measuredby MALDI TOF (Matrix Assisted Laser Desorption/Ionization -Time of Flight) mass spectrometry (Fig. 1). Singly charged [M+H]⁺ species for the peptides are converted to dimeric and trimericforms, which lie 2–5 Da below the expected mass gain pernoncovalently coupled multimer, e.g., [2M+H] ⁺ (Table 1). Anotherpeak occurs at 18 Da lower than the multimer peak (Fig. 1A).UV-Vis scans taken during the course of the enzyme or periodate-inducedoxidation exhibit the standard attributes of quinones ( ${lambda}$ 305nm) and quinone-amine adducts (500 nm) (Fig. 2). The two peptidesdiffer notably by the 350 nm shoulder in tyrosinase-oxidizedDOPA-neurotensin N6 (Fig. 2A). This is reminiscent of dehydroDOPAderivatives, which form by tautomerization from quinone methides(Taylor et al. 1991; Rzepecki et al. 1991).

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Fig. 1. MALDI TOF of the DOPA analogs of neurotensin N6 (A) and proctolin (B) cross-linked with tyrosinase. The peptides were incubated at a 50:1 peptide to enzyme weight ratio in a 10-mM HEPES pH 7.5 with stirring at room temperature. These spectra correspond to a 30-min incubation period. Parenthetical numbers correspond to the mass loss as a result of cross-linking and oxidation of one or more DOPA functionalities in the multimers.

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Table 1. Chemical data for neurotensin N6 derivatives and oligomers

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Fig. 2. Ultraviolet (UV)-visible spectra of DOPA-neurotensin N6 incubated with tyrosinase (A) and periodate (B). In both cases, the peptide was incubated in a 10-mM HEPES pH 7.5 buffer at room temperature. Tyrosinase was added at a 50:1 peptide to enzyme ratio. The scans correspond to 0, 5, 15, 30, 60, and 120 min. Periodate was added at different molar ratios to the DOPA content. Scans correspond to 0:1, 1:1, 10:1, 20:1, 30:1, and 50:1 periodate:DOPA molar ratios.

The extreme sensitivity of multimer formation to the additionof simple DOPA analogs is revealed in Figure 3A and 3B

. Here,all evidence of dimers and trimers has been supplanted by themultiple (up to 5Xs) coupling of low-molecular-weight DOPA analogsto the peptide. Again, each step in the coupling ladder is markedby a 2-Da loss.

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Fig. 3. The tyrosinase-catalyzed oxidation of the DOPA analog of neurotensin N6 in the presence of N-acetyl DOPA amide (A) and N-acetyl DOPA ethylester (B). Reaction conditions are as in Figure 1

. Competitive inhibitors were added in a 10-molar excess to the peptide-DOPA content. Numbers indicate the mass lost with each addition of the DOPA analog.

Given the rapid and extensive conversion of oxidized DOPA-neurotensinN6 to dimeric and trimeric multimers, we attempted a purificationof the multimers with the aim of identifying the coupling sitein a multimer. Two peaks are separated by reverse-phase high-pressureliquid chromatography (HPLC) (Fig. 4A

); these show a limitedseparation of monomer and oxidized monomer (-2 Da) for the firstpeak, and dimers (-3 Da and -22 Da) as well as trimers in thesecond (Table 1

; Fig. 5

). The UV-Vis spectra for the oxidizedmonomer and dimer show significant differences. The monomershows a quinone absorbance at 305 nm and is pink (504 nm). Incontrast, the dimer/trimer is yellow (410 nm) with a shoulderat 364 nm (Fig. 6

). Better resolution of multimers is affordedby a slight reduction in the acetonitrile gradient (Fig. 4B

)resulting in fractions with homogeneous oligomers. A trimerwas used for sequencing with MALDI TOF (Fig. 7

). Upon digestionwith subtilisin, the trimer showed mass changes consistent withthe removal of K, N, and E from the C-terminus, and pyroglutamate(pE) from the N-terminus (Fig. 7

and Table 2

). There was noevidence of Leu or DOPA release.

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Fig. 4. HPLC of monomer and oligomer separation (A). HPLC of dimers and trimers (B). Columns and elution profiles (corresponding to the dashed line) are as described in Materials and Methods. Absorbance was measured at 280 nm. In A, P is pink peak and Y is yellow peak. In B, arrow indicates fraction corresponding to the sequenced trimer.

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Fig. 5. MALDI TOF spectrum of fractions from the fractions of the peaks from Figure 4A

. (A) and (B) correspond to fractions of the pink peak, (C) and (D) correspond to those of the yellow peak. Reaction conditions are as in Figure 1

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Fig. 6. Ultraviolet (UV)-Vis spectra of HPLC peaks from Figure 4A

. Unoxidized DOPA-neurotensin N6 (|) yellow (—) and pink (– –) peaks.

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Fig. 7. MALDI TOF sequencing of a trimer of oxidized DOPA-neurotensin N6. The trimer was incubated with a 10:1 peptide:subtilisin ratio (w/w) in a 10-mM HEPES pH7.5 buffer. The spectrum corresponds to a 30-min digest. Peak labels in parenthesis reflect the mass lost to digestion, and are explained further in Table 2

. Peaks labeled "S" correspond to subtilisin fragments.

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Table 2. Mass losses calculated and observed for the subtilisin degradation of a trimer of DOPA modified neurotensin N6

	Discussion

TOP Abstract Introduction Results Discussion Materials and methods References

The DOPA analogs of neurotensin and proctolin undergo covalentcoupling during oxidation by tyrosinase or periodate. This wasto be expected based on an earlier study of DOPA-containingadhesive protein-derived decapeptides (Burzio and Waite 2000);upon oxidation, decapeptides formed multimers as high as 8-mers,while neurotensin-N6 and proctolin are both limited to trimersand dimers. The bigger question has to do with how the peptidesare coupled. There are two common coupling paradigms: 1) amine-quinoneadducts (Michael-type additions) such as dopachrome (Nagatsu 1973)and lysyl-dopaquinone (Wang et al. 1996) with ${lambda}$ _max at $~$ 500nm, and 2) polyphenolic coupling products such as 5, 5'diDOPA(McDowell et al. 1999) with ${lambda}$ _max at $~$ 420 nm (Andersen et al. 1992)(Fig. 8

). Curiously, there is evidence for both forms in thepresent study: a 500 nm peak was detected in the oxidized neurotensinN6 (Fig. 3

) and in the oxidized purified monomer (Fig. 6

). Thiscannot be dopachrome because DOPA's ${alpha}$ -amino group is blockedin a peptide bond. Detection of the pink oxidized monomer isespecially intriguing because it might represent a stable intramolecularadduct of Lys-6 and the quinone at DOPA-3 such as that foundin lysyl oxidase (Wang et al 1996) (Fig. 8D

). Its structureneeds further characterization. Dimers (Fig. 8C

–F) andtrimers, on the other hand, absorb maximally at 420 and 334nm, but not at 500 nm. Accordingly, there is a decrease of 2Da per each ring-C to ring-C bond formed (Fig. 8

). Another 2Da would be lost for each coupled DOPA that is reoxidized too-Dopaquinone (Fig. 8D and F

) or DOPA-quinone methide. Moreover,the absorbance shoulder at 350 to 364 nm in neurotensin suggeststhat some dehydroDOPA (E) is formed from the quinone by tautomerization(Rzepecki et al. 1991). Reoxidation of this to quinone wouldentail the loss of an additional 2 Da. Subtilisin digestionof the trimer indicates that there are no hitches in peptidebond cleavage until the Leu-DOPA sequence is encountered. Thisblockage may be steric as a result of peptide coupling throughthe DOPA residues, or, in the case of dehydroDOPA formation,to the planar ${alpha}$ -C (enamide) of DOPA.

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Fig. 8. Proposed pathway of DOPA neurotensin N6 cross-linking. Step I is catalyzed by tyrosinase in the presence of O₂. Reoxidations at steps marked * may also involve the enzyme. The aryl coupling step at II requires one equivalent each of DOPA-N6 and quinone-N6, which dismutate to two DOPA-semiquinones. Specific ring positions coupled remain to be determined; they were 5, 5' in McDowell et al. 1999.

Neurotensin-N6 coupling through DOPA is the most reasonableexplanation for the present results, and diDOPA is a good candidatefor the cross-link. The fact that dimers and trimers of oxidizedneurotensin N6 were competitively inhibited by low-molecular-weightDOPA analogs adds weight to this. 5, 5'-DiDOPA was detectedin DOPA-containing adhesive proteins (McDowell et al. 1999)and in mussel adhesive decapeptides oxidized in vitro (Burzio and Waite 2000).Notably, one of the aromatic partners in theDOPA-derived cross-links of neurotensin-N6 would appear to bedehydroDOPA ( ${lambda}$ _max 364 nm); this was not observed in the decapeptides,but it was reported previously in oxidized N-acetylDOPA-ethylester (Rzepecki et al. 1991; Taylor et al. 1991) and in intactoxidized mefp-1 (Burzio 1999). In summary, these results areconsistent with aryl (diDOPA) coupling as the cause of multimerformation in neuropeptide-derived sequences. The specific detailsof substitution remain to be determined. DiDOPA coupling chemistryis likely to be much more common than previously thought; itcertainly is not limited to marine adhesive proteins.

Materials and methods

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Neurotensin fragment 1–6 (N6) [pELYENK] and proctolin[RYLPT] were purchased from Sigma Chemical Corp. (St. Louis,MO). Sodium meta-periodate and mushroom tyrosinase were bothfrom Sigma Chemical Corp. The latter had a specific activityof 3400 units/mg^-1. Subtilisin, a nonspecific endoprotease,was obtained from Roche Diagnostics (Indianapolis, IN), andwas used to sequence peptide oligomers by MALDI-MS. Human angiotensinand a fragment of ACTH (18–39), used as calibration standardsfor MALDI TOF MS, were obtained from Sigma Chemical Corp.

Peptide hydroxylation
The hydroxylation of the Tyr residues of the peptides was doneaccording to published procedure (Marumo and Waite 1986). Briefly,the peptides were dissolved in 4 mL of 100 mM phosphate pH 7.5with 25 mM ascorbic acid at room temperature with constant stirringand aeration. Tyrosinase (for the monophenolase activity, aunit is defined as a change in absorbance of 0.001 min-1 mL-1at 280 nm with L-tyrosine as the substrate) was added and thereaction was allowed to proceed for 60 min. The reaction wasterminated by adding 25 µL 6 N HCl/mL.

The differentially hydroxylated peptides were separated by reverse-phaseHPLC on a C-8 column (Brownlee RP-300) using the following gradientmade by mixing 0.1% (v/v) trifluoroacetic acid (TFA) in waterwith 0.1% (v/v) TFA in acetonitrile (B): 0 to 15% in 45 min,to 100% at 46 min. 1-mL fractions were collected, lyophilized,and reconstituted in water. The extent of hydroxylation wasdetermined by MALDI TOF.

Peptide oxidation
Mushroom tyrosinase also was used as an oxidant (SA = 3400 units/mgwhere each unit equals a difference in absorbance at 265 nmof 0.001 min-1 mL-1 at pH 6.5 at 25°C in a reaction mixturecontaining either L-DOPA or catechol and ascorbate). The oxidationreaction was carried out on hydroxylated peptides in the absenceof ascorbate by adding 0.5 mg enzyme/mL at a 50:1 peptide:enzymeweight ratio in 10 mM HEPES pH 7.5 with stirring at room temperature.

Oxidation with periodate was carried out in the same incubationconditions. Periodate addition was done at different molar ratiosto the DOPA present.

Separation of monomer from oligomers
The N16-D peptide was cross-linked as described in the previoussection. To separate the dimer and trimer from any monomer thepolymerized peptide mix was run on a Brownlee Aquapore analyticalC-4 HPLC column (40 mm x 250 mm) (Rainin Medical Instruments,Woburn, MA). Two different gradients were employed: one to separatethe oligomers from the monomers (0%–10%B in 5 min, 10%–20%Bin 10 min, and a wash at 100% for 5 min) and another for separatingthe dimers and trimers (0%–16%B in 5 min, 16%–21%Bin 50 min, and a wash at 100%B for 10 min).

Product characterization
UV-Vis absorbance was measured on a Hewlett-Packard diode arrayspectrophotometer (HP Model 8453) equipped with interface 35900Eand ChemStation software.

Matrix-assisted laser desorption ionization mass spectrometrywith time-of-flight analysis (MALDI TOF) was done using a PEBiosystems Voyager DE instrument with delayed extraction. Matrix( ${alpha}$ -cyano-3-hydroxycinnamic acid) was prepared as a saturatedsolution in 1:1 (v/v) water and acetonitrile with 0.1% TFA.All samples were run in linear mode with 20 kV acceleratingvoltage, 18.96 kV grid voltage, and 2 V guide wire voltage.Typical relative laser power was 1800. Neurotensin fragment1–6 (MW 776.8), human angiotensin (MW 1297.5) and ACTHfragment 18–39 (MW 2465.7) were used as internal and externalcalibrants.

Subtilisin digestion
Subtilisin digestion was done on purified dimers and trimersof cross-linked DOPA-N6. The peptides were incubated with theenzyme at a weight ratio of 1:10 (enzyme:peptide) in a 10-mMHEPES pH 7.5 buffer. Aliquots were taken at different times,mixed with MALDI matrix, and deposited on the MALDI sample plate.The samples then were analyzed by MALDI TOF. Cleaved amino acidswere identified by the mass differences when compared to theoriginal mass of the oligomer.

Acknowledgments

We thank Dr. G. Nicol for his mass spectrometry assistance anddiscussions. Dr. L. Rzepecki synthesized and generously donatedthe DOPA analogs. This work was funded by the Office of NavalResearch and the Biomaterials Program at National Institutesof Dental Craniofacial Research (NIDCFR).

The publication costs of this article were defrayed in partby payment of page charges. This article must therefore be herebymarked "advertisement" in accordance with 18 USC section 1734solely to indicate this fact.

References

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Burley, S.K. and Petsko, G.A. 1985. Aromatic-aromatic interaction: A mechanism of protein structure stabilization. Science 229: 23–28.[Abstract/Free Full Text]

Burzio, L.A. 1999. Formation of DOPA derived cross-links in mussel byssal proteins and peptides. Ph.D. Thesis. University of Delaware, Newark, DE.

Burzio, L.A. and Waite, J.H. 2000. Cross-linking in adhesive quinoproteins: Studies with model decapeptides. Biochemistry 39: 11147–11153.[CrossRef][Medline]

Busby, T.F. and Gan, J.C. 1975. Reaction of tetranitromethane with human plasma ${alpha}$ ₁-antitrypsin. Int J Biochem 6: 835–841.[CrossRef]

Chowdhury, S.K., Eshraghi, J., Wolfe, H., Forde, D., Hlavac, A.G., and Johnston, D. 1995. Mass spectrographic identification of amino acid transformations during oxidation of peptides and proteins: Modifications of methionine and tyrosine. Anal Chem 34: 390–398.[CrossRef]

Cohen, G., Yakushin, S., and Dembiec-Cohen, D. 1998. Protein Dopa as an index of hydroxyl radical attack on protein tyrosine. Anal Biochem 263: 232–239.[CrossRef][Medline]

Gieseg, S.P., Simpson, J.A., Charlton, T.S., Duncan, M.W., and Dean, R.T. 1993. Protein bound DOPA is a major reductant formed during hydroxyl damage to proteins. Biochemistry 32: 4780–4786.[CrossRef][Medline]

Hofstädter, K., Stuart, F., Jiang, L., Vrijbloed, J.W., and Robinson, J.A. 1999. On the importance of being aromatic at an antibody-protein antigen interface. J Mol Biol 285: 805–815.[CrossRef][Medline]

Kato, Y., Nishikawa, T., and Kawakishi, S. 1995. Formation of protein-bound 3, 4-dihydroxyphenylalanine in collagen types I and IV exposed to UV light. Photochem Photobiol 61: 367–372.[Medline]

Konopinska, D. and Rosinski, G. 1999. Proctolin, an insect neuropeptide. J Peptide Sci 5: 533–546.[CrossRef][Medline]

Marumo, K. and Waite, J.H. 1986. Optimization of hydroxylation of tyrosine and tyrosine-containing peptides by mushroom tyrosinase. Biochem Biophys Acta 872: 98–103[CrossRef][Medline]

McDowell, L.M., Burzio, L.A., Waite, J.H., and Schaefer, J. 1999. Rotational echo double resonance detection of cross-links formed in mussel byssus under high-flow stress. J Biol Chem 274: 20293–20295.[Abstract/Free Full Text]

Michon, T., Chenu, M., Kellershon, N., Desmadril, M., and Gueguen, J. 1997. Horseradish peroxidase oxidation of tyrosine-containing peptides and their subsequent polymerization: A kinetic study. Biochemistry 36: 8504–8513.[CrossRef][Medline]

Minoux, H. and Chipot, C. 1999. Cation- ${pi}$ interactions in proteins: Can simple models provide an accurate description. J Am Chem Soc 121: 10366–10372.[CrossRef]

Montine, T.J., Farris, D.B., and Graham, D.G. 1995. Covalent cross-linking of neurofilament proteins by oxidized catechols as a potential mechanism of Lewy body formation. J Neuropath Exp Neurol 54: 311–319.[Medline]

Nagatsu, T. 1973. Biochemistry of Catecholamines. University Park Press, Baltimore, MD.

Newcomer, T.A., Rosenberg, P.A., and Aizenman, E. 1995, Iron-mediated oxidation of DOPA to an excitotoxin. J Neurol 64:1742–1748.

Rzepecki, L.M. and Waite, J.H. 1991. DOPA proteins: Versatile varnishes and adhesives from marine fauna. Bioorgan Mar Chem 4: 119–148.

Rzepecki, L.M., Nagafuchi, T., and Waite, J.H. 1991. ${alpha}$ , ß-Dehydro-3, 4-dihydroxyphenylalanine derivatives: Potential sclerotization intermendiates in natural composite materials. Arch. Biochem Biophys 285: 17–26.[CrossRef][Medline]

Schröder, E. and Hempel, R. 1965. Über Peptidylsynthesen. Über Angiotensin-Analoga. Justus Liebigs Ann Chem 684: 243–251.[Medline]

Smith, G.J. and Haskell, T.G. 2000. The fluorescent oxidation productions of dihydroxyphenylalanine and its esters. J Photochem Photobiol B Biol 55: 103–108.[CrossRef][Medline]

Spencer, J.P.E., Jenner, A., Aruoma, O.I., Evans, P.J., Kaur, H., Dexter, D.T., Jenner, P., Lees, A.J., Marsden, D.C., and Halliwell, B. 1994. Intense oxidative DNA damage promoted by L-DOPA and its metabolites: Implications for neuro-degenerative disease. FEBS Lett 353: 246–250.[CrossRef][Medline]

Souza, J.M., Giasson, B.I., Chen, Q., Lee, V.M.Y., and Ischiropoulos, H. 2000. Dityrosine cross-linking promotes formation of stable ${alpha}$ -synuclein polymers. J Biol Chem 275: 18344–18349.[Abstract/Free Full Text]

Taylor, S.W., Molinski, T.F., Rzepecki, L.M., and Waite, J.H.. 1991. Oxidation of peptidyl-DOPA analogues: Implications for the synthesis of tunichromes and related oligopeptides. J Nat Prod 54: 918–922.[CrossRef][Medline]

Vincent, J.P., Mazella, J., and Kiabgi, P. 1999. Neurotensin and neurotensin receptors. TiPS 20: 302–309.

Waite, J.H. 1990. The phylogeny and chemical diversity of quinone-tanning: A review. Comp Biochem Physiol 97B: 19–29.[CrossRef]

Walkinshaw, G. and Waters, C.M. 1995. Induction of apoptosis in catecholaminergic PC12 cells by L-Dopa. J Clin Invest 95: 2458–2464.

Wang, S.X., Mure, M., Medzihradsky, K.F., Burlingame, A.L., Brown, D.E., Dooley, D. M., Smith, A.J., Kagan, H.K., and Klinman J.P. 1996. A cross-linked cofactor in lysyl oxidase: redox function for amino acid side chains. Science 273: 1078–1084.[Abstract]

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