Contribution of histidine residues to the conformational stability of ribonuclease T1 and mutant Glu-58----Ala

The pK values of the histidine residues in ribonuclease T1 (RNase T1) are unusually high: 7.8 (His-92), 7.9 (His-40), and 7.3 (His-27) [Inagaki et al. (1981) J. Biochem. 89, 1185-1195]. In the RNase T1 mutant Glu-58----Ala, the first two pK values are reduced to 7.4 (His-92) and 7.1 (His-40). These lower pKs were expected since His-92 (5.5 A) and His-40 (3.7 A) are in close proximity to Glu-58 at the active site. The conformational stability of RNase T1 increases by over 4 kcal/mol between pH 9 and 5, and this can be entirely accounted for by the greater affinity for protons by the His residues in the folded protein (average pK = 7.6) than in the unfolded protein (pk approximately 6.6). Thus, almost half of the net conformational stability of RNase T1 results from a difference between the pK values of the histidine residues in the folded and unfolded conformations. In the Glu-58----Ala mutant, the increase in stability between pH 9 and 5 is halved (approximately 2 kcal/mol), as expected on the basis of the lower pK values for the His residues in the folded protein (average pK = 7.1). As a consequence, RNase T1 is more stable than the mutant below pH 7.5, and less stable above pH 7.5. These results emphasize the importance of measuring the conformational stability as a function of pH when comparing proteins differing in structure.     

Checking the pH-induced conformational transition of prion protein by molecular dynamics simulations: effect of protonation of histidine residues

The role of acidic pH in the conversion of human prion protein to the pathogenic isoform is investigated by means of molecular dynamics simulations, focusing the attention on the effect of protonation of histidine residues on the conformational behavior of human PrPC globular domain. Our simulations reveal a significant loss of alpha-helix content under mildly acidic conditions, due to destructuration of the C-terminal part of HB (thus suggesting a possible involvement of HB into the conformational transition leading to the pathogenic isoform) and a transient lengthening of the native beta-sheet. Protonation of His-187 and His-155 seems to be crucial for the onset of the conformational rearrangement. This finding can be related to the existence of a pathogenic mutation, H187R, which is associated with GSS syndrome. Finally, the relevance of our results for the location of a Cu2+-binding pocket in the C-terminal part of the prion is discussed.     

Nucler magnetic resonance studies of the unfolding of pancreatic ribonuclease.

The thermal unfolding of ribonuclease at a number of pH values has been studied by ¹H nuclear magnetic resonance spectroscopy, under conditions where the unfolding is fully reversible and concentration-independent. At pH¹ 5.5 (uncorrected for the deuterium isotope effect) there is evidence for a conformational change affecting His-48 and perhaps a methionine residue at temperatures below the major thermal transition. No evidence for intermediates in the major transition was found. The product of thermal unfolding under these conditions is not a random coil, and the remaining elements of structure probably include a phenylalanine and two histidine residues. At pH¹ 1.5 and pH¹ 2.9, the product of thermal unfolding is closer to a random coil, and under these conditions the changes in area of the histidine C₍₂₎H resonances with temperature give evidence for the existence of an intermediate in the unfolding process in which His-12 and His-119 are in a solvent-like environment, while His-48 and His-105 are not (see Westmoreland &; Matthews (1973)). The changes in the spectra of ribonuelease between pH¹ 5.5 and pH¹ 1.5 are described, and the possible relation between these changes and the alterations in thermal unfolding with pH are discussed.     

Mutational analysis of histidine residues in the human proton-coupled amino acid transporter PAT1

The proton-coupled amino acid transporter 1 (PAT1) represents a major route by which small neutral amino acids are absorbed after intestinal protein digestion. The system also serves as a novel route for oral drug delivery. Having shown that H+ affects affinity constants but not maximal velocity of transport, we investigated which histidine residues are obligatory for PAT1 function. Three histidine residues are conserved among the H+-coupled amino acid transporters PAT1 to 4 from different animal species. We individually mutated each of these histidine residues and compared the catalytic function of the mutants with that of the wild type transporter after expression in HRPE cells. His-55 was found to be essential for the catalytic activity of hPAT1 because the corresponding mutants H55A, H55N and H55E had no detectable l-proline transport activity. His-93 and His-135 are less important for transport function since H93N and H135N mutations did not impair transport function. The loss of transport function of His-55 mutants was not due to alterations in protein expression as shown both by cell surface biotinylation immunoblot analyses and by confocal microscopy. We conclude that His-55 might be responsible for binding and translocation of H+ in the course of cellular amino acid uptake by PAT1.     

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.     

Mutational analysis of histidine residues in the human proton-coupled amino acid transporter PAT1

The proton-coupled amino acid transporter 1 (PAT1) represents a major route by which small neutral amino acids are absorbed after intestinal protein digestion. The system also serves as a novel route for oral drug delivery. Having shown that H⁺ affects affinity constants but not maximal velocity of transport, we investigated which histidine residues are obligatory for PAT1 function. Three histidine residues are conserved among the H⁺-coupled amino acid transporters PAT1 to 4 from different animal species. We individually mutated each of these histidine residues and compared the catalytic function of the mutants with that of the wild type transporter after expression in HRPE cells. His-55 was found to be essential for the catalytic activity of hPAT1 because the corresponding mutants H55A, H55N and H55E had no detectable l-proline transport activity. His-93 and His-135 are less important for transport function since H93N and H135N mutations did not impair transport function. The loss of transport function of His-55 mutants was not due to alterations in protein expression as shown both by cell surface biotinylation immunoblot analyses and by confocal microscopy. We conclude that His-55 might be responsible for binding and translocation of H⁺ in the course of cellular amino acid uptake by PAT1.     

Two Histidine Residues in the Juxta-Membrane Cytoplasmic Domain of Na+/H+ Exchanger Isoform 3 (NHE3) Determine the Set Point

Histidine residues in Na+/H+ exchangers are believed to participate in proton binding and influence the Na+/H+ exchanger activity. In the present study, the function of three highly conserved histidines in the juxtamembrane cytoplasmic domain of NHE3 was studied. His-479, His-485, and His-499 were mutated to Leu, Gln or Asp and expressed in an Na+/H+ exchanger null cell line and functional consequences on Na+/H+ exchange kinetics were characterized. None of the histidines were essential for NHE3 activity, with all mutated NHE3 resulting in functional exchangers. However, the mutation in His-475 and His-499 significantly lowered NHE3 transport activity, whereas the mutation in H485 showed no apparent effect. In addition, the pH profiles of the H479 and H499 mutants were shifted to a more acidic region, and lowered its set point, the intracellular pH value above which the Na+/H+ exchanger becomes inactive, by approximately 0.3-0.6 pH units. The changes in set point by the mutations were further shifted to more acidic values by ATP depletion, indicating that the mechanism by which the mutations on the histidine residues altered the NHE3 set point differs from that caused by ATP depletion. We suggest that His-479 and His-499 are part of the H+ sensor, which is involved in determining the sensitivity to the intracellular H+ concentration and Na+/H+ exchange rate.     

Involvement of histidine residues in proton sensing of ROMK1 channel

ROMK channels are inhibited by intracellular acidification. This pH sensitivity is related to several amino acid residues in the channel proteins such as Lys-61, Thr-51, and His-206 (in ROMK2). Unlike all other amino acids, histidine is titratable at pH 6-7 carrying a positive charge below pH 6. To test the hypothesis that certain histidine residues are engaged in CO(2) and pH sensing of ROMK1, we performed experiments by systematic mutations of all histidine residues in the channel using the site-directed mutagenesis. There are two histidine residues in the N terminus. Mutations of His-23, His-31, or both together did not affect channel sensitivity to CO(2). Six histidine residues are located in the C terminus. His-225, His-274, His-342, and His-354 were critical in CO(2) and pH sensing. Mutation of either of them reduced CO(2) and pH sensitivities by 20-50% and approximately 0.2 pH units, respectively. Simultaneous mutations of all of them eliminated the CO(2) sensitivity and caused this mutant channel to respond to only extremely acidic pH. Similar mutations of His-280 had no effect. The role of His-270 in CO(2) and pH sensing is unclear, because substitutions of this residue with either a neutral, negative, or positive amino acid did not produce any functional channel. These results therefore indicate that histidine residues contribute to the sensitivity of the ROMK1 channel to hypercapnia and intracellular acidosis.     

Nuclear-magnetic-resonance study of the histidine residues of S-peptide and S-protein and kinetics of 1H-2H exchange of ribonuclease A.

1H NMR spectroscopy at 100 MHz was used to determine the first-order rate constants for the 1H-2H exchange of the H-2 histidine resonances of RNase-A in 2H2O at 35 degrees C and pH meter readings of 7, 9, 10 and 10.5. Prolonged exposure in 2H2O at 35 degrees C and pH meter reading 11 caused irreversible denaturation of RN-ase-A. The rate constants at pH 7 and 9 agreed reasonably well with those obtained in 1H-3H exchange experiments by Ohe, J., Matsuo, H., Sakiyama, F. and Narita, K. [J. Biochem, (Tokyo) 75, 1197-1200 (1974)]. The rate data obtained by various authors is summarised and the reasons for the poor agreement between the data is discussed. The first-order rate constant for the exchange of His-48 increases rapidly from near zero at pH 9 (due to its inaccessibility to solvent) with increase of pH to 10.5 The corresponding values for His-119 show a decrease and those for His-12 a small increase over the same pH range. These changes are attributed to a conformational change in the hinge region of RNase-A (probably due to the titration of Tyr-25) which allows His-48 to become accessible to solvent. 1H NMR spectra of S-protein and S-peptide, and of material partially deuterated at the C-2 positions of the histidine residues confirm the reassignment of the histidine resonances of RNase-A [Bradbury, J. H. & Teh, J. S. (1975) Chem. Commun., 936-937]. The chemical shifts of the C-2 and C-4 protons of histidine-12 of S-peptide are followed as a function of pH and a pK' value of 6.75 is obtained. The reassignment of the three C-2 histidine resonances of S-protein is confirmed by partial deuteration studies. The pK' values obtained from titration of the H-2 resonances of His-48, His-105 and His-119 are 5.3, 6.5 and 6.0, respectively. The S-protein is less stable to acid than RNase-A since the former, but not the latter, shows evidence of reversible denaturation at pH 3 and 26 degrees C. His-48 in S-protein titrates normally and has a lower pK than in RN-ase-A probably because of the absence of Asp-14, which in RN-ase-A forms a a hydrogen bond with His-48 and causes it to be inaccessible to solvent, at pH values below 9.     

Photo-CIDNP studies of the influence of ligand binding on the surface accessibility of aromatic residues in dihydrofolate reductase

The surface accessibility of the histidine, tyrosine, and tryptophan residues of Lactobacillus casei dihydrofolate reductase has been determined from 360-MHz 1H photochemically induced dynamic nuclear polarization (photo-CIDNP) NMR experiments. In the absence of ligands, four (or perhaps five) of the seven histidine residues and at least one of the four tryptophan residues are accessible to a flavin dye molecule. One of the five tyrosine residues is also slightly accessible. Of the accessible histidine residues, one becomes inaccessible on the binding of NADP+ and one on the binding of p-aminobenzoyl glutamate. These have been assigned to residues which interact directly with these two ligands. One histidine residue (probably His-22) shows an increase in accessibility on addition of folate or methotrexate to the enzyme . NADP+ complex. In addition, the binding of several ligands, notably trimethoprim, leads to an increase in the accessibility of a tryptophan residue. This is clear evidence for ligand-induced conformational changes in dihydrofolate reductase and allows us to identify some of the residues involved.     

Modification of histidine 56 in adrenodoxin with diethyl pyrocarbonate inhibited the interaction with cytochrome P-450scc and adrenodoxin reductase

Three histidine residues of bovine adrenodoxin, His-10, His-56, and His-62, were modified with diethyl pyrocarbonate. The order of the modification among the three histidines were monitored by measuring the proton NMR spectra. The modified adrenodoxin exhibited reduced affinity for adrenodoxin reductase as determined in cytochrome c reductase activity. In the presence of cholesterol, the modified adrenodoxin induced a high spin form of cytochrome P-450scc on complex formation in the same manner as native adrenodoxin. The spectral titration showed that adrenodoxin modified with diethyl pyrocarbonate exhibited a 5-fold higher Kd value than that of native adrenodoxin. These effects of the modification of adrenodoxin on the affinities for the redox partners were not proportional to the number of modified histidines determined by the optical absorbance change at 240 nm. Modification of adrenodoxin up to 2 histidine residues did not affect the affinity for the redox partners, but further modification on the third one resulted in an increase of apparent Km in cytochrome c reductase activity by 2-fold and of Kd for cytochrome P-450scc by 5-fold. The 1H NMR spectra of the modified adrenodoxin unequivocally demonstrated that histidine residues at His-10 and His-62 reacted more readily with diethyl pyrocarbonate than His-56 did, indicating that modification of His-56 was responsible for the reduction of binding affinities of adrenodoxin for redox partners. These results are consistent with the proposal that the residue of His-56 in adrenodoxin has an essential role in the electron transfer mechanism where adrenodoxin functions as a mobile shuttle.     

The aromatic residues of bovine pancreatic ribonuclease studied by 1H nuclear magnetic resonance.

1. The aromatic proton resonances in the 360-MHz 1H nuclear magnetic resonance (NMR) spectrum of bovine pancreatic ribonuclease were divided into histidine, tyrosine and phenylalanine resonances by means of pH titrations and double resonance experiments. 2. Photochemically induced dynamic nuclear polarization spectra showed that one histidine (His-119) and two tyrosines are accessibly to photo-excited flavin. This permitted the identification of the C-4 proton resonance of His-119. 3. The resonances of the ring protons of Tyr-25, Tyr-76 and Tyr-115 and the C-4 proton of His-12 were identified by comparison with subtilisin-modified and nitrated ribonucleases. Other resonances were assigned tentatively to Tyr-73, Tyr-92 and Phe-46. 4. On addition of active-site inhibitors, all phenylalanine resonances broadened or disappeared. The resonance that was most affected was assigned tentatively to Phe-120. 5. Four of the six tyrosines of bovine RNase, identified as Tyr-76, Tyr-115 and, tentatively, Tyr-73 and Tyr-92, are titratable above pH 9. The rings of Tyr-73 and Tyr-115 are rapidly rotating or flipping by 180 degrees about their C beta--C gamma bond and are accessible to flavin in photochemically induced dynamic nuclear polarization experiments. Tyr-25 is involved in a pH-dependent conformational transition, together with Asp-14 and His-48. A scheme for this transition is proposed. 6. Binding of active-site inhibitors to bovine RNase only influences the active site and its immediate surroundings. These conformational changes are probably not connected with the pH-dependent transition in the region of Asp-14, Tyr-25 and His-48. 7. In NMR spectra of RNase A at elevated temperatures, no local unfolding below the temperature of the thermal denaturation was observed. NMR spectra of thermally unfolded RNase A indicated that the deviations from a random coil are small and might be caused by interactions between neighbouring residues.     

Assignment of the histidine proton magnetic resonance peaks of soybean trypsin inhibitor (Kunitz) by a differertial deuterium exchange technique.

Deuterium exchange at the C(2)-H position of the two histidine residues of native soybean trypsin inhibitor (Kunitz) in 2-H2O was followed by 1-H nuclear magnetic resonance (NMR) spectroscopy. The two histidine residues of soybean trypsin inhibitor exchange at significantly different rates at pH* 5.00, 40 degrees. Half-times observed were: peak H1, t1/2=61 plus or minus 2 days; peak H2, T1/2=24 plus or minus 2 days. Differentially deuterated soybean trypsin inhibitor was cleaved by cyanogen bromide into two fragments each containing one histidine residue. The deuterium content of the histidine residue of each separated fragment was analyzed by 1H NMR spectroscopy. Hisidine-71 in fragment 1-114 showed approximately twice the deuterium content of His-157 in fragment 115-181. These results lead to the assignment of 1H NMR peak H1 to His-157 and peak H2 to His-71. These assignments were extended to the histidine peaks of trypsin-modified soybean trypsin inhibitor by converting the differentially deuterated virgin soybean trypsin inhibitor to the modified form. The correlation of histidine peaks in virgin amd modified soybean trypsin inhibitors was the same as proposed earlier on the basis of pK arguments. The results demonstrate that His-71 is the residue whose pK value is raised from 5.27 to 5.91 on trypsin modification of soybean trypsin inhibitor [Markley, J. L., (1973), Biochemistry 12, 2245].     

Solution structure of the IIAChitobiose-HPr complex of the N,N'-diacetylchitobiose branch of the Escherichia coli phosphotransferase system

The solution structure of the complex of enzyme IIA of the N,N'-diacetylchitobiose (Chb) transporter with the histidine phosphocarrier protein HPr has been solved by NMR. The IIA(Chb)-HPr complex completes the structure elucidation of representative cytoplasmic complexes for all four sugar branches of the bacterial phosphoryl transfer system (PTS). The active site His-89 of IIA(Chb) was mutated to Glu to mimic the phosphorylated state. IIA(Chb)(H89E) and HPr form a weak complex with a K(D) of ~0.7 mM. The interacting binding surfaces, concave for IIA(Chb) and convex for HPr, complement each other in terms of shape, residue type, and charge distribution, with predominantly hydrophobic residues, interspersed by some uncharged polar residues, located centrally, and polar and charged residues at the periphery. The active site histidine of HPr, His-15, is buried within the active site cleft of IIA(Chb) formed at the interface of two adjacent subunits of the IIA(Chb) trimer, thereby coming into close proximity with the active site residue, H89E, of IIA(Chb). A His89-P-His-15 pentacoordinate phosphoryl transition state can readily be modeled without necessitating any significant conformational changes, thereby facilitating rapid phosphoryl transfer. Comparison of the IIA(Chb)-HPr complex with the IIA(Chb)-IIB(Chb) complex, as well as with other cytoplasmic complexes of the PTS, highlights a unifying mechanism for recognition of structurally diverse partners. This involves generating similar binding surfaces from entirely different underlying structural elements, large interaction surfaces coupled with extensive redundancy, and side chain conformational plasticity to optimize diverse sets of intermolecular interactions.     

1H-NMR study on the tautomerism of the imidazole ring of histidine residues. II. Microenvironments of histidine-12 and histidine-119 of bovine pancreatic ribonuclease A

The NMR titration curves of proton chemical shifts were observed for the C2 protons of histidine residues in intact bovine pancreatic RNAase A (EC 3.1.27.5) and carboxyalkylated RNAase A. By comparing the methyl region of NMR spectra, the 250-340 nm region of circular dichoic spectra, and the NMR titration curves of tyrosine ring protons among intact and modified RNAase A, it was ascertained that the carboxyalkylation of histidine residues at position 12 or 119 did not make any appreciable conformational changes to RNAase A. With the pK values determined for intact and modified RNAase A, the microscopic pK values and molar ratios of tautomers were estimated for His-12 and His-119 by means of the procedure described in the preceding paper. The estimated microscopic pK values of tautomers were 6.2 for the N1-H tautomer of His-12, more than 8 for the N3-H tautomer of His-12, 7.0 for the N1-H tautomer of His-119, and 6.4 for the N3-H tautomer of His-119, respectively. These values were interpreted in terms of the microscopic environments surrounding the histidine residues. The microscopic structure estimated in the present study was discussed, comparing it with those from X-ray crystallography and hydrogen-tritium (or hydrogen-deuterium) exchange technique.     

Distinct histidine residues control the acid-induced activation and inhibition of the cloned K(ATP) channel

The modulation of K(ATP) channels during acidosis has an impact on vascular tone, myocardial rhythmicity, insulin secretion, and neuronal excitability. Our previous studies have shown that the cloned Kir6.2 is activated with mild acidification but inhibited with high acidity. The activation relies on His-175, whereas the molecular basis for the inhibition remains unclear. To elucidate whether the His-175 is indeed the protonation site and what other structures are responsible for the pH-induced inhibition, we performed these studies. Our data showed that the His-175 is the only proton sensor whose protonation is required for the channel activation by acidic pH. In contrast, the channel inhibition at extremely low pH depended on several other histidine residues including His-186, His-193, and His-216. Thus, proton has both stimulatory and inhibitory effects on the Kir6.2 channels, which attribute to two sets of histidine residues in the C terminus.     

1H nuclear-magnetic-resonance studies of porcine lutropin and its alpha and beta subunits.

The titration curves of the histidine residues of porcine lutropin and its isolated alpha and beta subunits have been determined by following the pH-dependence of the imidazole C-2 proton resonances. The isolated alpha subunit contains a buried histidine, whose C-2 proton does not exchange with solvent, and which has the unusually low pK of 3.3. In the native hormone all the histidine residues have relatively normal pK values (between 5.7 and 6.2). The four histidine C-2 proton resonances have been assigned to specific residues in the amino-acid sequence, by means of deuterium and tritium exchange experiments on the alpha subunit and its des(92-96) derivative. The histidine with a pK of 3.3 is identified as His-alpha87. The effects of pH on tyrosine and methyl proton resonances show that the titration of His-87 in the isolated alpha subunit is accompanied by a significant conformational change which involves loosening of the protein structure but which is not a normal unfolding transition. The role of conformational changes in the generation of biological activity by subunit association in the glycoprotein hormones is discussed.     

Histidine residue modification inhibits binding of murine β nerve growth factor to its receptor

The reaction of the β subunit of murine nerve growth factor (NGF) with diethylpyrocarbonate (DEP) results in the quantitative modification of histidine residues and the loss of binding to rabbit superior cervical ganglia microsomes. No conformational changes accompanied the conversion as judged by fluorescence spectra. Hydroxylamine converted the carbethoxy derivatives back to the unmodified imidazoles and simultaneously restored the capacity of NGF to bind to its receptor. Modification of des (1–9) NGF, from which His-4 and His-8 have been quantitatively removed, results in the same loss in binding activity, suggesting that His-75 and/or His-84 may play an important role in hormone-receptor interactions.     

The histidines reacting with ethoxyformic anhydride in porcine pancreatic lipase: their relationships with enzyme activity

The activities of porcine pancreatic lipase (449 amino acid residues) toward two different substrates, p-nitrophenylacetate and tributyrylglycerol, and their dependence on histidine ethoxyformylation were studied. In parallel, the ethoxyformylation of the lipase fragment constituting the C-terminal sequence of lipase (residues 336 to 449) was also investigated. This fragment was found to have retained the ability of lipase to catalyse p-nitrophenylacetate hydrolysis. The first histidine to react either in lipase or in the lipase fragment was His-354. The activities of the two compounds toward p-nitrophenyl-acetate were lost but that of the enzyme toward tributyrylglycerol was almost entirely retained. When a larger excess of ethoxyformic anhydride was used for the lipase reaction, 2.8 histidine residues were ethoxyformylated and characterised as His-354, His-156 and His-75, which resulted in an 85% inhibition of the tributyrylglycerol hydrolysis by the enzyme. Hydroxylamine treatment reactivated most of the lipase and lipase fragment. This is the first demonstration that the two lipase activities are not associated with the same active site. The loss of activity toward triacylglycerol hydrolysis suggests that His-156 and/or His-75 belong(s) to the active site or that a conformational change resulting from the ethoxyformylation renders the lipase inactive.     

Identification by proton nuclear magnetic resonance of the histidines in cytochrome b5 modified by diethyl pyrocarbonate

Diethyl pyrocarbonate (DEP) is an electrophilic reagent that is used to modify reversibly the histidine residues of proteins. Unfortunately, the lability of the acylated histidine adduct usually does not permit the isolation and identification of the modified histidine. By use of 500-MHz proton NMR spectroscopy, it has been possible to identify the C-H resonances of the nonaxial histidines of trypsin-solubilized bovine, rabbit, and porcine cytochrome b5 and therefore observe the interaction of DEP with specific histidine residues of cytochrome b5. In addition, the pKa of the peripheral histidines of bovine and rabbit cytochrome b5 have been measured in D2O. In the bovine protein it was found that the histidines are modified sequentially with increasing DEP concentration in the order His-26 greater than His-15 greater than His-80. This order is maintained in the rabbit protein with the following additions: His-26 approximately His-27 greater than His-15 greater than or equal to His-17 greater than His-80. The relative reactivity of the peripheral histidines with DEP was rationalized by considering three of their characteristics: (1) the pKa of the histidine, (2) the fraction of the side chain exposed to the solvent, and (3) the hydrogen-bond interactions of the imidazole ring.