An essential histidine residue in the catalytic mechanism of mammalian glutathione reductase

Glutathione reductase from human erythrocytes was inactivated by ethoxyformic anhydride, and > 95% activity was lost by modification of about 1–1.5 histidine residues per flavin (or subunit), as measured by the increased absorbance at 240 nm. Full reactivation was obtained with hydroxylamine. The rate of inactivation increased with pH and an apparent pK = 5.9 was obtained for the protolytic dissociation. The modified enzyme was inactive with NADPH and GSSG as substrates, but almost fully active in catalysis of a transhydrogenase reaction involving pyridine nucleotides. The visible absorption spectrum of oxidized or two-electron-reduced enzyme was not changed, but the flavin fluorescence of oxidized enzyme increased 2-fold after the modification. NADPH or NADP⁺ did not protect the enzyme against inactivation. It is concluded that the modification affects a histidine involved in the second half-reaction of the catalysis, i.e. reduction of GSSG by the dithiol of reduced enzyme. Glutathione reductase from three additional mammalian sources was similarly inactivated, but enzyme from yeast was much less inactivated by the corresponding treatment with ethoxyformic anhydride.     

Chemical modification of histidine residues in rabbit liver glutathione reductase

The role of histidine residues of glutathione reductase from rabbit liver was investigated by chemical modification with both ethoxyformic anhydride and dansyl chloride. At least four histidine residues were concomitantly modified by ethoxyformic anhydride at pH 6; both the GSSG reductase and the transhydrogenase activities were inhibited to the same extent. Dansyl chloride inactivated the enzyme showing pH-independence in the range 7-9. About 2.6 moles dansyl were incorporated in the protein 80% inactivated at pH 8, whereas at pH 7 a lower amount of labelling was found. Nearly complete reactivation of the inactivated enzyme could be obtained by incubation with hydroxylamine, which released all the acid-labile bound dansyl. Of the two histidine residues modified, only the slower reacting residue seems essential for activity. The modification with dansyl chloride will allow the identification of the histidine residues modified, in the sequence of the protein.     

The presence of a histidine residue at or near the NADPH binding site of enoyl reductase domain on the multifunctional fatty acid synthetase of chicken liver

Chemical modification of chicken liver fatty acid synthetase with the reagent ethoxyformic anhydride causes inactivation of the palmitate synthetase and enoyl reductase activities of the enzyme complex, but without significant effect on its beta-ketoacyl reductase or beta-ketoacyl dehydratase activity. The second-order rate constant of 0.2 mM-1 X s-1 for loss of synthetase activity is equal to the value for enoyl reductase, indicating that ethoxyformylation destroys the ability of the enzyme to reduce the unsaturated acyl intermediate. The specificity of this reagent for histidine residues is indicated by the appearance of a 240 nm absorption band for ethoxyformic histidine corresponding to the modification of 2.1 residues per enzyme dimer, and by the observation that the modified enzyme is readily reactivated by hydroxylamine. A pK value of 7.1 obtained by studies of the pH rate-profile of inactivation is consistent with that of histidine. Moreover, inactivation by ethoxyformic anhydride is unaffected by reversely blocking essential SH groups of the enzyme with 5,5'-dithiobis(2-nitrobenzoic acid), and therefore does not involve the reaction of these groups. The reaction of tyrosyl groups is excluded by an unchanged absorption at 278 nm. In other experiments, it was shown that inactivation of synthetase is protected by pyridine nucleotide cofactors and nucleotide analogs containing a 2'-phosphate group, and is accompanied by the loss of 2.4 NADPH binding sites. These results implicate the presence of a histidine residue at or near the binding site for 2'-phosphate group of pyridine nucleotide in the enoyl reductase domain of the synthetase.     

The role of histidine residues in glutamate dehydrogenase

1. Glutamate dehydrogenase was subject to rapid inactivation when irradiated in the presence of Rose Bengal or incubated in the presence of ethoxyformic anhydride. 2. Inactivation in the presence of Rose Bengal led to the photo-oxidation of four histidine residues. Oxidation of three histidine residues had little effect on enzyme activity, but oxidation of the fourth residue led to the almost total loss of activity. 3. Acylation of glutamate dehydrogenase with ethoxyformic anhydride at pH6.1 led to the modification of three histidine residues with a corresponding loss of half the original activity. Acylation at pH7.5 led to the modification of two histidine residues and a total loss of enzyme activity. 4. One of the histidine residues undergoing reaction at pH6.1 also undergoes reaction at pH7.5. 5. The presence of either glutamate or NAD(+) in the reaction mixtures at pH6.1 had no appreciable effect. At pH7.5 glutamate caused a marked decrease in both the degree of alkylation and degree of inactivation. NAD(+) had no effect on the degree of inactivation at pH7.5 but did modify the extent of acylation. 6. The normal response of the enzyme towards ADP was unaffected by acylation at pH6.1 or 7.5. 7. The normal response of the enzyme towards GTP was altered by treatment at both pH6.1 and 7.5.     

Chemical modifications of ribonuclease U1.

In order to obtain information on the nature of the amino acid residues involved in the activity of ribonuclease U1 [EC 3.1.4.8], various chemical modifications of the enzyme were carried out. RNase U1 was inactivated by reaction with iodoacetate at pH 5.5 with concomitant incorporation of 1 carboxymethyl group per molecule of the enzyme. The residue specifically modified by iodoacetate was identified as one of the glutamic acid residues, as in the case of RNase T1. The enzyme was also inactivated extensively by reaction with iodoacetamide at pH 8.0 with the loss of about one residue each of histidine and lysine. When RNase U1 was treated with a large excess of phenylglyoxal, the enzymatic activity and binding ability toward 3'-GMP were lost, with simultaneous modification of about 1 residue of arginine. The reaction of citraconic anhydride with RNase U1 led to the loss of enzymatic activity and modification of about 1 residue of lysine. The inactivated enzyme, however, retained binding ability toward 3'-GMP. These results indicate that there are marked similarities in the active sites of RNases T1 and U1.     

Identification of two essential histidine residues of ribonuclease T2 from Aspergillus oryzae

Ribonuclease (RNase) T2 from Aspergillus oryzae was modified by diethyl pyrocarbonate and iodoacetic acid. RNase T2 was rapidly inactivated by diethyl pyrocarbonate above pH 6.0 and by incorporation of a carboxymethyl group. No inactivation occurred in the presence of 3'AMP. 1H-NMR titration and photo-chemically induced dynamic nuclear polarization experiments demonstrated that two histidine residues were involved in the active site of RNase T2. Furthermore, analysis of inactive carboxymethylated RNase T2 showed that both His53 and His115 were partially modified to yield a total of one mole of N tau-carboxymethylhistidine/mole enzyme. The results indicate that the two histidine residues in the active site of RNase T2 are essential for catalysis and that modification of either His53 or His115 inactivates the enzyme.     

Essential histidine residues in coenzyme B12-dependent diol dehydrase: dye-sensitized photooxidation and ethoxycarbonylation

The apoenzyme of diol dehydrase was inactivated by photoirradiation in the presence of rose bengal or methylene blue, following pseudo-first-order kinetics. The inactivation rates were markedly reduced under a helium atmosphere, suggesting that the inactivation is due to photooxidation of the enzyme under air. The half-maximal rate of methylene blue-sensitized photoinactivation was observed at pH around 7.5. Amino acid analyses indicated that one to two histidine residues decreased upon the dye-sensitized photoinactivation, whereas the numbers of tyrosine, methionine, and lysine did not change. Ethoxyformic anhydride, another histidine-modifying reagent, also inactivated diol dehydrase, with pseudo-first-order kinetics and a half-maximal rate at pH 7.7. It was shown spectrophotometrically that three histidine residues per enzyme molecule were modified by this reagent with loss of enzyme activity. Two tyrosine residues per enzyme molecule were also modified rapidly, irrespective of the activity. The photooxidation or ethoxycarbonylation of the enzyme did not result in dissociation of the enzyme into subunits, but deprived the enzyme of ability to bind cyanocobalamin. The percentage loss of cobalamin-binding ability agreed well with the extent of inactivation. The enzyme-bound hydroxocobalamin showed only partial protecting effect against photoinactivation and resulting loss of the cobalamin-binding ability. These results provide evidence that diol dehydrase possesses essential histidine residues which are required for the coenzyme binding.     

Chemical modification of essential histidine residues in aspartase with diethylpyrocarbonate

Aspartase purified from Escherichia coli W cells was inactivated by diethylpyrocarbonate following pseudo-first order kinetics. Upon treatment of the inactivated enzyme with NH2OH, the enzyme activity was completely restored. The difference absorption spectrum of the modified vs. native enzyme preparations exhibited a prominent peak around 240 nm. The pH-dependence of the inactivation rate suggested that an amino acid residue having a pK value of 6.6 was involved in the inactivation. These results indicate that the inactivation was due to the modification of histidine residues. L-Aspartate and fumarate, substrates for the enzyme, and the Cl- ion, an inhibitor, protected the enzyme against the inactivation. Inspection of the spectral change at 240 nm associated with the inactivation in the presence and absence of the Cl- ion revealed that the number of histidine residues essential for the enzyme activity was less than two. Partial inactivation did not result in an appreciable change in the substrate saturation profiles. These results suggest that one or two histidine residues are located at the active site of aspartase and participate in an essential step in the catalytic reaction.     

Identification of histidine residues at the active site of Megalobatrachus japonicus alkaline phosphatase by chemical modification

Alkaline phosphatase from Megalobatrachus japonicus was inactivated by diethyl pyrocarbonate (DEP). The inactivation followed pseudo-first-order kinetics with a second-order rate constant of 176 M(-1) x min(-1) at pH 6.2 and 25 degrees C. The loss of enzyme activity was accompanied with an increase in absorbance at 242 nm and the inactivated enzyme was re-activated by hydroxylamine, indicating the modification of histidine residues. This conclusion was also confirmed by the pH profiles of inactivation, which showed the involvement of a residue with pK(a) of 6.6. The presence of glycerol 3-phosphate, AMP and phosphate protected the enzyme against inactivation. The results revealed that the histidine residues modified by DEP were located at the active site. Spectrophotometric quantification of modified residues showed that modification of two histidine residues per active site led to complete inactivation, but kinetic stoichiometry indicated that one molecule of modifier reacted with one active site during inactivation, probably suggesting that two essential histidine residues per active site are necessary for complete activity whereas modification of a single histidine residue per active site is enough to result in inactivation.     

Modification of histidines in human prothrombin. Effect on the interaction of fibrinogen with thrombin from diethyl pyrocarbonate-modified prothrombin

Diethyl pyrocarbonate (ethoxyformic anhydride) was used to modify histidyl residues in prothrombin. Diethyl pyrocarbonate inactivated the potential fibrinogen-clotting activity of prothrombin with a second-order rate constant of 70 M-1 min-1 at pH 6.0 and 25 degrees C. The difference spectrum of the modified protein had a maximum absorption at 240 nm which is characteristic of N-carbethoxyhistidine. The pH dependence for inactivation suggested the participation of a residue with a pKa of 6.2. Addition of hydroxylamine to ethoxyformylated prothrombin reversed the loss of fibrinogen-clotting activity. No structural differences were detected between the native and modified proteins using fluorescence emission and high-performance size-exclusion chromatography. The tyrosine and tryptophan content was not altered, but approximately 1-2 amino groups were modified. Statistical analysis of residual enzyme activity and extent of modification indicates that among 7 histidyl residues modified per molecule, there is 1 essential histidine (not in the active site) involved in the potential fibrinogen-clotting activity of prothrombin. To further examine its properties, the modified prothrombin was activated to thrombin using Echis carinatus venom protease. There was no difference in the catalytic activity of thrombin obtained from either native or ethoxyformylated prothrombin, as measured by H-D-Phe-pipecolyl-Arg-p-nitroanilide (D-Phe-Pip-Arg-NA) hydrolysis. However, thrombin produced from the modified protein showed a loss of fibrinogen-clotting activity but had a comparable apparent Ki value (about 20 microM) to thrombin from native prothrombin when fibrinogen was used as a competitive inhibitor during D-Phe-Pip-Arg-NA hydrolysis. The similarity in Ki values indicated that thrombin derived from diethyl pyrocarbonate-modified prothrombin does not have an altered fibrinogen-binding site. Although the histidyl residue involved during inactivation has not been identified, the results suggest that a histidyl residue in the thrombin portion of prothrombin is essential for interaction with fibrinogen.     

Evidence for an essential histidine in neutral endopeptidase 24.11

Rat kidney neutral endopeptidase 24.11, "enkephalinase", was rapidly inactivated by diethyl pyrocarbonate under mildly acidic conditions. The pH dependence of inactivation revealed the modification of an essential residue with a pKa of 6.1. The reaction of the unprotonated group with diethyl pyrocarbonate exhibited a second-order rate constant of 11.6 M-1 s-1 and was accompanied by an increase in absorbance at 240 nm. Treatment of the inactivated enzyme with 50 mM hydroxylamine completely restored enzyme activity. These findings indicate histidine modification by diethyl pyrocarbonate. Comparison of the rate of inactivation with the increase in absorbance at 240 nm revealed a single histidine residue essential for catalysis. The presence of this histidine at the active site was indicated by (a) the protection of enzyme from inactivation provided by substrate and (b) the protection by the specific inhibitor phosphoramidon of one histidine residue from modification as determined spectrally. The dependence of the kinetic parameter Vmax/Km upon pH revealed two essential residues with pKa values of 5.9 and 7.3. It is proposed that the residue having a kinetic pKa of 5.9 is the histidine modified by diethyl pyrocarbonate and that this residue participates in general acid/base catalysis during substrate hydrolysis by neutral endopeptidase 24.11.     

Reaction of 5-enol-pyruvoylshikimate-3-phosphate synthase with diethyl pyrocarbonate: evidence for an essential histidine residue

5-enol-Pyruvoylshikimate-3-phosphate synthase catalyzes the reversible condensation of phosphoenolpyruvate and shikimate 3-phosphate to yield 5-enol-pyruvoylshikimate 3-phosphate and inorganic phosphate. The enzyme is a target for the nonselective herbicide glyphosate (N-phosphonomethylglycine). Diethyl pyrocarbonate inactivated this enzyme with a second-order rate constant of 220 M-1 min-1 at pH 7.0 and 0 degrees C. The rate of inactivation is pH dependent and the pH inactivation rate data show the involvement of a group with a pKa of 6.8. Almost all of the original activity was recovered by treatment of the inactivated enzyme with hydroxylamine. The difference spectrum of the inactivated and native enzyme reveals a single peak at 242 nm but no trough at around 278 nm is observed. Complete inactivation required the modification of four histidine residues per molecule of the enzyme. However, statistical analysis of the residual activity and the extent of modification shows that among the four modifiable residues, only one is critical for activity. Furthermore, this inactivation is prevented by the substrates of the enzyme. The above results indicated that one histidine is located within or very close to the active site and may play an important role in catalysis.     

Evidence of an essential histidine residue in rabbit liver aryl sulfatase A.

A detailed study of the pH dependence of the Michaelis-Menten constants (V and K_m) of aryl sulfatase A (EC 3.1.6.1) from rabbit liver indicates that at least two functional groups (pK's ~4.3 and ~7 in the enzyme-substrate complex) participate in the enzymic degradation of substrate. Aryl sulfatase A is inactivated by diethyl pyrocarbonate (ethoxyformic anhydride). The enzyme that has been modified with this reagent can in turn be reactivated by treatment with hydroxylamine. The pH dependence of inactivation reveals a reactive group having a pK of 6.5–7.0. The results indicate that at least one histidine plays an important catalytic role in rabbit liver aryl sulfatase A, consistent with the results of earlier workers who employed diazotized sulfanilic acid. Phosphate ion, a competitive inhibitor, partially protects the enzyme from inactivation by diethyl pyrocarbonate whereas sulfate ion, also a competitive inhibitor, increases the rate of inactivation by diethyl pyrocarbonate. This result is of particular significance in view of the anomalous kinetics of aryl sulfatase A. The kinetic effects of even small amounts of sulfate ion impurities in many commercial sulfate ester substrate preparations is also discussed.     

Chemical modification by diethylpyrocarbonate of an essential histidine residue in 3-ketovalidoxylamine A C-N lyase

3-Ketovalidoxylamine A C-N lyase of Flavobacterium saccharophilum is a monomeric protein with a molecular weight of 36,000. Amino acid analysis revealed that the enzyme contains 5 histidine residues and no cysteine residue. The enzyme was inactivated by diethylpyrocarbonate (DEP) following pseudo-first order kinetics. Upon treatment of the inactivated enzyme with hydroxylamine, the enzyme activity was completely restored. The difference absorption spectrum of the modified versus native enzyme exhibited a prominent peak around 240 nm, but there was no absorbance change above 270 nm. The pH-dependence of inactivation suggested the involvement of an amino acid residue having a pKa of 6.8. These results indicate that the inactivation is due to the modification of histidine residues. Substrates of the lyase, p-nitrophenyl-3-ketovalidamine, p-nitrophenyl-alpha-D-3-ketoglucoside, and methyl-alpha-D-3-ketoglucoside, protected the enzyme against the inactivation, suggesting that the modification occurred at or near the active site. Although several histidine residues were modified by DEP, a plot of log (reciprocal of the half-time of inactivation) versus log (concentration of DEP) suggested that one histidine residue has an essential role in catalysis.     

Histidine in the nucleotide-binding site of NADP-linked isocitrate dehydrogenase from pig heart.

Incubation of pig heart NADP-dependent isocitrate dehydrogenase with ethoxyformic anhydride (diethylpyrocarbonate) at pH 6.2 results in a 9-fold greater rate of loss of dehydrogenase than of oxalosuccinate decarboxylase activity. The rate constants for loss of dehydrogenase and decarboxylase activities depend on the basic form of ionizable groups with pK values of 5.67 and 7.05, respectively, suggesting that inactivation of the two catalytic functions results from reaction with different amino acid residues. The rate of loss of dehydrogenase activity is decreased only slightly in the presence of manganous isocitrate, but is reduced up to 10-fold by addition of the coenzymes or coenzyme analogues, such as 2'-phosphoadenosine 5'-diphosphoribose (Rib-P2-Ado-P). Enzyme modified at pH 5.8 fails to bind NADPH, but exhibits manganese-enhanced isocitrate binding typical of native enzyme, indicating that reaction takes place in the region of the nucleotide binding site. Dissociation constants for enzyme . coenzyme-analogue complexes have been calculated from the decrease in the rate of inactivation as a function of analogue concentration. In the presence of isocitrate, activating metals (Mn2+, Mg2+, Zn2+) decrease the Kd value for enzyme . Rib-P2-Ado-P, while the inhibitor Ca2+ increases Kd. The strengthened binding of nucleotide produced by activating metal-isocitrate complexes may be essential for the catalytic reaction, reflecting an optimal orientation of NADP+ to facilitate hydride transfer. Measurements of ethoxyformyl-histidine formation at 240 nm and of incorporation of [14C]ethoxy groups in the presence and absence of Rib-P2-Ado-P indicate that loss of activity may be related to modification of approximately one histidine. The critical histidine appears to be located in the nucleotide binding site in a region distal from the substrate binding site.     

Chemical modification of the histidine residue in phospholipase A2 (Naja naja naja). A case of half-site reactivity.

Reaction of phospholipase A2 (Naja naja naja) with p-bromophenacyl bromidine leads to almost complete loss of enzymatic activity. The rate of inactivation is pH-dependent with pKa equals 6.9 for the ionizing residue. p-Bromophenacyl bromide modifies 0.5 mol of histidine/mol of enzyme as judged by amino acid analysis and incorporation studies with 14C-labeled reagent. The rate of inactivation is affected by various cations; a saturating concentration of Ca2+ decreases the rate 5-fold, while Mn2+ increases the rate by a factor of 2. Triton X-100, which by itself has little affinity for the enzyme, protects against inactivation, presumably by sequestering p-bromophenacyl bromide into the apolar micellar core. The mixed micelle system of Triton X-100, dipalmitoyl phosphatidylcholine, and Ba2+ offers the best protection, lowering the inactivation rate by at least 50-fold. This suggests an active site role for the histidine residue. Ethoxyformic anhydride also modifies phospholipase A2, by acylation of the two amino groups, a tyrosine, and 0.5 mol of histidine/mol of enzyme without totally inactivating the enzyme. Removal of the ethoxyformyl group from the histidine does not reactivate the enzyme. Thus, modification of 0.5 mol of histidine with this reagent is not responsible for the 85% loss of activity seen. Ethoxyformylated enzyme, with 0.5 mol of acylated histidine/mol of enzyme, can be further inactivated by treatment with p-bromophenacyl bromide. The resulting derivative contains 0.4 mol of the 14C-labeled p-bromophenacyl group. Other modifiable groups do not show this half-residue reactivity. For example, oxidation of phospholipase A2 with N-bromosuccinimide leads to rapid destruction of 1.0 tryptophan residue and 5% residual activity. The results of these chemical modification experiments can be interpreted in terms of a model in which the active species of enzyme interacting with mixed micelles is a dimer (or possibly higher order aggregate). The dimer, though composed of identical subunits, is asymmetric; the histidine of one subunit is accessible to ethoxyformic anhydride, while the other histidine is near a hydrophobic region of the enzyme and is chemically reactive toward p-bromophenacyl bromide.     

Bovine brain adenosine 3',5'-monophosphate dependent protein kinase. Mechanism of regulatory subunit inhibition of the catalytic subunit.

Adenosine 3',5'-monophosphate (cAMP) dependent protein kinase (EC 2.7.1.37) catalyzes the phosphorylation of serine and threonine residues of a number of proteins according to the following chemical equation: ATP + protein leads to phosphoprotein + ADP. The DEAE-cellulose peak II holoenzyme from bovine brain, which is composed of regulatory and catalytic subunits, is resistant to ethoxyformic anhydride inactivation. After adding cAMP, the protein kinase becomes susceptible to ethoxyformic anhydride inhibition. Ethoxyformic anhydride (2mM) inhibits the enzyme 50% (5 min, pH 6.5, 30 degrees) in the presence of 10 muM cAMP, but less than 5% in its absence. The substrate, Mg2+-ATP, protects against inactivation suggesting that inhibition is associated with modification of the active site. Addition of regulatory subunit or Mg2+-ATP to the isolated catalytic subunit also prevents ethoxyformic anhydride inactivation. These results suggest that the regulatory subunit shields the active site of the catalytic subunit thereby inhibiting it. In contrast to the bovine brain or muscle DEAE-cellulose peak II holoenzyme, the bovine muscle peak I holoenzyme is susceptible to ethoxyformic anhydride inactivation in the absence of cAMP.     

Photooxidation and carbethoxylation of a minor ribonuclease from Aspergillus saitoi.

In order to investigate the nature of amino acid residues involved in the active in the active site of a ribonuclease from Aspergillus saitoi, the pH dependence of the rates of inactivation of RNase Ms by photooxidation and modification with diethylpyrocarbonate were studied. (1) RNase Ms was inactivated by illumination in the presence of methylene blue at various pH's. The pH dependence of the rate of photooxidative inactivation of RNase Ms indicated that at least one functional group having pKa 7.2 was involved in the active site. (2) Amino acid analyses of photooxidized RNase Ms at various stages of photooxidative inactivation at pH's 4.0 and 6.0 indicated that one histidine residue was related to the activity of RNase Ms, but that no tryptophan residue was involved in the active site. (3) 2',(3')-AMP prevented the photooxidative inactivation of RNase Ms. The results also indicated the presence of a histidine residue in the active site. (4) Modification of RNase Ms with diethylpyrocarbonate was studied at various pH's. The results indicated that a functional group having pKa 7.1 was involved in the active site of RNase Ms.     

Involvement of arginine residues in the allosteric activation of Escherichia coli ADP-glucose synthetase

Inactivation of Escherichia coli ADP-glucose synthetase (EC 2.7.2.27) by the arginine-specific reagents cyclohexanedione and phenylglyoxal resulted primarily from interference with normal allosteric activation. Partial modification by phenylglyoxal resulted in a lessened ability of fructose 1,6-bisphosphate (fructose-P2) to stimulate and of 5'-AMP (5'-adenylate) to inhibit enzymic activity. The apparent affinity for fructose-P2 and the Vmax at saturating fructose-P2 concentrations were decreased by the arginine modification. Fructose-P2, 5'-adenylate, and several other allosteric effectors were able to partially protect the enzyme from inactivation. However, catalytic activity was not decreased by arginine modification under conditions where the enzyme was assayed in the absence of fructose-P2. The two arginine-modifying reagents differed markedly in their reactivity with the enzyme. Cyclohexanedione inactivated the enzyme quite slowly and eventually reacted with at least 14 of the 32 arginines present per subunit. Phenylglyoxal was some 50-fold more effective in inactivation, but it modified only one arginine residue per subunit.     

Hydrophobicity modulation as a tool for the purification of histidyl peptides

A methodology is described for purification of histidyl peptides based on the changes in hydrophobicity induced by the specific and reversible modification of histidine residues by ethoxyformic anhydride. The mixture of modified peptides is subjected to HPLC; peptides containing modified histidines are detected at 242 nm, recovered, deethoxyformylated, and rechromatographed under the same conditions, then being detected at 220 nm. This procedure allows their isolation free from contaminants.