Functional tuning of the catalytic residue pKa in a de novo designed esterase

AlleyCatE is a de novo designed esterase that can be allosterically regulated by calcium ions. This artificial enzyme has been shown to hydrolyze p‐nitrophenyl acetate (pNPA) and 4‐nitrophenyl‐(2‐phenyl)‐propanoate (pNPP) with high catalytic efficiency. AlleyCatE was created by introducing a single‐histidine residue (His¹⁴⁴) into a hydrophobic pocket of calmodulin. In this work, we explore the determinants of catalytic properties of AlleyCatE. We obtained the pK_a value of the catalytic histidine using experimental measurements by NMR and pH rate profile and compared these values to those predicted from electrostatics pK_a calculations (from both empirical and continuum electrostatics calculations). Surprisingly, the pK_a value of the catalytic histidine inside the hydrophobic pocket of calmodulin is elevated as compared to the model compound pK_a value of this residue in water. We determined that a short‐range favorable interaction with Glu¹²⁷ contributes to the elevated pK_a of His¹⁴⁴. We have rationally modulated local electrostatic potential in AlleyCatE to decrease the pK_a of its active nucleophile, His¹⁴⁴, by 0.7 units. As a direct result of the decrease in the His¹⁴⁴ pK_a value, catalytic efficiency of the enzyme increased by 45% at pH 6. This work shows that a series of simple NMR experiments that can be performed using low field spectrometers, combined with straightforward computational analysis, provide rapid and accurate guidance to rationally improve catalytic efficiency of histidine‐promoted catalysis. Proteins 2017; 85:1656–1665. © 2017 Wiley Periodicals, Inc.     

Assignment of the histidine 12-threonine 45 hydrogen-bonded proton in the NMR spectrum of ribonuclease A in H2O.

Described herein are proton nmr experiments on chemically modified derivatives of ribonuclease A designed to elucidate the origin of an exchangeable resonance, assigned previously to a histidine ring N proton that titrates between 11 to 13 ppm with a pK_a of 6.1 in H₂O solution. Histidines 48 and 105, which are distant from the active site, are eliminated as candidates for this resonance from inhibitor binding studies on the enzyme in acetate–water solutions. This exchangeable resonance titrates with modified pK_a's and constant area over the above pH range in His-119-N₁-carboxymethylated-RNase A and des-(121–124)-RNase A, thus eliminating the imidazole N₃ proton in the His 119-Asp 121 hydrogen bond. In His-12-N₁-carboxymethylated-RNase A, this resonance is also observable, but broadens on raising the pH above 7 and at elevated temperatures above neutrality. It exhibits a pH-independent chemical shift characteristic of the protonated state of histidine. On the basis of these findings, this exchangeable resonance, designated a, is assigned to the imidazole N₁ proton of His 12, which is hydrogen-bonded to the carbonyl oxygen of Thr 45 in the crystal.     

The pH dependence of the equilibrium constant KHyd for the hydrolysis of the Lys15-Ala16 reactive-site peptide bond in bovine pancreatic trypsin inhibitor (aprotinin)

ThepH dependence of the equilibrium constant K_Hyd for the hydrolysis of the Lys¹⁵-Ala¹⁶ reactive-site peptide bond of the bovine pancreatic trypsin inhibitor (aprotinin) was investigated over thepH range 2.3–6.5. Solutions of aprotinin, modified aprotinin with the Lys¹⁵-Ala¹⁶ peptide bond cleaved and mixtures of both species were incubated with 10 mol% porcine -trypsin. The state of equilibrium was determined by analytical cation-exchange HPLC. The K_Hyd values obtained did not exactly obey the simple equation of Dobry et al. (1952), which had to be used in an extended form with two additional parameters for a satisfactory fit. ThepH-independent equilibrium constant is 0.90 and thepK values of the Lys¹⁵ carboxyl group and of the Ala¹⁶ amino group are 3.10 and 8.22, respectively. ThepK of an additional group is apparently perturbed by the peptide-bond hydrolysis. It is 4.60 in the native and 4.40 in the modified aprotinin.     

The structure of carbonyl horseradish peroxidase: spectroscopic and kinetic characterization of the carbon monoxide complexes of His-42 → Leu and Arg-38 → Leu mutants

Horseradish peroxidase isoenzyme C (HRPC) mutants were constructed in order to understand the involvement of two key distal heme cavity residues, histidine 42 and arginine 38, in the formation and structure of the carbon monoxide complex of HRPC (carbonyl HRPC). The rates of CO binding to the wild-type glycosylated and non-glycosylated recombinant (HRPC*) ferrous enzymes were essentially identical and exhibited the same pH dependence with pK _as at 7.4 and 4.0. Data obtained with the His-42?→?Leu [(H42L)HRPC*)] and Arg-38?→?Leu [(R38L)HRPC*] mutants allowed the pK _a at 7.4 in ferrous HRPC to be assigned to His-42. The infra-red and electronic absorption spectra of HRPC-CO, HRPC*-CO, (R38L)HRPC*-CO and (H42L)HRPC*-CO have been investigated over the pH range 3.0–10.0. HRPC*-CO exhibited two ν?(CO) bands at 1934?cm^–1 and 1905?cm^–1 whose relative intensity changed with pH, showing an acidic and a basic pK _a as previously reported for HRPC [IE Holzbaur; AM English, AA Ismail (1996) J Am Chem Soc 118?:?3354–3359]. (H42L)HRPC*-CO and (R38L)HRPC*-CO exhibited single infra-red bands at 1924.2?cm^–1 (pH?7.0) and 1941.5?cm^–1 (pH?5.0) respectively. Acidic and alkaline pK _as were determined from shifts in the infra-red frequencies and by UV-visible spectrophotometry at the Söret maxima. (H42L)HRPC*-CO exhibited a pK _a at ～pH?4.0 but no alkaline pK _a. (R38L)HRPC*-CO exhibited a single pK _a at pH?6.5. Shifts of 2–3?cm^–1 in ν?(CO) with (H42L)HRPC*-CO in D₂O show that a distal residue is H-bonding to the CO in this variant at both pD?7.5 and 3.9. However, with (R38L)HRPC*-CO, only a small shift of the ν?(CO) band was observed at pD?5.5. The results are consistent with the involvement of Arg-38 in H-bonding to the CO ligand in HRPC and with His-42 modulating the distribution of carbonyl HRPC conformers below pH?8.7. These data are discussed in terms of the importance of distal pocket polarity in HRPC. It is concluded that His-42 can have a pK _a between 4.0 and 8.7 depending on its environment and the nature of the distal ligand at position 38. This enables His-42 to carry out multiple functions during the catalytic cycle of HRPC.     

A proton nuclear magnetic resonance study on the solution structure of crotamine

Proton nuclear magnetic resonance (NMR) spectra of crotamine, a myotoxic protein from a Brazilian rattlesnake (Crotalus durissus terrificus), have been analyzed. All the aromatic proton resonances have been assigned to amino acid types, and those from Tyr-1, Phe-12, and Phe-25 to the individual residues. ThepH dependence of the chemical shifts of the aromatic proton resonances indicates that Tyr-1 and one of the two histidines (His-5 or His-10) are in close proximity. A conformational transition takes place at acidicpH, together with immobilization of Met-28 and His-5 or His-10. Two sets of proton resonances have been observed for He-17 and His-5 or His-10, which suggests the presence of two structural states for the crotamine molecule in solution.     

Proton NMR investigation of heme and surrounding proton in low-spin cyanide-ligated bacterial hemoglobin from Vitreoscilla

¹H NMR spectra of low-spin cyanide-ligated bacterial hemoglobin fromVitreoscilla (VtHb-CN) are reported. The assignments of the¹H NMR spectra of VtHb-CN have been made through MCOSY, NOESY, 1D TOE and SUPERWEFT experiments. Almost all resonance peaks of heme and ligated His85 are identified. The spin-lattice relaxation timeT ¹’s and the variation relationships of chemical shifts of these peaks with temperature have been acquired, from which the distances between the measured protons and Fe³⁺, and the diamagnetic chemical shifts have been acquired, respectively. The ionization constants of pK _a’s of ligated His85 are determined through pH titration of chemical shift, which is 4.95 for ligated His85 C₂H proton. The lower pK _a is attributed to the influence of the Fe³⁺ of carrying positive charge and the coordination of His85 and Fe³⁺ of heme.     

Elucidating Relayed Proton Transfer through a His–Trp–His Triad of a Transmembrane Proton Channel by Solid-State NMR

Proton transfer through membrane-bound ion channels is mediated by both water and polar residues of proteins, but the detailed molecular mechanism is challenging to determine. The tetrameric influenza A and B virus M2 proteins form canonical proton channels that use an HxxxW motif for proton selectivity and gating. The BM2 channel also contains a second histidine (His), H27, equidistant from the gating tryptophan, which leads to a symmetric H¹⁹xxxW²³xxxH²⁷ motif. The proton-dissociation constants (pK_a's) of H19 in BM2 were found to be much lower than the pK_a's of H37 in AM2. To determine if the lower pK_a's result from H27-facilitated proton dissociation of H19, we have now investigated a H27A mutant of BM2 using solid-state NMR. ¹⁵N NMR spectra indicate that removal of the second histidine converted the protonation and tautomeric equilibria of H19 to be similar to the H37 behavior in AM2, indicating that the peripheral H27 is indeed the origin of the low pK_a's of H19 in wild-type BM2. Measured interhelical distances between W23 sidechains indicate that the pore constriction at W23 increases with the H19 tetrad charge but is independent of the H27A mutation. These results indicate that H27 both accelerates proton dissociation from H19 to increase the inward proton conductance and causes the small reverse conductance of BM2. The proton relay between H19 and H27 is likely mediated by the intervening gating tryptophan through cation–π interactions. This relayed proton transfer may exist in other ion channels and has implications for the design of imidazole-based synthetic proton channels.     

Diethylpyrocarbonate reactivity ofKlebsiella aerogenes urease: Effect ofpH and active site ligands on the rate of inactivation

Reaction ofKlebsiella aerogenes urease with diethylpyrocarbonate (DEP) led to a pseudo-first-order loss of enzyme activity by a reaction that exhibited saturation kinetics. The rate of urease inactivation by DEP decreased in the presence of active site ligands (urea, phosphate, and boric acid), consistent with the essential reactive residue being located proximal to the catalytic center. ThepH dependence for the rate of inactivation indicated that the reactive residue possessed apK _a of 6.5, identical to that of a group that must be deprotonated for catalysis. Full activity was restored when the inactivated enzyme was treated with hydroxylamine, compatible with histidinyl or tyrosinyl reactivity. Spectrophotometric studies were consistent with DEP derivatization of 12 mol of histidine/mol of native enzyme. In the presence of active site ligands, however, approximately 4 mol of histidine/mol of protein were protected from reaction. Each protein molecule is known to possess two catalytic units; hence, we propose that urease possesses at least one essential histidine per catalytic unit.     

Role of the conserved histidine and aspartic acid residues in activity and stabilization of human gelatinase B: An example of matrix metalloproteinases

Gelatinase B (MMP-9), a member of the matrix metalloproteinase family, is a zinc- and calcium-dependent endopeptidase that is known to play a role in tumor cell invasion and in destruction of cartilage in arthritis. It contains a conserved sequence⁴⁰⁰His-(X)₃-His-(X)₂₈-Asp-Asp-(X)₂-⁴³⁶Gly, the function of which is under investigation. The conserved Asp-432 and Asp-433 residues were individually replaced with Gly; these substitutions reduced the gelatinolytic activity of the enzyme to 23% and 0%, respectively. Replacing Asp-433 with Glu, however, decreased the gelatinolytic activity of the enzyme by 93% and proteolytic activity of the enzyme for the Mca-Pro-Leu-Gly-Leu-Dpa-Ala-Arg-NH₂ substrate by 79%. The wild-type and D432G and D433E mutant enzymes had similarK _m values for the synthetic substrate and similarK _i values for the competitive inhibitor, GM6001. Thek _cat/K _m values for D432G and D433E mutant enzymes, however, were reduced by a factor of 4 and their K _a ^Ca values were increased by four- and sixfold, respectively. The significance of His-400 in the activity of the enzyme was assessed by replacing this residue with Ala and Phe. Both H400A and H400F mutants were inactive toward gelatin substrate. These data demonstrate that Asp-432, Asp-433, and His-400 residues are important for the activity of gelatinase B. His-400 may act as a zinc-binding ligand similar to the His-197 in interstitial collagenase (MMP-7) and Asp-432 and Asp-433 residues are probably involved in stabilization of the active site of the enzyme. The His-400 and Asp-433 residues are conserved in all members of the MMP family. Therefore, our results are relevant to this group as a whole.Abbreviations MMP Matrix metalloproteinase - TIMP tissue inhibitor of metalloproteinase - IPTG isopropyl-D-thiogalactoside - APMA 4-aminophenyl-mercuric acetate - PCR polymerase chain reaction - Dpa 3(2,4-di-nitrophenyl) diaminopropionic acid - Mca 7-methoxycoumarin acetic acid     

ThepH dependence of the equilibrium constantK Hyd for the hydrolysis of the Lys15-Ala16 reactive-site peptide bond in bovine pancreatic trypsin inhibitor (aprotinin)

ThepH dependence of the equilibrium constant K_Hyd for the hydrolysis of the Lys¹⁵-Ala¹⁶ reactive-site peptide bond of the bovine pancreatic trypsin inhibitor (aprotinin) was investigated over thepH range 2.3–6.5. Solutions of aprotinin, modified aprotinin with the Lys¹⁵-Ala¹⁶ peptide bond cleaved and mixtures of both species were incubated with 10 mol% porcine β-trypsin. The state of equilibrium was determined by analytical cation-exchange HPLC. The K_Hyd values obtained did not exactly obey the simple equation of Dobry et al. (1952), which had to be used in an extended form with two additional parameters for a satisfactory fit. ThepH-independent equilibrium constant is 0.90 and thepK values of the Lys¹⁵ carboxyl group and of the Ala¹⁶ amino group are 3.10 and 8.22, respectively. ThepK of an additional group is apparently perturbed by the peptide-bond hydrolysis. It is 4.60 in the native and 4.40 in the modified aprotinin.     

Histidines 345 and 378 of <Emphasis Type="Italic">Bacillus stearotheromophilus</Emphasis> leucine aminopeptidase II are essential for the catalytic activity of the enzyme

The conserved histidine residues, His-191, His-227, His-345, and His-378, in Bacillus stearothermophilus leucine aminopeptidase II (LAPII) were replaced with leucine by site-directed mutagenesis. The overexpressed wild-type and mutant enzymes have been purified by nickel-chelate chromatography and their molecular masses were approximately 44.5 kDa. Under assay conditions, no LAP activity was detected in H345L and H378L. Although the K_m value for H191L increased more than 30% with respect to the wild-type LAPII, alteration in this residue did not lead to a significant change on the catalytic efficiency. The 39% decrease in K_cat/K_m for H227L was partly caused by a 3.9-fold increase in K_m value. Based on these results, it is suggested that His-345 and His-378 play a crucial role in the catalytic reaction of B. stearothermophilus LAPII.     

1H nuclear magnetic resonance studies of histidine-containing di- and tripeptides. Estimation of the effects of charged groups on the pKa value of the imidazole ring.

The nmr titration curves of chemical shifts versus pH were observed for the protons of various histidine-containing di- and tripeptides. With these results, the macroscopic pK_a values and the chemical shifts intrinsic to each ionic species were determined by a computer curve-fitting based on a simple acid dissociation sequence. The pK_a value of the imidazole ring in N-acetyl-L -histidine methylamide was assumed to represent the intrinsic (or unperturbed) pK_a of the imidazole rings of histidine having peptide linkages at both the CO and NH sides. The pK_a values of the imidazole rings observed for most di- and tripeptides were reasonably reproduced by simple calculations using the intrinsic value and the perturbations due to the CO₂^? and NH₃⁺ groups located at various positions. Some other factors affecting the pK_a value of the imidazole ring are also discussed.     

Steric Enhancement of Imidazole Basicity incis-Urocanic Acid Derivatives: Models for the Action of Chymotrypsin

To test the hypothesis that substrate-induced steric compression between His 57 and Asp 102 at the active site of chymotrypsin can increase the basicity of His 57, we have synthesized thecis- andtrans-isomers of 2-bromo-3-(N-tritylimidazole)-2-propenoic acid and 2-chloro-3-(N-tritylimidazole)-2-propenoic acid and compared selected properties with those ofcis-andtrans-urocanic acids. Thecis-isomers display low field¹H NMR signals at 17 ppm in dimethylsulfoxide, similar tocis-urocanic acid; whereas thetrans-isomers do not show strong hydrogen bonds. Increasing the size of the C2 substituent (H < Cl < Br) in thecis-isomers increases the pK_aof the imidazolium group from 6.78 for H to 7.81 and 9.10 for Cl and Br, respectively; whereas the pK_as of thetransisomers are all 6.0 ± 0.1. The results indicate that thecis-urocanic acid derivatives with large substituents at C2 act as proton sponges in water, and they support the concept that steric compression in the catalytic triad of chymotrypsin can increase the basicity of His 57.     

Inhibition by cupric ions of the hydration of CO2 catalyzed by carbonic anhydrase II

The inhibition by cupric ions of the hydration of CO₂ catalyzed by carbonic anhydrase II is interesting because of the results of Tuet al. obtained at chemical equilibrium, indicating that Cu²⁺ inhibits specifically a proton transfer in the catalytic pathway. We have measured this inhibition at steady state, using stopped-flow methods. The inhibition by Cu²⁺ of the hydration of CO₂ catalyzed by carbonic anhydrase II had aK _I near 1×10^–6 M atpH 7.0 and gave inhibition that is noncompetitive atpH 6.0 and mixed, but close to uncompetitive, atpH 6.8. ThepH dependence of this binding is consistent with a binding site for Cu²⁺ on the enzyme with apK _a near 7. The binding interaction between Cu²⁺ and the fluorescent inhibitor 5-dimethylaminonaphthalene-l-sulfonamide on carbonic anhydrase II was noncompetitive, indicating that the binding site for Cu²⁺ is distinct from the coordination sphere of zinc in which the actual interconversion of CO₂ and HCO ₃ ^– and the binding of sulfonamides takes place.     

Electrostatics of cysteine residues in proteins: Parameterization and validation of a simple model

One of the most popular and simple models for the calculation of pK_as from a protein structure is the semi‐macroscopic electrostatic model MEAD. This model requires empirical parameters for each residue to calculate pK_as. Analysis of current, widely used empirical parameters for cysteine residues showed that they did not reproduce expected cysteine pK_as; thus, we set out to identify parameters consistent with the CHARMM27 force field that capture both the behavior of typical cysteines in proteins and the behavior of cysteines which have perturbed pK_as. The new parameters were validated in three ways: (1) calculation across a large set of typical cysteines in proteins (where the calculations are expected to reproduce expected ensemble behavior); (2) calculation across a set of perturbed cysteines in proteins (where the calculations are expected to reproduce the shifted ensemble behavior); and (3) comparison to experimentally determined pK_a values (where the calculation should reproduce the pK_a within experimental error). Both the general behavior of cysteines in proteins and the perturbed pK_a in some proteins can be predicted reasonably well using the newly determined empirical parameters within the MEAD model for protein electrostatics. This study provides the first general analysis of the electrostatics of cysteines in proteins, with specific attention paid to capturing both the behavior of typical cysteines in a protein and the behavior of cysteines whose pK_a should be shifted, and validation of force field parameters for cysteine residues. Proteins 2012. © 2012 Wiley Periodicals, Inc.     

A goose-type lysozyme from ostrich (Struthio camelus) egg white: multiple roles of His101 in its enzymatic reaction

A goose-type lysozyme from ostrich egg white (OEL) was produced by Escherichia coli expression system, and the role of His101 of OEL in the enzymatic reaction was investigated by NMR spectroscopy, thermal unfolding, and theoretical modeling of the enzymatic hydrolysis of hexa-N-acetylchitohexaose, (GlcNAc)₆. Although the binding of tri-N-acetylchitotriose, (GlcNAc)₃, to OEL perturbed several backbone resonances in the ¹H–¹⁵N HSQC spectrum, the chemical shift of the backbone resonance of His101 was not significantly affected. However, apparent pK_a values of His101 and Lys102 determined from the pH titration curves of the backbone chemical shifts were markedly shifted by (GlcNAc)₃ binding. Thermal unfolding experiments and modeling study of (GlcNAc)₆ hydrolysis using a His101-mutated OEL (H101A-OEL) revealed that the His101 mutation affected not only sugar residue affinities at subsites ?3 and ?2 but also the rate constant for bond cleavage. His101 appears to play multiple roles in the substrate binding and the catalytic reaction.     

Carboxyl pKa Values and Acid Denaturation of BBL

The protein BBL undergoes structural transitions and acid denaturation between pH 1.2 and 8.0. Using NMR spectroscopy, we measured the pK_a values of all the carboxylic residues in this pH range. We employed ¹³C direct-detection two-dimensional IPAP (in-phase antiphase) CACO NMR spectroscopy to monitor the ionization state of different carboxylic groups and demonstrated its advantages over other NMR techniques in measuring pK_a values of carboxylic residues. The two residues Glu161 and Asp162 had significantly lowered pK_a values, showing that these residues are involved in a network of stabilizing electrostatic interactions, as is His166. The other carboxylates had unperturbed values. The pH dependence of the free energy of denaturation was described quantitatively by the ionizations of those three residues of perturbed pK_a, and, using thermodynamic cycles, we could calculate their pK_as in the native and denatured states as well as the equilibrium constants for denaturation of the different protonation states. We also measured ¹³C^α chemical shifts of individual residues as a function of pH. These shifts sense structural transitions rather than ionizations, and they titrated with pH consistent with the change in equilibrium constant for denaturation. Kinetic measurements of the folding of BBL E161Q indicated that, at pH 7, the stabilizing interactions with Glu161 are formed mainly in the transition state. We also found that local interactions still exist in the acid-denatured state of BBL, which attenuate somewhat the flexibility of the acid-denatured state.     

The pKa values of two histidine residues in human haemoglobin, the Bohr effect, and the dipole moments of alpha-helices

Studies of abnormal and chemically modified haemoglobins indicate that in 0.1 m-NaCl about 40% of the alkaline Bohr effect of human haemoglobin is contributed by the C-terminal histidine HC3(146)β. In deoxyhaemoglobin, the imidazole of this histidine forms a salt bridge with aspartate FG1(94)β, in oxyhaemoglobin or carbonmonoxyhaemoglobin it accepts a hydrogen bond from its own NH group instead. Kilmartin et al. (1973) showed that in 0.2 m-NaCl + 0.2 m-phosphate this change of ligation lowered the pK_a of the histidine from 8.0 in Hb³ to 7.1 in HbCO, but Russu et al. (1980) claimed that in bis-Tris buffer without added NaCl its pK_a in HbCO dropped no lower than 7.85, and that in this medium the C-terminal histidine made only a negligible contribution to the alkaline Bohr effect.We have compared the histidine resonances of HbCO A with those of three abnormal haemoglobins: HbCO Cowtown (His HC3(146)β → Leu), HbCO Wood (His FG4(97)β → Leu) and HbCO Malmø (His FG4(97)β → Gln). Our results show that the resonance assigned by Russu et al. to His HC3(146)β in fact belongs to His FG4(97)β. Although in Hb the pK_a of His HC3(146)β is 8.05 ± 0.05 independent of ionic strength, in HbCO its pK_a drops sharply with diminishing ionic strength, so that in the buffer employed by Russu et al. it has a pK_a of 6.2 and makes a contribution to the alkaline Bohr effect that is 57% larger than in the phosphate buffer employed by Kilmartin et al. (1973).In HbCO A, His FG4(97)β does not contribute to the Bohr effect, but in HbCO from which His HC3(146)β has been cleaved (HbCO des-His), His FG4(97)β is in equilibrium between two conformations with different pK_a values. This equilibrium varies with ionic strength and pH, and presumably also with degree of ligation of the haem moiety.In HbCO A, His FG4(97)β has a pK_a of 7.8 compared to the pK_a value of about 6.6 characteristic of free histidines at the surface of proteins. This high pK_a is accounted for by its interaction with the negative pole at the C terminus of helices F and FG. It corresponds to a free energy change of the same order as that observed in the interaction of histidines with carboxylate ions and confirms the strongly dipolar character of α-helices, which manifests itself even when they lie on the surface of the protein.     

Correlation of exchangeable (NH) and nonexchangeable (C2H) histidine resonances in the proton NMR spectrum of ribonuclease A in aqueous solution.

The ionization characteristics of the hydrogen-bonded His 12 N₁ proton observed to titrate between 11 to 13 ppm in the nmr spectrum of ribonuclease A in H₂O solution are compared with the ionization characteristics of the four histidine C₂ protons in the enzyme. Comparison of the pK_a's of the enzyme in H₂O and D₂O in the absence and presence of cytidine monophosphate (?5′, ?3′, and ?2′) inhibitors, line widths in the presence of Cu II at pH 3.6 and 5.6, and chemical shifts in the presence of AgNO₃ permit a correlation of the exchangeable His 12 N₁ proton with the active site histidine C₂ proton exhibiting the lower ionization pK_a. The histidines with pK_a of 5.1 and 5.6 in ribonuclease A in the absence of salt are assigned in this study to His 12 and His 119, respectively.