Inactivation of horse liver alcohol dehydrogenase by modification of cysteine residue 174 with diazonium-1H-tetrazole.

Diazonium-1H-tetrazole was tested as a potential active-site-directed reagent for amino acid residues involved in catalysis by alcohol dehydrogenase. In a novel reaction with a protein, diazonium-1H-tetrazole inactivated the enzyme selectively, and almost stoichiometrically, but reacting with the sulfur of a cysteine residue, Cys-174. As a model compound, the tetrazole adduct of free cysteine was prepared. Elementary and spectral analyses of the adduct were consistent with the structure 5-tetrazoleazo-S-cysteine. The adduct absorbs light with a maximun at 316 nm, and is destroyed by irradiation at this wavelength. The inactivated enzyme still bound NADH as determined by difference spectroscopy, but did not enhance the fluorescence of the bound NADH as did native enzyme. X-ray crystallographic studies of free enzyme have shown that Cys-174 coordinates the zinc at the active site (Eklund, H., Nordstr?m, B., Zeppezauer, E., S?derlund, G., Ohlsson, I., Boiwe, T., and Br?ndén, C-I. (1974), FEBS Lett. 44, 200-204). The modified enzyme is probably inactive because the large, negatively charged tetrazole ring interferes sterically or electrostatically with the binding of substrates or with hydride transfer.     

The reaction of mercuric acetate with histidine and tyrosine

The reaction of mercuric acetate with polypeptides in an appropriate buffer system has been found to result in the selective binding of two atoms of mercury to each tyrosine and histidine residue. These heavy atom labels are stable to the high chloride concentrations used to displace the excess mercury (II) from other binding sites on the polypeptide. The kinetics and stoichiometry of these reactions have been studied by the binding of radioactive (²⁰³Hg) mercuric acetate to synthetic polymers of these amino acids and by ultraviolet-visible spectroscopy. For a polymer containing tyrosine the mercuration kinetics closely match those for the following mechanism:

At 60°C, and in a buffer containing 0.05M TRIS-acetate, k₁ was determined to be 9.47 ± 0.27 M^?1 min^?1. The best match to the data was for k₁/k₁ = 5.5 It was discovered that there is an inverse relationship between k₁ and the TRIS buffer concentration. The activation energy of k₁ was determined to be 18.9 ± 0.1 kcal/mole.Chemical analyses of the products obtained from the reaction of mercuric acetate with tyrosine amide, L(-)-histidine and the methyl ester of L(-)-histidine have established that mercuration results in the formation of a Hg-C bond at the C₃ and C₅ sites on the phenolic ring in tyrosine and at the C₄ site in the imidazole ring in histidine. The site of the second mercury retained by histidine in the presence of high chloride concentrations is uncertain but does involve the amine functions of the imidazole ring.The reaction conditions employed also cause the oxidation of methionine and cysteine to methionine sulfoxide and cysteic acid, respectively. Cystine, however, resists oxidation.     

The reaction of penicillin with proteins.

The mode of reaction of benzylpenicillin with two proteins was studied, with particular reference to the allergenicity of penicillin. These reactions, with pig insulin, and with hen's-egg-white lysozyme, were carried out in neutral solution at 37 degrees C. High concentrations of penicillin are needed to label the proteins, owing to concurrent hydrolysis of penicillin. Evidence has been obtained that the penicillin-reactive sites on the insulin molecule are the alpha-amino group at the N-terminus of the A chain and the epsilon-amino group of the lysine residue; whereas a site of reaction with lysozyme appears to be the epsilon-amino group of lysine-116.     

Introduction of the dansyl group into histidine and tyrosine residues in peptides and proteins

Two dansyl derivatives: 1-(5-dimethylaminonaphthalene) sulfonyl (4-amino)-benzyl amine and 1-(5-dimethylaminonaphthalene) sulfonyl beta(4-aminophenyl) ethylamine, have been recently synthesized. Reaction of these compounds with nitrous acid lead to the corresponding dansyl-bearing diazonium salts. The latter derivatives can couple, under mild basic conditions, to the imidazole moiety of histidine, the phenolic ring of tyrosine and to the epsilon-amino function of lysine. The applicability of the two reagents was tested in the modification of several peptides, including [D-Phe6]LHRH, [D-Gln6]LHRH, Leu-enkephalin and Tyr-tuftsin, and proteins such as calmodulin, bovine serum albumin and nerve growth factor.     

Determination of chemical properties of individual histidine and tyrosine residues of concanavalin A by competitive labeling with 1-fluoro-2,4-dinitrobenzene

A selective peptide-mapping procedure was devised to purify peptides containing histidine or tyrosine residues from proteolytic digests of concanavalin A (Con A). The protein was modified with maleic anhydride followed by 1-fluoro-2,4-dinitrobenzene (Dnp-F) and then digested with thermolysin. The resulting labeled peptides were separated by high-performance liquid chromatography, and the Dnp-histidine and Dnp-tyrosine peptides were identified by their spectral characteristics. From their amino acid compositions, the labeled peptides could all be assigned within the known sequence. Peptides representing five of the six histidines and all seven tyrosines were obtained. With the same peptide-mapping procedure, the chemical properties (pK and reactivity) of these residues were determined. Samples of concanavalin A at various pH values were labeled with trace amounts of [3H]Dnp-F, in the presence of Gln-Gly as an internal standard. To each sample was added an aliquot of a mixture of [14C]Dnp-Gln-Gly and [14C]Dnp-maleyl-Con A. Portions of each sample were removed, [14C]Dnp-Ala-Ala and epsilon-[14C]Dnp-lysine were added, and the mixtures were hydrolyzed. The various Dnp amino acid derivatives were purified by HPLC. The remainder of each [3H]Dnp sample was maleylated, dinitrophenylated, and digested with thermolysin and separated by HPLC as above. From the 3H/14C ratios of the Dnp amino acid derivatives and the Dnp peptides relative to the ratio of the internal standard, pK and reactivity data were obtained for (a) the average behavior of the lysine, histidine, and tyrosine residues and (b) the individual behavior of the N-terminal alanine residue and the five histidine and seven tyrosine residues in the protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

The reaction of the histidine residues of luteinizing hormone with ethoxyformyl anhydride.

Bovine and porcine luteinizing hormones (B-LH, P-LH) and their subunits were treated by ethoxyformyl anhydride. The acylation of the histidine residues was followed by examination of the absorbance spectrum. All the histidine residues of the luteinizing hormone molecule can be modified at pH5. However 2 His in B-LH and 1 in P-LH appear to be much less reactive at pH 5 than the others and their acylated imidazols more labile at the same pH. At neutral pH, 2 histidines in B-LH (and 1 in P-LH) become unreactive. In the case of the subunits, 1 histidine becomes unreactive in each subunit at neutral pH. These unreactive histidine residues at neutral pH are probably those which appear to be poorly reactive at pH 5. Comparison of the results obtained with B-LH and P-LH suggests that of the 2 histidine residues present in B-LH and absent in P-LH (beta 60, beta 112), only one exhibits a low reactivity. Acylation of 4 His in B-LH do not cause dissociation into subunits of the molecule but supress 95 per cent of the biological activity.     

The iron and subunit binding sites of hemerythrin. The role of histidine, tyrosine and tryptophan.

Of the three tyrosine residues available for nitration by tetranitromethane in hemerythrin, nitration of tyrosine residue 70 has no effect on dissociation of octomers to monomers, but nitration of tyrosines 18 and/or 67 results in dissociation to monomers. The latter data suggests these residues are important for subunit association. The reactive sulfhydryl, the modification of which produces dissociation, was protected as a mixed disulfide during the nitration but was regenerated for analysis of the state of association. Residue 70 can be selectively modified because of its exposed position and perhaps because of its slightly lower pk of 6.9, compared to 7.3 as an average of all nitrotyrosines in a completely nitrated hemerythrin. Solvent perturbation studies in 20% Me2SO indicate that 3 tyrosines, in agreement with the nitration results, and 2 tryptophan residues are exposed; however, oxidation at a 2-fold molar excess of N-bromosuccinimide oxidizes three tryptophan whereas a 3.5-fold excess oxidizes all four, but results in a rapid active site destruction. Photo-oxidation with methylene blue results in oxidation of only two tryptophan residues. These data have been interpreted to indicate that two tryptophans are free and two are involved in subunit association. Photo-oxidation with methylene blue results in the destruction of three histidines but no decrease in active site absorption. Histidine modification with diethyloxydiformate shows that three histidines react with no change in active site absorption. These results indicate that four histidines are unreactive toward these modifying agents and are therefore either buried or are ligands to the iron.     

O-carboxamidomethyl tyrosine as a reaction product of the alkylation of proteins with iodoacetamide

Iodoacetamide-1-¹⁴C was found to be rapidly incorporated into RBP, a protein devoid of free SH, under conditions similar to those normally employed for the derivatization of SH. The reaction extent is pH dependent and at pH 10.0 one mole of acetamide was incorporated per mole of tyrosine residue. The amino acid composition of the alkylated RBP was found to be identical to RBP except for a loss of tyrosine and the appearance of a new dicarboxylic acid peak which was converted to tyrosine by prolonged acid hydrolysisUnder similar reaction conditions, phenol and p-cresol reacted rapidly to form phenoxyacetamide and p-cresoxyacetamide. These phenolic ethers as well as anisole and phenetole were found to be readily hydrolized under the conditions normally used to hydrolyze protein.The incorporation of acetamide into RBP did not effect its riboflavinbinding capacity or its immunological reactivity to RBP antibody. The ¹⁴C alkylated RBP has been found to be a convenient tool for biological half-life studies.The tyrosine residues of glucagon react with iodoacetamide in a similar fashion and the use of ¹⁴C-iodoacetamide may prove to be a convenient means of introducing ¹⁴C into proteins. Iodoacetamide in the pH 7–10.0 range will derivatize the cysteine and tyrosine groups of proteins at comparable rates.     

Increase of histidine content in Brassica rapa subsp. oleifera by over-expression of histidine-rich fusion proteins

An approach that enables the increase of the quantity of a specific amino acid in crop plants is reported. Oleosin gene from Arabidopsis thaliana or 30K movement protein gene of Tobacco mosaic virus (TMV; genus Tobamovirus) were cloned under the control of napin or hybrid promoters, and in fusion to synthetic poly-histidine (poly-His) sequences for transformation into spring turnip rape (Brassica rapa subsp. oleifera; synonym to B. campestris). The most stable expression cassettes for the poly-His production prior to the plant transformation were selected by analyzing the protein expression in in vitro translation and in transient plant expression systems using GFP as marker. Expression of the poly-His-constructs in transgenic Brassica rapa plants was analyzed using dot and western blotting and PCR. The constructs were stably expressed in the third generation of the transgenic plant lines. Histidine content was measured from the seeds of the transgenic plants, and some plant lines had more than 20% increase in histidine content compared to wild type. The methodology may be widely applicable to increase the content of any amino acid in crop plants including those encoded by rare codons.     

The chemical modification of beef liver catalase. V. Ethoxyformylation of histidine and tyrosine residues of catalase with diethylpyrocarbonate.

In order to elucidate the possible roles of histidine and tyrosine residues of catalase [EC 1.11.1.6] in maintaining the quaternary structure and catalatic activity, diethylpyrocarbonate modification experiments were carried out. A method for the estimation of N-ethoxyformyl (EF)-His at pH 5--7 and of O-ethoxyformyl (EF)-Tyr in alkaline solution by measuring A 242 nm (ximM = 3.2) and A278 nm (ximM = 1.16), respectively, was developed. The formation of EF-His and EF-Tyr was an electrophilic reaction and was dependent on pH, exhibiting pK values of 6.8 and 9.9, respectively. The maximal yield of EF-His at pH 6.0 was 49% of the total histidine content, but no inactivation nor unfolding of the enzyme was observed. The formation of 12 EF-Tyr residues per mole of catalase at pH 8.1 did not cause any inactivation, but the formation of 8 more EF-Tyr residues at pH 8.9 resulted in both inactivation and unfolding. Nearly complete inactivation and partial splitting of catalase were observed when 43-46 EF-Tyr residues per mole were produced at pH 10.0. More EF-His residues were formed by the reaction of diethyl pyrocarbonate with cyanoethylated (CE)-catalase monomer (subunit) than with CE-catalase tetramer. The CE-catalase tetramer and monomer were extensively O-ethoxyformylated, reaching 100% EF-Tyr formation. These results indicate that a half of the histidine residues may lie outside the protein core and that three-quarters of the tyrosine residues are probably in the protein core of the enzyme. The production of 2--3 EF-Tyr residues per mole of the monomer by ethoxyformylation at pH 7.0 was accompanied by a decrease in the magnitude of the Soret peak. A possible interaction of those tyrosine residues with porphyrin of the heme group is discussed.