Limited tryptic proteolysis of pig kidney 3,4-dihydroxyphenylalanine decarboxylase

Pig kidney 3,4-dihydroxyphenylalanine (Dopa) decarboxylase can be nicked by trypsin with complete loss of its catalytic activity. The original dimer of subunit molecular weight of about 52,000 yields fragments of Mr 38,000 and 14,000, as seen on sodium dodecyl sulfate-gel electrophoresis. Though inactive, the nicked protein retains its native molecular weight and its capacity to bind pyridoxal-5'-phosphate (pyridoxal-P), is recognized by an antiserum raised against the native enzyme, and forms Schiff's base intermediates with aromatic amino acids in L and D forms. Thus, the nicked protein appears to be in a conformation--closely resembling that of the original enzyme--which consists of a tight association of the two tryptic fragments. Dissociation and separation of the two fragments can be achieved under denaturing conditions on a reverse-phase HPLC column. The pyridoxal-P binding site is located on the larger fragment. No NH2-terminal residue is detected in either the intact enzyme or the larger fragment, whereas analysis of the smaller fragment yields a sequence of the first 50 amino acid residues. These data indicate that the smaller fragment is located at about one-third from the COOH terminus of Dopa decarboxylase, while the larger fragment constitutes the aminic portion of the molecule. The site of trypsin cleavage seems to be in a region of the enzyme particularly susceptible to proteolysis. The results of these studies contribute to a better understanding of the structural properties of pig kidney Dopa decarboxylase and may constitute an important step toward the elucidation of the enzyme's primary structure.     

Chemical modification of pig kidney 3,4-dihydroxyphenylalanine decarboxylase with diethyl pyrocarbonate. Evidence for an essential histidyl residue

Diethyl pyrocarbonate inhibits pig kidney holo-3,4-dihydroxyphenylalanine decarboxylase with a second-order rate constant of 1170 M-1 min-1 at pH 6.8 and 25 degrees C, showing a concomitant increase in absorbance at 242 nm due to formation of carbethoxyhistidyl derivatives. Activity can be restored by hydroxylamine, and the pH curve of inactivation indicates the involvement of a residue with a pKa of 6.03. Complete inactivation of 3,4-dihydroxyphenylalanine decarboxylase requires the modification of 6 histidine residues/mol of enzyme. Statistical analysis of the residual enzyme activity and of the extent of modification shows that, among 6 modifiable residues, only one is critical for activity. Protection exerted by substrate analogues, which bind to the active site of the enzyme, suggests that the modification occurs at or near the active site. The modified inactivated 3,4-dihydroxyphenylalanine decarboxylase still retains most of its ability to bind substrates. Thus, it may be suggested that the inactivation of enzyme by diethyl pyrocarbonate is not due to nonspecific steric or conformational changes which prevent substrate binding. However, the modified enzyme fails to produce at high pH either an enzyme-substrate complex or an enzyme-product complex absorbing at 390 nm. Considerations on this peculiar feature of the modified enzyme consistent with a catalytic role for the modified histidyl residue are discussed. The overall conclusion of this study may be that the modification of only one histidyl residue of 3,4-dihydroxyphenylalanine decarboxylase inactivates the enzyme and that this residue plays an essential role in the mechanism of action of the enzyme.     

An essential arginine residue at the binding site of pig kidney 3,4-dihydroxyphenylalanine decarboxylase

Pig kidney 3,4-dihydroxyphenylalanine (Dopa) decarboxylase is inactivated by the arginine-specific reagent phenylglyoxal. Under these experimental conditions, the reaction follows pseudo-first-order kinetics with a second-order rate constant of 25 m-1 min-1. Holo- and apo-enzyme were inactivated at the same rate. However, inactivation seems to be related to modification of 1 and 2 arginyl residues per mol of holo- and apo-enzyme, respectively. Only one of these two residues was essential to decarboxylase activity of the enzyme. Phenylglyoxal-modified apo-Dopa decarboxylase retained the capacity to bind pyridoxal-P. Neither this reconstituted species nor the phenylglyoxal-modified holoenzyme were able to form Schiff base intermediates with aromatic amino acids in L and D forms. These data together with protection experiments suggest that the susceptible arginine residue in holoenzyme may somehow perturb the substrate binding site. However, unlike in other pyridoxal-P enzymes, this critical arginine in Dopa decarboxylase does not seem to behave as an anionic recognition site for the phosphate group of the coenzyme or the carboxy group of the substrate. It is speculated that this guanidyl group could function in hydrogen bonding of substrate side chain.     

Stereospecificity of sodium borohydride reduction of pig kidney dopa decarboxylase

Sodium boro[3H]hydride reduction of pig kidney 3,4 dihydroxyphenylalanine decarboxylase followed by complete hydrolysis of the enzyme produced epsilon-[3H]pyridoxyllysine. Degradation of this material to 4'-[3H]pyridoxamine and stereochemical analysis with apoaspartate aminotransferase showed that the re side at C-4' of the coenzyme is exposed to solvent. In order to determine the face exposed to the solvent in the external Schiff's base, attempts to trap reaction intermediates were made by reduction with sodium boro [3H]hydride of the holoenzyme in the presence of various substrates or substrate analogs. In all cases, covalently bound radioactive material was found which was identified as epsilon-N-pyridoxyllysine. These results suggest that the internal Schiff's base is in mobile equilibrium with the external Schiff's base and that sodium borohydride reduction displaces this equilibrium, resulting in complete reduction of the internal Schiff's base.     

Reactions of DOPA (3,4-dihydroxyphenylalanine) decarboxylase with DOPA.

The study of DOPA (3,4-dihydroxyphenylalanine) decarboxylase by steady-state methods is difficult because multiple reactions occur. The reaction with DOPA was studied at enzyme concentrations between 20 and 50 micrometer by direct observation of the bound coenzyme by using stopped-flow and conventional spectrophotometry. Four processes were observed on different time scales and three of these were attributed to stages in the decarboxylation. The fourth was attributed to an accompanying transamination that renders the enzyme inactive. It was clear that much, if not all, of the 330 nm-absorbing coenzyme present in the free enzyme plays an active part in the decarboxylation, since it is converted into 420 nm-absorbing material in the first observable step. An intermediate absorbing maximally at 390 nm is formed in a slower step. Rate and equilibrium constants have been determined and the ratio of decarboxylation to transamination was estimated to be 1200:1.     

Affinity labeling of pig kidney 3,4-dihydroxyphenylalanine (Dopa) decarboxylase with N-(bromoacetyl)pyridoxamine 5'-phosphate. Modification of an active-site cysteine

Pig kidney 3,4-dihydroxyphenylalanine (Dopa) decarboxylase is inactivated by N-(bromoacetyl)pyridoxamine 5'-phosphate (BAPMP) in a reaction which follows first-order kinetics at pH 7.5 and 25 degrees C. The concentration dependence of inactivation reveals saturation kinetics with an apparent Ki of 0.16 mM and kinact of 0.086 min-1 at saturating inhibitor concentration. Enzyme can be protected from inactivation by pyridoxal 5'-phosphate. Inactivation of enzyme by [14C]BAPMP proceeds with the incorporation of a stoichiometric amount of labeled inhibitor. Proteolytic digestions of the radioactively labeled enzyme followed by high-performance liquid chromatography allow the isolation of the modified peptide corresponding to the sequence Ala-Ala-Ser-Pro-Ala-Cys-Thr-Glu-Leu in which cysteine (Cys111) is the modified residue. The conservation of this residue and also of an extended region around it in all Dopa decarboxylases so far sequenced is underlined. The overall conclusion of these findings is that Cys111 may be at, or near, the pyridoxal-5'-phosphate binding site of pig kidney Dopa decarboxylase and plays a critical role in the catalytic function of the enzyme. Furthermore, fluorescence studies of BAPMP-modified apoenzyme provide useful information on the microenvironment of the affinity label at its binding site.     

3,4-Dihydroxyphenylalanine (dopa) decarboxylase activity in the arthropod nervous system

1. When homogenates of brains from mature adult locusts (Locusta migratoria) were incubated with l-3-(3,4-dihydroxyphenyl)[3-(14)C]alanine the major radioactive metabolite was dopamine, suggesting the presence of a dopa (3,4-dihydroxyphenylalanine) decarboxylase. 2. Decarboxylation of l-dopa by this tissue, measured under optimum conditions by a radiochemical method, was 21mumol of CO(2)/h per g wet wt. Apparent decarboxylation of l-tyrosine proceeded at 0.34mumol of CO(2)/h per g wet wt. There was no detectable decarboxylation of l-tryptophan, l-histidine or l-phenylalanine. 3. Dopa decarboxylase activity was found in all major regions of the ventral nerve cord of the mature locust (range: 4-7mumol of CO(2)/h per g wet wt.) but was low or absent in thoracic peripheral nerve. 4. Marked decarboxylation of l-dopa was found in homogenates of brains of four other species of insects, and in brain and ventral nerve cord, but not in the claw nerve, of the crayfish. 5. The activity of the locust brain enzyme may be slightly lower at the time of imaginal ecdysis than during the mature period. By contrast, the dopa decarboxylase that produces dopamine as an intermediate in cuticle biosynthesis is known to be high in activity at the time of ecdysis and low in activity during the intermoult stages.     

Purification and characterization of 3,4-dihydroxyphenylalanine decarboxyase from pig kidney.

A procedure for 3,4-dihydroxyphenylalanine decarboxylase from pig kkdney purification is described in detail. The preparation has no detectable impurity on electrophoresis and on ultracentrifugation and authors. However two significant differences are observed: a different stimulation of activity by added pyridoxal 5'-phosphate and a nearly complete decarboxylation of L-3,4-dihydroxyphenylalanine in absence of added coenzyme. Absorption, fluorescence and circular dichroism properties of the coenzyme-apoenzyme interaction are also described. The results are consistent with the existence of at least four coenzyme-apoenzyme complexes, three of them active.     

The interaction of 2,3,4-trihydroxybenzylhydrazine with dopa decarboxylase from pig kidney

The spectral modifications induced by addition of 2,3,4,-trihydroxybenzylhydrazine (Ro 4-5127) to Dopa decarboxylase indicate the binding of this compound to the coenzyme binding site and allow the titration of the enzyme: 1.07 moles of Ro 4-5127 bind 1 mole of enzyme. Inhibition data indicate that Ro 4-5127 behaves as a pseudoirreversible inhibitor of Dopa decarboxylase and that 100% inhibition is not reached at a 1:1 inhibitor/ enzyme molar ratio, as expected from spectral data, but at a molar ratio of about 6. On this basis it would be possible to suggest, beside the coenzyme binding site, the existence on the enzyme molecule of other sites where the compound could bind without affecting its spectral feature. The interaction of Ro 4-5127 with Dopa decarboxylase shows that “in vivo” Ro 4-5127 behaves as a more powerful inhibitor of Dopa decarboxylase than its precursor trihydroxybenzylhydrazine seryl derivative (Ro 4-4602) indicating that the strong “in vivo” inhibition exerted by Ro 4-4602 might reflect the effective interaction of Dopa decarboxylase with Ro 4-5127.     

Phosphonic analogues of tyrosine and 3,4-dihydroxyphenylalanine (dopa) influence mushroom tyrosinase activity.

A series of phosphonic analogues of tyrosine and 3,4-dihydroxyphenylalanine (dopa) were synthesized in order to study their interaction with mushroom tyrosinase. 1-Amino-2-(3,4-dihydroxyphenyl)ethylphosphonic acid and 1-amino-2-(3,4-dimethoxyphenyl)ethylphosphonic acid turned out to be substrates for mushroom tyrosinase with Km values of 3.3 mM and 9.3 mM respectively. Shortening of the alkyl chain by one methylene group gave amino-(3,4-dihydroxyphenyl)methylphosphonic acid, one of the most powerful known inhibitors of this enzyme. This compound, racemic as well as in its optically active forms, exerts a mixed type of inhibition with an affinity for the enzyme one order of magnitude greater than that of the natural substrate.     

Induction of dopa (3,4-dihydroxyphenylalanine) decarboxylase in blowfly integument by ecdysone. A demonstration of synthesis of the enzyme de novo.

The activity of the enzyme dopa (3,4-dihydroxyphenylalanine) decarboxylase, present in the epidermis cells of blowfly larvae, increases during the late third instar under the influence of the steroid hormone, ecdysone. By using the double-labelling technique and immune precipitation with univalent antibody to dopa decarboxylase, we demonstrated that the increase in enzyme activity was due to a stimulation of synthesis of enzyme molecules de novo. In this respect, the action of ecdysone is similar to the action of other steroid hormones.     

Purification and characterization of rat-liver 3,4-dihydroxyphenylalanine decarboxylase

A simple and rapid procedure, which takes advantage of the effectiveness of conventional and HPLC hydrophobic interaction, for the isolation of highly purified rat liver 3,4-dihydroxyphenylalanine decarboxylase is described in detail. Some of its structural and functional properties are reported and discussed in comparison with those of pig kidney 3,4-dihydroxyphenylalanine decarboxylase.     

Reaction specificity of native and nicked 3,4-dihydroxyphenylalanine decarboxylase

3,4-Dihydroxyphenylalanine (Dopa) decarboxylase is a stereospecific pyridoxal 5'-phosphate (PLP)-dependent alpha-decarboxylase that converts L-aromatic amino acids into their corresponding amines. We now report that reaction of the enzyme with D-5-hydroxytryptophan or D-Dopa results in a time-dependent inactivation and conversion of the PLP coenzyme to pyridoxamine 5'-phosphate and PLP-D-amino acid Pictet-Spengler adducts, which have been identified by high performance liquid chromatography. We also show that the reaction specificity of Dopa decarboxylase toward aromatic amines depends on the experimental conditions. Whereas oxidative deamination occurs under aerobic conditions (Bertoldi, M., Moore, P. S., Maras, B., Dominici, P., and Borri Voltattorni, C. (1996) J. Biol. Chem. 271, 23954-23959; Bertoldi, M., Dominici, P., Moore, P. S., Maras, B., and Borri Voltattorni, C. (1998) Biochemistry 37, 6552-6561), half-transamination and Pictet-Spengler reactions take place under anaerobic conditions. Moreover, we examined the reaction specificity of nicked Dopa decarboxylase, obtained by selective tryptic cleavage of the native enzyme between Lys334 and His335. Although this enzymatic species does not exhibit either decarboxylase or oxidative deamination activities, it retains a large percentage of the native transaminase activity toward D-aromatic amino acids and displays a slow transaminase activity toward aromatic amines. These transamination reactions occur concomitantly with the formation of cyclic coenzyme-substrate adducts. Together with additional data, we thus suggest that native Dopa decarboxylase can exist as an equilibrium among "open," "half-open," and "closed" forms.     

A pulse radiolysis investigation of the oxidation of the melanin precursors 3,4-dihydroxyphenylalanine (dopa) and the cysteinyldopas

The unstable quinones of 3,4-dihydroxyphenylalanine (dopa) and the most abundant cysteinyldopa isomers (2S-, 5S- and 2,5S,S'-) have been generated rapidly via disproportionation of their respective semiquinones prepared pulse radiolytically by one-electron oxidation of the corresponding dopas with azide radicals. Dopaquinone decays via a base-catalysed unimolecular cyclisation yielding leucodopachrome which, under the present conditions, is immediately oxidised by remaining dopaquinone to form dopachrome and dopa back again. Addition of cysteine increased the rate of dopaquinone decay and precluded dopachrome formation. By contrast, the cysteinyldopa quinones decayed via an acid-catalysed unimolecular cyclisation involving the cysteine side chain to form a cyclic quinone-imine observed directly for the first time. These quinone-imine intermediates subsequently rearranged to more stable phenolic benzothiazine isomers. The addition of cysteine had little effect on cysteinyldopa quinone decay and did not prevent quinone-imine formation. The absorption spectra, extinction coefficients and rate constants for formation and decay of these various transient species involved in melanisation are reported.     

Biochemical identification of residues that discriminate between 3,4-dihydroxyphenylalanine decarboxylase and 3,4-dihydroxyphenylacetaldehyde synthase-mediated reactions

In available insect genomes, there are several L-3,4-dihydroxyphenylalanine (L-dopa) decarboxylase (DDC)-like or aromatic amino acid decarboxylase (AAAD) sequences. This contrasts to those of mammals whose genomes contain only one DDC. Our previous experiments established that two DDC-like proteins from Drosophila actually mediate a complicated decarboxylation-oxidative deamination process of dopa in the presence of oxygen, leading to the formation of 3,4-dihydroxyphenylacetaldehyde (DHPA), CO₂, NH_3, and H₂O₂. This contrasts to the typical DDC-catalyzed reaction, which produces CO₂ and dopamine. These DDC-like proteins were arbitrarily named DHPA synthases based on their critical role in insect soft cuticle formation. Establishment of reactions catalyzed by these AAAD-like proteins solved a puzzle that perplexed researchers for years, but to tell a true DHPA synthase from a DDC in the insect AAAD family remains problematic due to high sequence similarity. In this study, we performed extensive structural and biochemical comparisons between DHPA synthase and DDC. These comparisons identified several target residues potentially dictating DDC-catalyzed and DHPA synthase-catalyzed reactions, respectively. Comparison of DHPA synthase homology models with crystal structures of typical DDC proteins, particularly residues in the active sites, provided further insights for the roles these identified target residues play. Subsequent site-directed mutagenesis of the tentative target residues and activity evaluations of their corresponding mutants determined that active site His192 and Asn192 are essential signature residues for DDC- and DHPA synthase-catalyzed reactions, respectively. Oxygen is required in DHPA synthase-mediated process and this oxidizing agent is reduced to H₂O₂ in the process. Biochemical assessment established that H₂O₂, formed in DHPA synthase-mediated process, can be reused as oxidizing agent and this active oxygen species is reduced to H₂O; thereby avoiding oxidative stress by H₂O₂. Results of our structural and functional analyses provide a reasonable explanation of mechanisms involved in DHPA synthase-mediated reactions. Based on the key active site residue Asn192, identified in Drosophila DHPA synthase, we were able to distinguish all available insect DHPA synthases from DDC sequences primarily.     

Dye-sensitized photo-oxidation of pig kidney Dopa decarboxylase

The effects of irradiation of pig kidney Dopa decarboxylase by visible light absorbed by the intrinsic chromophore, pyridoxal-P, and by the externally added dyes, pyridoxal-P or proflavin, have been studied. In all cases inactivation was observed, even though to different extens, which seemed to be essentially correlated to tryptophanyl residues photodestruction. Kinetics of inactivation and oxidation of these amino acid residues revealed the presence of two distinct groups of tryptophan residues with different photooxidation rate constants. A different role for these classes of residues in the structure and function of Dopa decarboxylase has been suggested.