Proton nuclear magnetic resonance studies on bovine lutropin, its subunits, and on the alpha subunit of pregnant mare serum gonadotropin. Assignment of histidine resonances in the alpha subunit.

The pK values of the 3 histidine residues in the common alpha subunits of bovine and equine glycoprotein hormones have been determined from titration curves generated from their C-2 proton nuclear magnetic resonances at different pH values. Assignment of resonances to specific histidines is based on a comparison between the two species, which have 1 histidine residue in different positions in their sequences, and of the bovine alpha subunit after removal of its histidine 94 by treatment with carboxypeptidases. In both species, those histidines closest to the COOH terminus titrate with near normal pK values of 6.2. The histidine residue found in the bovine subunit at position 87 titrates with an approximate pK value of 5.4. Histidine 83, adjacent to an oligosaccharide moiety in both species, does not titrate over a pH range of 4.0 to 8.0 and thus appears inaccessible to solvent. Similarly, in bovine lutropin-beta, 1 of 3 histidine residues does not titrate between pH 5.0 and 7.0. In the intact hormone, 2 "nontitratable" histidine residues are found. Changes in the characteristics of the signals, however, preclude unambiguous assignment of these two resonances to the nontitrating histidines in the isolated subunits. It appears that changes in the environment of at least some histidines occur when the subunits combine to yield intact hormone.     

Proton magnetic resonance studies of carbonic anhydrase. II. Group controlling catalytic activity.

The seven resonances observed in the histidine region of the proton magnetic resonance (pmr) spectrum of human carbonic anhydrase B and reported in the preceding paper are studied in the presence of sulfonamide, azide, cyanide, and chloride inhibitors and in metal-free, cadmium substituted, cobalt substituted, and carboxymethylated forms of the enzyme. Results indicate that the two resonances that move-downfield with increasing pH and the two that do not move with pH reflect residues located at the active site. The first two resonances are assigned to the same titratable histidine whose pK value of 8.24 corresponds to that of the group controlling catalytic activity. Addition of anions or sulfonamides, removal of zinc, or substitution of cadmium for zinc at the active site, procedures known to abolish enzymatic activity, prevent titration of this residue. Partial inhibition of carbonic anhydrase by chloride slectively increases the pK value of the group controlling catalytic activity and of the histidine with pK equals 8.24. Experiments with metal-free and cadmium carbonic anhydrases and comparisons with model systems suggest that this histidine is bound to the metal ion at high pH; at low pH this complex appears to dissociate as protons compete with the metal for the imidazole group. It is proposed that ionization of the group controlling catalytic activity represents loss of the pyrrole proton of this neutral ligand when it binds to Zn(II), forming an imidazolate anion and juxtaposing a strong base and a powerful Lewis acid at the active site. When bound to zinc as an anion, this histidine can act as a general base catalyst in the hydration of carbon dioxide and be replaced as a metal ligand by an oxygen of the substrate in the course of the reaction. The histidine-metal complex is thought to exist in a strained configuration in the active enzyme so that its imidazole-metal bond is readily broken on addition of substrates or inhibitors. This model is consistent with the available data on the enzyme and is discussed in relation to alternative proposals.     

Proton nuclear magnetic resonance studies of histidines in horse carbonic anhydrase I

The 250 MHz 1H-NMR spectrum of horse carbonic anhydrase I (or B) (carbonate hydro-lyase, EC 4.2.1.1) was measured as a function of pH under various conditions. Eight resonances corresponding to histidine C-2 protons and four resonances corresponding to histidine C-4 protons were identified and assigned to individual histidine residues in the enzyme molecule. Substantial similarities between horse and human carbonic anhydrases I were demonstrated. While the human enzyme has three titratable histidine residues in its active site, the horse enzyme has only two, His-67 in the human enzyme being replaced by Gln in the horse enzyme (Jabusch, J.R., Bray, R.P. and Deutsch, H.F. (1980) J. Biol. Chem. 255, 9196-9204). This substitution has small but significant effects on the behaviour of the other active-site histidines. His-64 and His-200. However, His-64 has an anomalously low pKa value also in horse isoenzyme I, as previously observed in human isoenzyme I (Campbell, I.D., Lindskog, S. and White, A.I. (1974) J. Mol. Biol. 90, 469-489).     

Proton nuclear magnetic resonance study of cobrotoxin.

Cobrotoxin (Mr 6949), which binds tightly to the acetylcholine receptors, contains no phenylalanines and only two histidines, two tyrosines, and one tryptophan that result in well-resolved aromatic proton resonances in D2O at 360 MHz. His-32, Tyr-25, and the Trp are essential for toxicity and may interact with the acetylcholine receptor. We assign two titratable resonances (pKa = 5.1) at delta = 9.0 and 7.5 ppm at pH 2.5 and at 7.7 and 7.1 ppm at pH 9.5 to the C-2 and C-4 ring protons, respectively, of His-4. Two other titratable resonances (pKa = 5.7) at delta = 8.8 and 6.9 ppm at pH 2.5 and at 7.8 and 6.7 ppm at pH 9.5 are assigned to the C-2 and C-4 ring protons of His-32, respectively. The differences in delta values of the two histidines reflect chemically different microenvironments while their low pKa values could arise from nearby positive charges. A methyl resonance gradually shifts upfield to delta approximately 0.4 ppm as His-4 is deprotonated and is tentatively assigned to the methyl group of Thr-14 or Thr-15 which, from published X-ray studies of neurotoxins, are located in the vicinity of His-4. Further, we have identified the aromatic resonances of the invariant tryptophan and individual tyrosines and the methyl resonance of one of the two isoleucines in the molecule. Several broad nontitrating resonances of labile protons which disappear at pH greater than 9 may arise from amide groups of the beta sheet in cobrotoxin.     

Proton magnetic resonance spectra of adrenodoxin: features of the aromatic region

This paper presents the first 1H-NMR spectra of the aromatic region of adrenodoxin, a mammalian mitochondrial 2Fe-2S non-heme iron ferredoxin. One-dimensional proton NMR spectra of both reduced and oxidized adrenodoxin were recorded as a function of pH. Resonances due to two of the three histidines of adrenodoxin gave sharp signals in the one-dimensional proton NMR spectra. The pKa values of the resolved histidine resonances in the oxidized protein were 6.64 +/- 0.03 and 6.12 +/- 0.06. These values were unchanged when adrenodoxin was reduced by the addition of sodium dithionite. In addition, the oxidized protein showed a broadened histidine C-2H resonance with a pKa value of approx. 7. This resonance was not apparent in the spectra of the reduced protein. The resonances due to the single tyrosine in adrenodoxin were identified using convolution difference spectroscopy. In addition, a two-dimensional Fourier-transform double quantum filtered (proton, proton) chemical shift correlated (DQF-COSY) spectrum of oxidized adrenodoxin was obtained. The cross peaks of the resonances due to the tyrosine, the four phenylalanines, and two of the three histidines of adrenodoxin were resolved in the DQF-COSY spectrum. Reduction of the protein caused several changes in the aromatic region of the NMR spectra. The resonances assigned to the C2 proton of the histidine with a pKa of 6.6 shifted upfield approx. 0.15 ppm. In addition, when the protein was reduced one of the resonances assigned to a phenylalanine residue with a chemical shift of 7.50 ppm appeared to move downfield to 7.82 ppm.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proton NMR studies of the biologically active 1-34 fragment of bovine parathyroid hormone: examination of a structural model

Proton NMR spectra of the biologically active 1-34 fragment of bovine parathyroid hormone (bPTH) were studied as a function of pH over the range of pH 4 to 10, in buffer and in 6 M guanidine DC1. One of the histidine C-2 peaks titrated normally, with a pKa value of 6.8, but the other two histidines in this peptide had pKa values of 6.3. Denatured PTH showed only one histidine C-2 peak with a pKa of 6.7. An aliphatic peak identified as due to either a methionine or a glutamine residue also shifted with pH, and the pKa for this shift was 6.3. Finally, small but significant upfield shifts in the methyl and methylene resonances were observed as a function of pH, and when compared to the denatured peptide. These results indicate that the N-terminal domain of native PTH has considerable structure in solution, and are consistent with a theoretical model for the folding of this peptide.     

Proton magnetic resonance studies of ribonuclease T1. Assignment of histidine-40 peak and analysis of the active site.

Nuclear magnetic resonances of the C-2 protons of the three histidine residues in ribonuclease T₁ have been studied at 360 MHz as a function of pH to discuss the structure of the active site. Comparison of the order of deuterium exchange of the histidine peaks with tritium incorporation rates into individual histidines of the enzyme leads to the unambigous assignment of one of the C-2 proton peaks to histidne-40. It has been concluded that histidine-40 is in the active site, interacting with a charged group of pK 4.1, which is replaced by the phosphate group of guanosine-3′-monophosphate in the enzyme-inhibitor complex. Histidine-92 is most likely a binding site for the complex, where the existence of a hydrogen bond between N-7 of the inhibitor and the ring NH proton of the histidine is suggested on the basis of NMR data.     

Proton magnetic resonance studies of histidines in human, rhesus monkey, and bovine carbonic anhydrases.

Histidine C-2 proton resonances in rhesus monkey carbonic anhydrase B (carbonate hydro-lyase, EC 4.2.1.1) and bovine carbonic anhydrase were investigated using 270-MHz proton magnetic resonance. The results suggest that there are extensive three-dimensional homologies between the human B and rhesus B enzymes and between the human C and bovine enzymes. Resonances from solvent exchangeable protons have been observed in the 11-16 ppm range in the NMR spectra of human carbonic anhydrases B and C and bovine carbonic anhydrase. Up to five of these are sensitive to changes of pH and the presence of inhibitors. Three of these resonances are assigned to NH protons of the metal coordinated imidazole groups. These results are discussed in relation to various models for the catalytic mechanism of carbonic anhydrase.     

A New Method for Purification of Carbonic Anhydrase Isozymes by Affinity Chromatography

A new affinity gel for purification of carbonic anhydrase isozymes was prepared using EUPERGIT C-250L derivatized with p-aminobenzenesulfonamide, an inhibitor of carbonic anhydrase. The binding capacity of the affinity gel was determined at different temperatures, pH values, elution buffers, and ionic strengths. Human carbonic anhydrase isozymes (HCA I and HCA II) and bovine carbonic anhydrase (BCA) were purified in high yields from erythrocytes.     

A study of the histidine residues of human carbonic anhydrase B using 270 MHz proton magnetic resonance

Nine resonances in the 270 MHz proton magnetic resonance spectrum of human carbonic anhydrase B have been identified with imidazole C₍₂₎ protons of histidine residues, six of which are observed to titrate with pK_a values in the range 4.7 to 7.4. The behaviour of the nine resonances has been studied in the presence of the inhibitors, iodide, cyanide, acetate, hexacyanochromate, and imidazole. Measurements have also been made of the enzyme in its apo, cobalt, and mono-alkylated forms. Used in conjunction with the crystal structure, these results have enabled the tentative assignment of all nine resonances to particular histidine residues in the amino-acid sequence. Three of the active-site histidines at positions 64, 67, and 200 have low pK_a values and cannot be directly linked to the activity of the enzyme. However, the resonances assigned to the three metal-liganding histidines do exhibit changes on anion binding and with pH, which parallel changes in the esterase activity. These results are consistent with the model of an ionizable water molecule bound to the zinc ion.Linewidth measurements of the resonances of the histidine residues on the enzyme surface are used to estimate pseudo-first-order rate constants of the order of 4 × 10³ s^?1 for D⁺ exchange between imidazole N and solvent in the absence of buffer. These rates are observed to increase in the presence of small amounts of the buffers Tris and imidazole.     

Assignment, by proton magnetic resonance, of histidines of dihydrofolate reductase from chicken liver

The effects of pH and temperature upon C epsilon 1 H resonances of the four histidyl residues of chicken liver dihydrofolate reductase in binary complex with methotrexate were studied by 500-MHz 1H NMR spectroscopy. The four histidines labelled a, b, c, d are distinguishable by their pK values and the chemical shifts of their C epsilon 1H protons. The local electromagnetic environment as deduced from X-ray studies at 2.9 A resolution was used as a basis for proposed assignment of the four histidines. The assignments were a: H42, b: H140, c: H131, d: H87. Furthermore the histidyl residue labelled c was shown to be upfield shifted in its C epsilon 1H proton in the enzyme-methotrexate complex compared to the native enzyme. The hypothesis of a conformational change of the protein is discussed.     

Nuclear magnetic resonance titration curves of histidine ring protons. Human metmyoglobin and the effects of azide on human, horse, and sperm whale metmyoglobins.

Four titrating histidine ring C2 and C4 proton resonances are observed in 220 MHz proton NMR spectra of human metmyoglobin as a function of pH. Values of ionization constants determined from the NMR titration data using an equation describing a simple proton association-dissociation equilibrium are curves (1) 6.6, (2) 7.0, (3) 5.8, and (4) 7.4. Four histidine residues have also been found to be solvent-accessible in human metmyoglobin by carboxymethylation studies (Harris, C.M., and Hill, R.L. (1969) J. Biol. Chem. 244, 2195-2203). Two of the titration curves (3 and 4) deviate significantly from the chemical shift values normally observed for histidine C2 proton resonances. Curve 3, with a low pKa, is shifted downfield at high values of pH and also exhibits a second minor inflection with a pKa value of 8.8. On the other hand, the high pKa curve, 4, is shifted upfield at all values of pH. The characteristics of the NMR titration curves with the lowest and highest pKa values (3 and4) are very similar to curves observed previously with sperm whale and horse metmyoglobins (Cohen, J.S., Hagenmaier, H., Pollard, H., and Schechter, A.N. (1972) J. Mol. Biol. 71, 513-519). These results indicate that the histidine residues from which these curves are derived have unusual and characteristic environments in this series of homologous proteins. The NMR spectra of all three metmyoglobins are changed extensively as a result of azide ion binding, indicating conformational changes affecting the environments of several imidazole side chains. The presence of azide ion causes a selective downfield chemical shift for the low pKa curve and a selective upfield chemical shift for the high pKa curve in all three proteins. Azide also abolishes the second inflection seen in the low pKa curve at high pH. In addition to these effects, the presence of azide ion permits the observation of two additional titrating proton resonances for all three metmyoglobins. Increasing the azide to protein ratio at several fixed values of pH yields results which show that a slow exchange process is occurring with each of the metmyoglobins. In the azide titration studies the maximum changes in the NMR spectra occurred at approximately equimolar concentrations. The NMR results for these proteins in the absence and presence of azide ion are related to x-ray crystallographic studies of sperm whale metmyoglobin and the known alkylation properties of the histidine residues. Tentative assignments of the titrating resonances observed are suggested.     

The interactions between nucleic acids and polyamines: I. High resolution carbon-13 and hydrogen-1 nuclear magnetic resonance studies of spermidine and 5'-AMP

In 0.5 M solution at pH 7.6, interaction of spermidine and 5'-AMP is demonstrated by downfield proton NMR shifts. Shifts of ribose and adenine protons support a model in which triprotonated spermidine engages the phosphate, anion with the C-3 diamine segment in a conformation to maximize interaction and the C-4 ammo segment extended to interact with adenine N-7 (base anti, 2'endo, g'g' and gg nucleoside conformation). Changes in carbon-13 chemical shifts for ribose C-5' (downfield), C-2' C-3', and C-4' (upfield) and for adenine C-6 and C-8 (upfield) support this model. In 0.006 M solution no significant changes in proton shifts and therefore no evidence for interaction was found. Spermidine and 5'-UMP (0.006 M) showed interaction at pH 10.5 (small upfield shifts in the proton nmr) interpreted as changing conformation by solvent interaction. In 0.006 M 3'-UMP at pH 10.5 small downfield proton shifts induced by spennidine are attributed to interactions with phosphate anion.     

Proton nuclear magnetic resonance studies of intact native bovine parathyroid hormone

Native intact bovine PTH was studied by proton nuclear magnetic resonance (NMR) techniques, at pH 3.5 and pH 6.3. The 1H-NMR spectra had good resolution and many multiplet structures were observed. Assignment of the NMR resonances corresponding to specific amino acids was approached using 1H chemical shifts, coupling constants, and pH dependence in the one-dimensional spectra and the 1H-1H connectivities revealed in two-dimensional homonuclear correlated spectroscopy (COSY) experiments. All the aromatic proton resonances were assigned. Two histidine residues had lower pK than the other two. The methyl groups of two residues were moved significantly downfield: using COSY and two-dimensional nuclear Overhauser enhancement spectroscopy (NOESY) correlations, these were assigned to an alanine residue close to both Trp-23 and Tyr-43, and a valine residue in close spatial proximity to Trp-23. The NOESY spectrum also showed cross-peaks between the residues of the upfield valine-leucine-isoleucine methyl envelope. Many of the H alpha protons moved upfield as the pH was increased. These results indicate that intact native PTH exists in a preferred conformation in solution at pH 6.5. Our studies have provided new information on the three-dimensional spatial proximity of several amino acids along the polypeptide chain. The observed interactions are consistent with the currently accepted model suggesting that the hormone has two separate structural domains associated with the amino- and carboxy-terminal regions of the molecule respectively. The potential implications of this model for the expression of biological activity are discussed.     

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.     

NMR studies of chromomycin A3 interaction with DNA

The binding of chromomycin A3 to calf thymus DNA and poly(dG-dC) has been studied by 13C and 1H NMR with emphasis on the mode of binding, the role of Mg2+, and pH effects. The most prominent changes in the DNA base pair 13C NMR resonances upon complexation with chromomycin were observed for G and C bases, consistent with the G-C preference exhibited by this compound. Comparison of the 13C spectrum of DNA-bound chromomycin A3 with that of DNA-bound actinomycin D, a known intercalator, showed many similarities in the base pair resonances. This suggested the possibility that chromomycin A3 binds via an intercalative mechanism. 1H NMR studies in the imino proton, low-field region of the spectrum provided additional evidence in support of this binding mode. In the low-field spectrum of chromomycin A3 bound to calf thymus DNA, a small shoulder was observed on the upfield side of the G-C imino proton peak. Similarly, in the chromomycin A3 complex with poly(dG-dC), a well-resolved peak was found upfield from the G-C imino proton peak. These results are expected for ligands that bind by intercalation. Furthermore, in both the calf thymus and poly(dG-dC) drug complexes (in the presence of Mg2+) a broad peak was also present downfield (approximately 16 ppm from TSP) from the DNA imino protons. This was attributed to the C-9 phenolic hydroxyl proton on the chromomycin chromophore. Visible absorbance spectra at different pH values showed that the role of Mg2+ in the binding of chromomycin A3 to DNA is more than simple neutralization of the drug's anionic change.     

Magnetic resonance study of exchangeable protons in human carbonic anhydrases.

A titratable exchangeable proton resonance assignable to a histidine imidazole ring N--H proton is observed approximately minus 15 ppm downfield from tetramethylsilane. The chemical shift of this resonance is affected by sulfonamide and anion inhibitors, and by removal of zinc or replacement of zinc by cobalt, indicating that the proton is located at or near the active site. The pH dependence of the chemical shift of this resonance, which is abolished by inhibitors, reflects the titration of a group with a pK-a of 7.3 in human carbonic anhydrase B and smaller than or equal to 7.1 in human carbonic anhydrase C. These pK-a values are interpreted to be due to the ionization of a neutral imidazole to form the imidazolate anion coordinated to zinc. A mechanism for enzymatic catalysis involving reversible deprotonation and coordination of a histidine to the metal is consistent with these studies.     

Proton nuclear magnetic resonance spectra of Pseudomonas aeruginosa ferricytochrome cd1

Proton nuclear magnetic resonance spectra of ferricytochrome cd1 from the denitrifying bacterium Pseudomonas aeruginosa have been obtained. The normal 0-10-ppm chemical shift range shows many overlapping and nonresolvable peaks, as would be expected for a dimeric protein of molecular weight approximately 120,000. In the downfield region between 10 and 50 ppm, and in the upfield region between 0 and -20 ppm, resolvable resonances corresponding to a small number of protons are observed. The temperature and pH behavior of these resonances have been examined. For some of the resolved resonances, the pH behavior of chemical shifts and intensities indicates that the oxidized form of the enzyme undergoes a structural transition with a pK of 5.8 +/- 0.3. On the basis of several lines of evidence, some assignments are proposed in which resolvable resonances are assigned as originating from either the heme c or the heme d1 prosthetic groups of the enzyme.     

Studies of the histidine residues of human and bovine glycoprotein hormones by nuclear magnetic resonance

Titration curves of the histidine residues in lutropin, thyrotropin, follitropin and chorionic gonadotropin have been assigned using imidazole C-2 proton nuclear magnetic resonance spectra and their estimated pK values determined. Spectra of reassociated hormone preparations, in which one or the other of their two subunits (alpha or beta) have had their accessible histidines exchanged with deuterium, permitted assignment of C-2 resonance to specific residues. Similar titration curves were found for residues which are conserved from one hormone to another. However, these conserved histidines do not have identical pK values, indicating that differences in the conformation or microenvironment around these residues occur in these hormones. Changes in some pK values also occur as a function of subunit association. The most dramatic change seen in all cases is the exposure to solvent of histidine alpha-83; in isolated alpha subunits this residue is unavailable for titration over a wide pH range. This change appears to be a general consequence of the association of the two subunits in any of these hormones. The data show that all histidines in the intact hormones are accessible to the environment, including those proposed to be in domains involved in subunit-subunit interaction.     

A comparison by 220-MHz NMR of histidine hydronium ion titrations in porcine pancreatic ribonuclease and an extensively deglycosylated derivative.

220-MHz NMR was used to observe the titration behavior of the 5 histidine residues in porcine pancreatic ribonuclease (ribonucleate pyrimidine-nucleotido-2'-transferase (cyclizing), EC 3.1.4.22) and a derivative prepared by removal of 80% of the attached carbohydrate from this glycoprotein. Resonances due to histidine C-2 protons were observed over the full pH range for 3 of the residues; such resonances for the remaining 2 histidine residues broadened out as the pH was increased. Resonances due to histidine C-4 protons were also observed for 2 of the residues. The titration curves for both proteins were identical within experimental error. Resonances were assigned by comparison with histidine NMR titrations in ribonucleases from other species. Histidine 105, immediately adjacent to the site of attachment of a heterosaccharide side chain, has a C-2 proton chemical shift and pK that are insensitive to the large alteration in the bulk of the carbohydrate side chain. The chemical shifts of the C-2 proton of histidine 48 and of the C-4 proton of histidine 80, histidine residues that are close to one another and to another heterosaccharide side chain, show a similar insensitivity. The observations are direct evidence in support of the thesis that the heterosaccharides in porcine ribonuclease project away from the surface of the protein into the solution environment.