Structure and dynamics of hydronium in the ion channel gramicidin A.

The effects of the hydronium ion, H(3)0+, on the structure of the ion channel gramicidin A and the hydrogen-bonded network of waters within the channel were studied to help elucidate a possible mechanism for proton transport through the channel. Several classical molecular dynamics studies were carried out with the hydronium in either the center of a gramicidin monomer or in the dimer junction. Structural reorganization of the channel backbone was observed for different hydronium positions, which were most apparent when the hydronium was within the monomer. In both cases the average O-O distance between the hydronium ion and its nearest neighbor water molecule was found to be approximately 2.55 A, indicating a rather strong hydrogen bond. Importantly, a subsequent break in the hydrogen-bonded network between the nearest neighbor and the next-nearest neighbor(approximately 2.7 -3.0 A) was repeatedly observed. Moreover, the carbonyl groups of gramicidin A were found to interact with the charge on the hydronium ion, helping in its stabilization. These facts may have significant implications for the proton hopping mechanism. The presence of the hydronium ion in the channel also inhibits to some degree the reorientational motions of the channel water molecules.     

Substrate-selective activation of histidine-modified porcine pancreatic alpha-amylase by chloride ion.

Porcine pancreatic alpha-amylase (1,4-alpha-D-glucan glucanohydrolase) [EC 3.2.1.1] has both amylase activity (hydrolysis of alpha-1,4-D-glucoside bond of starch) and maltosidase activity (hydrolysis of p-nitrophenyl-alpha-D-maltoside to p-nitrophenol and maltose). By the modification of histidine residues of porcine pancreatic alpha-amylase with diethylpyrocarbonate (DEP), both amylase and maltosidase activities were decreased in the absence of chloride ion. In the presence of chloride ion, however, maltosidase activity of the modified enzyme was increased to more than 260% of that of the native enzyme, whereas amylase activity was decreased to less than 15% of the native enzyme. Since the chloride ion binding site is part of the active site loop [Buisson et al. (1987) Food Hydrocolloids 1,399-406 and Buisson et al. (1987) EMBO J. 6, 3909-3916], the special arrangements of both catalytic and modified histidine residues induced by the chloride ion binding would enhance only the maltosidase activity of the histidine-modified enzyme.     

NMR studies of interactions between inhibitors and porcine pancreatic phospholipase A2.

Two-dimensional NMR studies were performed on the complexes of porcine pancreatic phospholipase A2, bound to a micellar lipid-water interface of fully deuterated dodecylphosphocholine, with competitive inhibitors derived from the following general structure: [formula: see text] X and Y are alkyl chains with various 'reporter groups'. The interactions between the inhibitor and the enzyme were localized by comparison of 2-D nuclear Overhauser effect spectra using protonated and selectively deuterated inhibitors, and inhibitors with groups having easily identifiable chemical shifts. These experiments led us to the following conclusions for the phospholipase A2/inhibitor/micelle complex: i) the His48 C2 ring proton is in close proximity to both the amide proton and the methylene protons at the sn-1 position of the glycerol skeleton of the inhibitor, ii) the acyl chain of the inhibitor at the sn-2 position makes hydrophobic contacts near Phe5, Ile9, Phe22 and Phe106; iii) no interactions between the acyl chain at the sn-1 position and the protein could be identified. Comparison of our results on the enzyme/inhibitor/micelle ternary complex with the crystal structure of the enzyme-inhibitor complex shows that the mode of inhibitor binding is similar. However, in several cases we found indications that the hydrophobic chains of the inhibitors can have multiple conformations.     

1H NMR study on the interaction of cupric ion with ribonuclease A.

The reassignment of the 1H NMR C-2 histidine signals of the bovine pancreatic ribonuclease A has required a revision of the 1H NMR data on the role of the different histidines in their interaction with the Cu2+. The results of our measurements carried out at p2H 5.5 and 7.0 reduce the importance of His-12 as main site of interaction. At p2H 5.5 a very strong binding site involves His-119, while a weaker one contains certainly His-105. On the contrary, at p2H 7.0 the histidines 105 and 119 seem to possess binding constants of the same order of magnitude and in addition they provide stronger ligands for the Cu2+ than His-12. The comparison with X-ray data in the crystal shows numerous analogies. Finally, preliminary results on the competitive inhibition effect between the Cu2+ and 2',3'-cytidine monophosphoric acid are discussed.     

The ribonuclease inhibitors from porcine thyroid and liver are slow, tight-binding inhibitors of bovine pancreatic ribonuclease A

Ribonuclease inhibitors were purified from the latent ribonuclease fractions of porcine thyroid and liver and used to test the hypothesis that their inhibition of bovine pancreatic ribonuclease A is correctly described by tight-binding rather than Michaelis-Menton kinetics. Both proteins were found to act as slow, tight-binding inhibitors of the enzyme. These steady-state velocities also showed that both the thyroid and liver inhibitors were competitive inhibitors of bovine pancreatic ribonuclease A with Ki's of 0.1 and 0.4 nM, respectively. In contrast to interpretations based on Michaelis-Menton assumptions that show non-competitive inhibition, these results suggest that an enzyme:inhibitor:substrate complex does not exist.     

Modification of amino acids and bovine pancreatic ribonuclease A by kethoxal.

Kethoxal (3-ethoxy-2-ketobutanal) reacts with the guanidino group of Nalpha-acetylarginine to produce four derivatives, reactive to periodate, stable at pH 7, with 15% reverting to arginine on acid hydrolysis. Other amino acids with blocked alpha-amino groups do not react, except the epsilon-amino of lysine (slowly). The pK of the mixed Kethoxal-Nalpha-acetylarginine derivatives is 5.8-6.1. Kethoxal reacts at neutral pH with arginyl residues of bovine pancreatic ribonuclease A. In the presence of an active-site ligand, arginine-39 and arginine-85 react at about equal rates. The loss of enzymic activity at pH 7 is proportional to the combined loss of these residues. The enzymic activity toward RNA is 20-25% of that of native RNAase at pH 7, and 90-100% at pH 5. In the absence of an active site ligand, arginine-10 is also modified with the loss of almost all enzymic activity, although arginine-10 is not an active-site residue. Arginine-33 is unreactive. Kethoxal-modified RNAase undergoes cross-linking in solution at pH 7 or in the freeze-dried state, Incubation at pH 9 in the presence of homoarginine results in partial regeneration of arginyl residues and activity at pH 7. Kethoxal modification of arginines-39 and -85 appears to raise the pK of lysine-41 by about 1 unit, as indicated ty the pH dependence of arylation by 2-carboxy-4,6-dinitrochlorobenzene. The claims of Patthy and Smith (J. Biol, Chem. (1975) 250, 565-569), and of Takahashi (J. Biol. Chem. (1968) 243, 6171-6179) that arginine-39 is a more important functional residue than is arginine-85 are questioned.     

Proton NMR assignments and regular backbone structure of bovine pancreatic ribonuclease A in aqueous solution

Proton NMR assignments have been made for 121 of the 124 residues of bovine pancreatic ribonuclease A (RNase A). During the first stage of assignment, COSY and relayed COSY data were used to identify 40 amino acid spin systems belonging to alanine, valine, threonine, isoleucine, and serine residues. Approximately 60 other NH-alpha CH-beta CH systems were also identified but not assigned to specific amino acid type. NOESY data then were used to connect sequentially neighboring spin systems; approximately 475 of the possible 700 resonances in RNase A were assigned in this way. Our assignments agree with those for 20 residues assigned previously [Hahn, U., & Rüterjans, H. (1985) Eur. J. Biochem. 152, 481-491]. Additional NOESY correlations were used to identify regular backbone structure elements in RNase A, which are very similar to those observed in X-ray crystallographic studies [Wlodawer, A., Borkakoti, N., Moss, D. S., & Howlin, B. (1986) Acta Crystallogr. B42, 379-387].     

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.     

Assignment of the imidazole ring nitrogen protons of histidine 48 in the proton NMR spectrum of ribonuclease A in water solution.

Several exchangeable resonances, designated a, b, c and d are observed in the 11-14 ppm (from 2,2-dimethyl-2-silapentane-5-sulfonate) region of the proton spectrum of ribonuclease A in water solution. We describe a number of lines of evidence suggesting the assignment of peaks b and c to the N1 and N3 protons of His 48, which occupies an interior position in the protein remote from the active site. This evidence includes the observation that the binding of Cu(II) and 3'-CMP (cytidine 3'-monophosphate) has no effect on these resonances. Further evidence includes pH titration data showing a pKa of approx. 2 for these protons, solvent exchange rates in the native state and with disulfide bridges IV-V and III-VIII cleaved, the observation of the carboxymethylated enzymes CM-His12-RNAase A and CM-His119-RNAase A, and of the modified enzymes Des(1-21)-RNAase A (S-protein) and Des(119-124)-RNAase A.     

NMR studies of myelin basic protein. XIII. Assignment of histidine residues in rabbit, bovine and porcine proteins

Myelin basic protein from three species (rabbit, cow and pig) and peptides from enzymatic digests or cleavage of the proteins have been examined in aqueous solutions by proton nuclear magnetic resonance (NMR) at 400 MHz. The epsilon 1-CH and delta 2-CH resonances of all the histidine residues in the three proteins have been assigned and the pK values have been measured. The heterogeneity of chemical shifts among these resonances can be variously ascribed to persistent localized secondary structures and to effects arising from charged side-chains, particularly those of aspartic acid residues, and from side-chains of aromatic moieties.     

The structure and function of ribonuclease T1. XXI. Modification of histidine residues in ribonuclease T1 with iodoacetamide.

1. When ribonuclease T1 [EC 3.1.4.8] (0.125% solution) was treated with a 760-fold molar excess of iodoacetamide at pH 8.0 and 37 degrees, about 90% of the original activity was lost in 24 hr. The half-life of the activity was about 8 hr. The binding ability for 3'-GMP was lost simultaneously. Changes were detected only in histidine and the amino-terminal alanine residues upon amino acid analyses of the inactivated protein and its chymotryptic peptides. The inactivation occurred almost in parallel with the loss of two histidine residues in the enzyme. The pH dependences of the rate of inactivation and that of loss of histidine residues were similar and indicated the implication of a histidine residue or residues with pKa 7.5 to 8 in this reaction. 3'-GMP and guanosine showed some protective effect against loss of activity and of histidine residues. The reactivity of histidine residues was also reduced by prior modification of glutamic acid-58 with iodoacetate, of lysine-41 with maleic or cis-aconitic anhydride or 2,4,6-trinitrobenzenesulfonate or of arginine-77 with ninhydrin. 2. Analyses of the chymotryptic peptides from oxidized samples of the iodoacetamide-inactivated enzyme showed that histidine-92 and histidine-40 reacted with iodoacetamide most rapidly and at similar rates, whereas histidine-27 was least reactive. Alkylation of histidine-92 was markedly slowed down when the Glu58-carboxymethylated enzyme was treated with iodoacetamide. On the other hand, alkylation of histidine-40 was slowed down most in the presence of 3'-GMP. These results suggest that histidine-92 and histidine-40 are involved in the catalytic action, probably forming part of the catalytic site and part of the binding site, respectively, and that histidine-27 is partially buried in the enzyme molecule or interacts strongly with some other residue, thus becoming relatively unreactive.     

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.