Coupling of drug protonation to the specific binding of aminoglycosides to the A site of 16 S rRNA: elucidation of the number of drug amino groups involved and their identities

2-Deoxystreptamine (2-DOS) aminoglycoside antibiotics bind specifically to the central region of the 16S rRNA A site and interfere with protein synthesis. Recently, we have shown that the binding of 2-DOS aminoglycosides to an A site model RNA oligonucleotide is linked to the protonation of drug amino groups. Here, we extend these studies to define the number of amino groups involved as well as their identities. Specifically, we use pH-dependent 15N NMR spectroscopy to determine the pK(a) values of the amino groups in neomycin B, paromomycin I, and lividomycin A sulfate, with the resulting pK(a) values ranging from 6.92 to 9.51. For each drug, the 3-amino group was associated with the lowest pK(a), with this value being 6.92 in neomycin B, 7.07 in paromomycin I, and 7.24 in lividomycin A. In addition, we use buffer-dependent isothermal titration calorimetry (ITC) to determine the number of protons linked to the complexation of the three drugs with the A site model RNA oligomer at pH 5.5, 8.8, or 9.0. At pH 5.5, the binding of the three drugs to the host RNA is independent of drug protonation effects. By contrast, at pH 9.0, the RNA binding of paromomycin I and neomycin B is coupled to the uptake of 3.25 and 3.80 protons, respectively, with the RNA binding of lividomycin A at pH 8.8 being coupled to the uptake of 3.25 protons. A comparison of these values with the protonation states of the drugs predicted by our NMR-derived pK(a) values allows us to identify the specific drug amino groups whose protonation is linked to complexation with the host RNA. These determinations reveal that the binding of lividomycin A to the host RNA is coupled to the protonation of all five of its amino groups, with the RNA binding of paromomycin I and neomycin B being linked to the protonation of four and at least five amino groups, respectively. For paromomycin I, the protonation reactions involve the 1-, 3-, 2'-, and 2"'-amino groups, while, for neomycin B, the binding-linked protonation reactions involve at least the 1-, 3-, 2', 6'-, and 2"'-amino groups. Our results clearly identify drug protonation reactions as important thermodynamic participants in the specific binding of 2-DOS aminoglycosides to the A site of 16S rRNA.     

Isolation, purification and 13C- and 1H-n.m.r. assignments of peptide [1-24] of human serum albumin

Isolation, purification and 360 MHz 1H- and 13C-n.m.r. spectra of the residue corresponding to the NH2-terminal peptide fragment [1-24] of human serum albumin are reported. The various resonances have been assigned to individual amino acid residues and their spatial microenvironment has been determined in a straightforward manner on the basis of (i) pH dependent chemical shifts; (ii) combined use of multiple and selective proton-decoupled 1H- and 13C-n.m.r. spectra; (iii) the characteristic pK values exhibited by protons adjacent to sites of ionization in the molecule; and (iv) comparison of the spectra with the NH2-terminal tripeptide segment of human albumin. The pK values of different ionizable groups all fall in the normal range expected for each titrating sites and support a model of peptide fragment [1-24] in which there is no special structure-forming strong associations. These results are in agreement with those obtained by CD spectroscopy.     

15N-enriched 5-fluorocytosine as a probe for examining unusual DNA structures

A new method is presented for the synthesis of oligonucleotides containing 15N-enriched 5-fluorocytosine (FC). Due to the reduced pK of FC, the amino protons of an unpaired FC residue may be observed at lower values of solution pH. The labeled FC residue has been placed as a template base at a model DNA replication fork. The amino protons of the FC residue have been identified in isotope-edited NMR spectra. Data is presented for a template FC residue unpaired, paired with guanine, and mispaired with adenine. These studies demonstrate the utility of labeled FC in examining unusual DNA structures.     

Proton magnetic resonance studies of carbonic anhydrase. I. Identification of histidine resonances.

Nuclear magnetic resonance (nmr) spectra of human carbonic anhydrase B recorded in deuterium oxide reveal seven discrete single proton resonances between 7 and 9 ppm downfield from sodium 2,2-dimethyl-i-silapentane-5-sulfonate. Simplification of spectra by use of Fremy's salt, comparison of peak widths at intersections, and evaluation of the results of inhibition and modification experiments permit determination of the pH dependencies of these resonances. Five of these peaks change position with increasing pH; three move upfield by approximately 95 Hz and two move downfield by 10 and 23 Hz. The first three reflect residues with pK values of 7.23, 6.98, and 6 and can be assigned to the C-2 protons of histidines. The two remaining pH dependent resonances reflect groups with pK values of 8.2 and 8.24. Their line widths and T1 values are comparable to those of the first group, and they also appear to reflect C-H protons of histidines. Despite the structural and functional similarities of the B and C isozymes of human carbonic anhydrase, few of the low field resonances appear to be common to both. Six histidine C-2 protons are observed in the C enzyme and reflect groups with pK values of approximately 7.3, 6.5, 5.7, 6.6, 6.6, and 6.4. A seventh peak contains two protons and moves upfield with increasing pH without titrating. A final resonance to low field moves downfield with increasing pH and reflects a group with a pK between 6 and 7. Its behavior resembles that of peak 1 of the human B enzyme, and it also appears to be a histidine C-H proton. This peak may reflect a conserved residue in the two isozymes that plays an important role in enzymatic function, as discussed in the following paper.     

Assignment of aromatic resonances in the 1H nuclear magnetic resonance spectra of cardioactive polypeptides from sea anemones

High-resolution 1H NMR spectroscopy at 300 MHz has been used to investigate the aromatic residues of a series of homologous polypeptides from sea anemones: anthopleurin-A from Anthopleura xanthogrammica and toxins I and II from Anemonia sulcata. Using two-dimensional NMR techniques, specific assignments to individual protons have been made for all aromatic resonances in the spectra of these molecules. In all three polypeptides the resonances from the two conserved Trp residues, 23 and 33, are shifted significantly from their random coil values, and the indole NH resonance of Trp-23 is not observed. These shift perturbations are due in part to a mutual interaction of the two indole rings, which is also indicated by the observation of nuclear Overhauser enhancements between protons of the two rings. Several other nonpolar side chains also interact with these two Trp residues, forming a hydrophobic region, the overall structure of which is conserved throughout the series. The other aromatic residues in these polypeptides appear not to participate in this structural region.     

Complete thermodynamic characterization of the multiple protonation equilibria of the aminoglycoside antibiotic paromomycin: a calorimetric and natural abundance 15N NMR study

The binding of aminoglycoside antibiotics to a broad range of macromolecular targets is coupled to protonation of one or more of the amino groups that typify this class of drugs. Determining how and to what extent this linkage influences the energetics of the aminoglycoside-macromolecule binding reaction requires a detailed understanding of the thermodynamics associated with the protonation equilibria of the aminoglycoside amino groups. In recognition of this need, a calorimetric- and NMR-based approach for obtaining the requisite thermodynamic information is presented using paromomycin as the model aminoglycoside. Temperature- and pH-dependent 15N NMR studies provide pK(a) values for the five paromomycin amino groups, as well as the temperature dependence of these pK(a) values. These studies also indicate that the observed pK(a) values associated with the free base form of paromomycin are lower in magnitude than the corresponding values associated with the sulfate salt form of the drug. This difference in pK(a) is due to drug interactions with the sulfate counterions at the high drug concentrations (> or = 812 mM) used in the 15N NMR studies. Isothermal titration calorimetry studies conducted at drug concentrations < or = 45 microM reveal that the extent of paromomycin protonation linked to the binding of the drug to its pharmacologically relevant target, the 16 S rRNA A-site, is consistent with the pK(a) values of the free base and not the sulfate salt form of the drug. Temperature- and pH-dependent isothermal titration calorimetry studies yield exothermic enthalpy changes (deltaH) for protonation of the five paromomycin amino groups, as well as positive heat capacity changes (deltaC(p)) for three of the five amino groups. Regarded as a whole, the results presented here represent an important first step toward establishing a thermodynamic database that can be used to predict how aminoglycoside-macromolecule binding energetics will be influenced by conditions such as temperature, pH, and ionic strength. Such a predictive capability is a critical component of any drug design strategy.     

15N-Enriched 5-Fluorocytosine as a Probe for Examining Unusual DNA Structures

Abstract

A new method is presented for the synthesis of oligonucleotides containing ¹⁵N-enriched 5- fluorocytosine (FC). Due to the reduced pK of FC, the amino protons of an unpaired FC residue may be observed at lower values of solution pH. The labeled FC residue has been placed as a template base at a model DNA replication fork. The amino protons of the FC residue have been identified in isotope-edited NMR spectra. Data is presented for a template FC residue unpaired, paired with guanine, and mispaired with adenine. These studies demonstrate the utility of labeled FC in examining unusual DNA structures.     

The uptake of protons by heme-linked ionizable groups on azide binding to methemoglobin

When azide ion reacts with methemoglobin in unbuffered solution the pH of the solution increases. This phenomenon is associated with increases in the pK values of heme-linked ionizable groups on the protein which give rise to an uptake of protons from solution. We have determined as a functional of pH the proton uptake, delta h+, on azide binding to methemoglobin at 20 degrees C. Data for methemoglobins A (human), guinea pig and pigeon are fitted to a theoretical expression based on the electrostatic effect of these sets of heme-linked ionizable groups on the binding of the ligand. From these fits the pK values of heme-linked ionizable groups are obtained for liganded and unliganded methemoglobins. In unliganded methemoglobin pK1, which is associated with carboxylic acid groups, ranges between 4.0 and 5.5 for the three methemoglobins; pK2, which is associated with histidines and terminal amino groups, ranges from 6.2 to 6.7. In liganded methemoglobin pK1 lies between 5.8 and 6.3 and pK2 varies from 8.1 to 8.5. The pH dependences of the apparent equilibrium constants for azide binding to the three methemoglobins at 20 degrees C are well accounted for with the pK values calculated from the variation of delta h+ with pH.     

Nuclear magnetic resonance studies on the spatial relationship of aromatic donor molecules to the heme iron of horseradish peroxidase

The geometry of hydrogen donor molecules bound to horseradish peroxidase was investigated using nuclear magnetic resonance techniques. Between resorcinol and 2-methoxy-4-methylphenol which showed different optical difference spectra, little difference was observed in the orientation of the molecules bound to horseradish peroxidase: the minimal distances between the enzyme iron and the protons of the phenol rings are in the range of 8.4-11.0 A. This situation was not greatly different for the third compound studied in this paper, benzhydroxamic acid, providing evidence against the view that its side chain coordinates to the heme iron. Furthermore, it was found that transferred nuclear Overhauser effect for the signals of these compounds was observable only when the heme peripheral 8-methyl proton signal was irradiated. These results, together with a hypothetical model of the enzyme structure obtained by computer-aided simulation procedures, suggest that the binding of these donor molecules and competitive inhibitors occur in the vicinity of the heme peripheral 8-methyl group, with hydrophobic interactions probably with Tyr-185 and with hydrogen bond with adjacent amino acid residues such as Arg-183.     

`Rapidly Appearing' molybdenum electron-paramagnetic-resonance signals from reduced xanthine oxidase

Further electron-paramagnetic-resonance studies relating to the role of molybdenum in the enzymic mechanisms of xanthine oxidase were carried out. The classification of the various molybdenum signals obtained on reducing the enzyme is briefly discussed. The group of `Rapidly appearing'' signals, which are obtained with all substrates within the turnover time and which show interaction with exchangeable protons, were studied in detail. Signals with salicylaldehyde, purine and xanthine in H₂O and in 95% D₂O were examined at 9 and 35GHz and interpreted with the help of computer simulation. Molybdenum atoms in a number of different chemical environments are involved, each substrate giving rise to two superimposed spectra with slightly different parameters; g values and proton splittings were determined. The spectrum with salicylaldehyde is believed to represent the reduced enzyme alone not in the form of a complex with substrate and its two constituents are believed to represent the two molybdenum atoms bonded slightly differently within the enzyme molecule. With purine and xanthine the spectra are thought to represent complexes of reduced enzyme with substrate molecules. With xanthine one signal-giving species shows coupling to two equivalent protons, whereas in all the other species observed two non-equivalent protons are involved. The origin of the protons is discussed in the light of the direct hydrogen-transfer mechanism implicated earlier for the enzyme. It is concluded that the proton derived from the substrate is located at least 3å from the molybdenum atom with which it interacts.     

Titration of E. coli transhydrogenase domain III with bound NADP+ or NADPH studied by NMR reveals no pH-dependent conformational change in the physiological pH range

A pH-titration 2D NMR study of Escherichia coli transhydrogenase domain III with bound NADP(+) or NADPH has been carried out, in which the pH was varied between 5.4 and 12. In this analysis, individual amide protons served as reporter groups. The apparent pK(a) values of the amide protons, determined from the pH-dependent chemical shift changes, were attributed to actual pK(a) values for several titrating residues in the protein. The essential Asp392 is shown to be protonated at neutral pH in both the NADP(+) and NADPH forms of domain III, but with a marked difference in pK(a) not only attributable to the charge difference between the substrates. Titrating residues found in loop D/alpha5 point to a conformational difference of these structural elements that is redox-dependent, but not pH dependent. The observed apparent pK(a) values of these residues are discussed in relation to the crystal structure of Rhodospirillum rubrum domain III, the solution structure of E. coli domain III and the mechanism of intact proton-translocating transhydrogenase.     

Structure and dynamics in solution of the complex of Lactobacillus casei dihydrofolate reductase with the new lipophilic antifolate drug trimetrexate

We have determined the three-dimensional solution structure of the complex of Lactobacillus casei dihydrofolate reductase and the anticancer drug trimetrexate. Two thousand seventy distance, 345 dihedral angle, and 144 hydrogen bond restraints were obtained from analysis of multidimensional NMR spectra recorded for complexes containing 15N-labeled protein. Simulated annealing calculations produced a family of 22 structures fully consistent with the constraints. Several intermolecular protein-ligand NOEs were obtained by using a novel approach monitoring temperature effects of NOE signals resulting from dynamic processes in the bound ligand. At low temperature (5 degrees C) the trimethoxy ring of bound trimetrexate is flipping sufficiently slowly to give narrow signals in slow exchange, which give good NOE cross peaks. At higher temperature these broaden and their NOE cross peaks disappear thus allowing the signals in the lower-temperature spectrum to be identified as NOEs involving ligand protons. The binding site for trimetrexate is well defined and this was compared with the binding sites in related complexes formed with methotrexate and trimethoprim. No major conformational differences were detected between the different complexes. The 2,4-diaminopyrimidine-containing moieties in the three drugs bind essentially in the same binding pocket and the remaining parts of their molecules adapt their conformations such that they can make effective van der Waals interactions with essentially the same set of hydrophobic amino acids, the side-chain orientations and local conformations of which are not greatly changed in the different complexes (similar chi1 and chi2 values).     

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.     

Spectra and structure of complexes formed by sodium fusidate and potassium helvolate with beta- and gamma-cyclodextrin

The complexation of two steroid antibiotics of the fusidane family, sodium fusidate and potassium helvolate, by beta-CD and gamma-CD has been studied by using 1D and 2D-NMR techniques. Both guests form 1:1 complexes with gamma-CD and 1:2 (guest:cyclodextrin) complexes with beta-CD. Thus, both antibiotics behave as monotopic and ditopic guests when they are complexed by gamma-CD and beta-CD, respectively. Both steroids enter into the cavity of the gamma-CD by the side chain, reaching the central region of the steroid (rings C and D), whereas the A and B (partially) rings remain outside. For beta-CD complexes, ROESY spectra show a remarkable absence of interactions of the protons of the C and D rings, whereas clear interactions corresponding to the side chain, and A and B rings are observed. The obtained equilibrium constants (see previous paper) are discussed in terms of the structures proposed for the complexes. NMR spectra of sodium fusidate are revised, and a full assignment of the 1H and 13C NMR spectra is presented for potassium helvolate.     

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.     

Characteristics of azurin from Pseudomonas aeruginosa via 270-MHz 1H nuclear magnetic resonance spectroscopy.

Assignments of resonances in the 1H nmr spectra of Cu(I) azurin to proton groups in the protein are discussed in detail. Comparisons are drawn between Cu(I), Cu(II), apo, Hg(II), and Co(II) azurin samples. Redox titration of Cu(I) azurin with K3Fe(CN)6, is used to correlate Cu(I) and Cu(II) 1H nmr spectral features, and observed line broadenings deriving from Cu(II) paramagnetic effects are used to deduce the distances of assigned proton groups from the copper center. Histidine residues are characterized in terms of pK values, rates of acid-base exchange near the the pK, and rates of C2H exchange with solvent deuterium. The possibility of histidine involvement in the azurincytochrome 551 electron exchange mechanism is discussed. A small number of NH protons observed to be distinctively inert to 2H exchange with solvent 2H2O, in the Cu(I) protein, are found to show increased lability on removal of the metal.     

Insensitivity of perturbed carboxyl pK(a) values in the ovomucoid third domain to charge replacement at a neighboring residue

A number of carboxyl groups in turkey ovomucoid third domain (OMTKY3) have low pK(a) values. A previous study suggested that neighboring amino groups were primarily responsible for the low carboxyl pK(a) values. However, the expected elevation in pK(a) values for these amino groups was not observed. In the present study, site-directed mutagenesis is used to investigate the origins of perturbed carboxyl pK(a) values in OMTKY3. Electrostatic calculations suggest that Lys 34 has large effects, 0.4-0.6 unit, on Asp 7, Glu 10, and Glu 19 which are 5-11 A away from Lys 34. Two-dimensional (1)H NMR techniques were used to determine pK(a) values of the acidic residues in OMTKY3 mutants in which Lys 34 has been replaced with threonine and glutamine. Surprisingly, the pK(a) values in the mutants are very close to those of the wild-type protein. The insensitivity of the acidic residues to replacement of Lys 34 suggests that long-range electrostatic interactions play less of a role in perturbing carboxyl pK(a) values than originally thought. We hypothesize that hydrogen bonds play a key role in perturbing some of the carboxyl ionization equilibria in OMTKY3.     

The phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus aureus. Complete tyrosine assignments in the 1H nuclear-magnetic-resonance spectrum of the phosphocarrier protein HPr.

Upon nitration of the phosphocarrier protein HPr three nitrated derivatives of the protein were isolated: mononitrated HPr, dinitrated HPr and trinitrated HPr. Tryptic digestion of the derivatives leads to nitrotyrosine-containing peptides which were isolated and characterized by amino acid analysis. This resulted in the determination of the positions of the nitrated tyrosyl residues in the amino acid sequence. In mononitrated HPr only Tyr-56 was modified, in dinitrated HPr both Tyr-56 and Tyr-37 had reacted with the nitrating agent; modification of all three tyrosyl residues in trinitrated HPr required more drastic reaction conditions. The nuclear magnetic resonance spectra of the three derivatives allowed the assignments of the tyrosine resonances as follows: Tyr-A and Tyr-B with pK values of 10.5 and 11.5 were designated Tyr-56 and Tyr-37 whereas Tyr-C, whose protons are not titratable before denaturation of the protein, was assigned to Tyr-6 in the amino acid sequence. The nitration studies, together with the titration behaviour of the three tyrosines, indicate the topology of the tyrosyl residues to be as follows: Tyr-56 is located at the surface, Tyr-37 is slightly buried, Tyr-6 is deeply buried. The nitrotyrosyl derivatives retain their biological activity.     

Selective detection of rapid motions in spectrin by NMR

Human erythrocyte spectrin molecules exhibit relatively sharp (30-50 Hz) proton NMR signals in the aliphatic region. A standard solvent presaturation pulse sequence that also partially suppresses the broad envelope from protons with rigid structures in spectrin and selectively enhances the sharp resonances has been used to characterize the behavior of these resonances. The overall resonance pattern strongly resembles that of the denatured spectrin. The observed spectra are also quite similar to the line-broadened spectrum from a mixture of amino acids that corresponds to the composition of the spectrin molecule. These data indicate the existence of regions exhibiting rapid internal motions within the intact spectrin molecule, and suggest that the amino acid composition of the residues giving rise to the sharp resonances is quite similar to that of the full spectrin molecule.     

Discrete charge calculations of potentiometric titrations for globular proteins: sperm whale myoglobin, hemoglobin alpha chain, cytochrome c.

The modified Tanford-Kirkwood theory of Shire et al. for intramolecular electrostatic interactions has been applied to hydrogen ion equilibria of sperm whale ferrimyoglobin, human hemoglobin α-chain and horse cytochrome c. The model employs two sets of parameters derived from the crystalline protein structures, first, the atomic coordinates of charged amino acid residues and, second, static accessibility factors to reflect their solvent exposure. In addition, a consistent set of intrinsic pK values (pK_int) for the individual groups is employed. The theoretical pK values at half-titration for individual groups in each protein correspond to the available observed pK values, and the theoretical titration curves compare closely with experimental potentiometric curves.