The phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus aureus. 3. 1H and 31P nuclear-magnetic-resonance studies on the phosphocarrier protein HPr; tyrosine titration and denaturation studies.

The phosphocarrier protein HPr has been investigated by proton nuclear magnetic resonance (NMR) at 270 MHz in order to evaluate structural properties of the whole molecule and its active site. The titration behaviour of the three tyrosines of the HPr protein was analysed by monitoring the chemical shifts of the aromatic proton resonances of these residues as a function of pH. It was found that the HPr protein contains a lot of slowly exchanging NH backbone protons which suggested a relatively rigid secondary structure of the protein molecule itself although it contains no disulfide bridges. The HPr protein shows a sharp reversible denaturation behaviour at alkaline pH values. Between pH 10.8 and 11.1 two C-2 proton resonance peaks for the single histidine residue could be observed together with abrupt changes in the aromatic and aliphatic absorption region of the HPr protein which are due to chemical exchange processes. The NMR spectrum of the HPr protein is only changed a little upon raising the temperature from 14 degrees C to 70 degrees C. At 76 degrees C all resonances in the spectrum broaden and almost disappear. This process is irreversible.     

Proton nuclear magnetic resonance studies on glutamine-binding protein from Escherichia coli. Formation of intermolecular and intramolecular hydrogen bonds upon ligand binding

Proton nuclear magnetic resonance studies have revealed several structural and dynamic properties of the glutamine-binding protein of Escherichia coli. When this protein binds L-glutamine, six low-field, exchangeable proton resonances appear in the region from +5.5 to +10 parts per million downfield from water (or +10.2 to +14.7 parts per million downfield from the methyl proton resonance of 2,2-dimethyl-2-silapentane-5-sulfonate). This suggests that the binding of L-glutamine induces specific conformational changes in the protein molecule, involving the formation of intermolecular and intramolecular hydrogen bonds between the glutamine-binding protein and L-glutamine, and within the protein molecule. The oxygen atom of the gamma-carbonyl group of L-glutamine is likely to be involved in the formation of an intermolecular hydrogen bond between the ligand and the binding protein. We have shown that at least one phenylalanine and one methyl-containing residue are spatially close to this intermolecular hydrogen-bonded proton. The intermolecular and intramolecular hydrogen-bonded protons of the ligand-protein complex undergo solvent exchange. The local conformations around these intermolecular and intramolecular hydrogen bonds are quite stable when subjected to pH and temperature variations. From these results, the utility of proton nuclear magnetic resonance spectroscopy for investigating such binding proteins has been shown, and a picture of the ligand-binding process can be drawn.     

Studies on the role and mode of operation of the very-lysine-rich histone H1 in eukaryote chromatin. The isolation of the globular and non-globular regions of the histone H1 molecule.

Digestion of calf thymus H1 histone with thrombin cleaves the molecule at the sequence -(Pro)-Lys-Lys-Ala-, corresponding to a point approximately 122 residues from the N-terminus (about 56% along the molecule). The N-terminal fragment is shown by proton nuclear magnetic resonance (NMR) to possess the globular structure of the intact histome H1 molecule, whereas the C-terminal fragment appears to possess little or no structure. The N-terminal fragment separates into two peaks on an ion-exchange column, one of which is shown to originate from a single subfraction of calf thymus histone H1 and the other to originate from the other subfractions, by detailed comparison of the NMR spectra. It thus seems that the structure of the H1 histone in solution under physiological conditions consists of a globular head with a highly basic random coil tail. It is suggested that the globular head has a specific binding site on the subunit structure of the chromosome.     

Characterization of the oligosaccharide alditols from ovarian cyst mucin glycoproteins of blood group A using high pressure liquid chromatography (HPLC) and high field 1H NMR spectroscopy

A combination of reverse phase and normal phase high pressure liquid chromatography has been used to separate the reduced oligosaccharides produced by alkaline borohydride degradation of a blood group A ovarian cyst mucin glycoproteins. Fourteen compounds, ranging in size from a monosaccharide to a decasaccharide, have been isolated preparatively using a Zorbax C-18 reverse phase column eluted with water and a MicroPak AX-5 normal phase column eluted with aqueous acetonitrile. The purity of the products and their structures were determined from the fully assigned high field proton NMR spectra. The resonances of exchangeable amide protons, observed by the Redfield selective pulse sequence in H2O, were assigned by decoupling to the resonances of H2 of the 2-acetamido sugars. Nuclear Overhauser effects were used to establish the relationship of the anomeric protons and those of the aglycone. In exception to earlier proposals that nuclear Overhauser effect on irradiation of the anomeric proton should always be observed at the proton attached to the aglycone carbon, we find that for the linkage of GalNAcp(1----3)Gal, nuclear Overhauser effect on irradiation of the alpha-anomeric proton resonance is observed not at H3 but at H4 of galactose. A combination of NMR methods and enzymatic degradation was employed to determine the structures of 13 different oligosaccharides of which seven have not previously been reported. These oligosaccharides, which terminate with beta-Gal, alpha-Fuc, beta-GlcNAc, and alpha-GalNAc, account for 75% of the total glycoprotein carbohydrate, the remainder being isolated as a mixture of glycopeptides and a high molecular weight polysaccharide whose NMR spectrum implies a simple repeating subunit structure closely related to that of the oligosaccharides.     

Effect of pH on the oxidase activity of ceruloplasmin

The effect of pH on the kinetic parameters (Kms, Vs) of the reaction of adrenaline and Fe(II) (More's salt) oxidation by ceruloplasmin isolated from human donor blood was investigated. It was assumed that the imidazole group of histidine is functionally important for the above reactions. For Fe(II) the effect of the ionizeable group was observed during substrate binding to the ceruloplasmin molecule, whereas in the course of the adrenaline oxidation reaction it manifests itself during catalytic interaction of the substrate with the enzyme. The organic substrate can bind both to the protonated and to the non-protonated form of the enzyme. Fe(II) interacts only with the protonated form of the protein. In both cases, the rate-limiting step of the oxidase reaction is preceded by a single step, i.e., proton binding. The schemes describing the order of proton attachment in the course of the above reactions are proposed.     

Study of the interaction between uncharged yeast tRNAPhe and elongation factor Tu from Bacillus stearothermophilis

Proton NMR studies are presented on the interaction of nonaminoacylated yeast tRNAPhe and elongation factor Tu X GTP from Bacillus stearothermophilis. From experiments in which transfer of magnetization is observed between proton spins of tRNA and the protein, it is concluded that complex formation takes place. Amino acid residues of the protein come into close contact with the base pair A5U68 and/or U52A62 of the acceptor T psi C limb of the tRNA molecule. From the line broadening of tRNA resonances, associated with complex formation, an association constant of 10(3)-10(4) M-1 is estimated. The NMR experiments do not monitor a significant conformational change of the tRNA molecule upon interaction with the protein. However, at times long after the onset of complex formation, spectral changes indicate that the upper part of the acceptor helix becomes distorted.     

Structural determination of biomolecular interfaces by nuclear magnetic resonance of proteins with reduced proton density

Protein interactions are important for understanding many molecular mechanisms underlying cellular processes. So far, interfaces between interacting proteins have been characterized by NMR spectroscopy mostly by using chemical shift perturbations and cross-saturation via intermolecular cross-relaxation. Although powerful, these techniques cannot provide unambiguous estimates of intermolecular distances between interacting proteins. Here, we present an alternative approach, called REDSPRINT (REDduced/Standard PRoton density INTerface identification), to map protein interfaces with greater accuracy by using multiple NMR probes. Our approach is based on monitoring the cross-relaxation from a source protein (or from an arbitrary ligand that need not be a protein) with high proton density to a target protein (or other biomolecule) with low proton density by using isotope-filtered nuclear Overhauser spectroscopy (NOESY). This methodology uses different isotropic labeling for the source and target proteins to identify the source-target interface and also determine the proton density of the source protein at the interface for protein-protein or protein-ligand docking. Simulation indicates significant gains in sensitivity because of the resultant relaxation properties, and the utility of this technique, including a method for direct determination of the protein interface, is demonstrated for two different protein–protein complexes.     

Ruthenium-iron hybrid hemoglobins as a model for partially liganded hemoglobin: NMR studies of their tertiary and quaternary structures

Diruthenium-substituted Ru-Fe hybrid hemoglobins (Hb) were synthesized by heme substitution from protoheme to ruthenium (II) carbonyldeuteroporphyrin in the alpha or beta subunits. As the carbon monoxide coordinated to ruthenium (II) is not released under physiological conditions, deoxygenated Ru-Fe hybrid derivatives [alpha(Fe)2 beta(Ru-CO)2 and alpha(Ru-CO)2 beta(Fe)2] can serve as models for half-liganded Hbs. On the basis of proton NMR spectra of hyperfine-shifted proton resonances, these Ru-Fe hybrid Hbs have only small structural changes in the heme environment of the partner subunits at low pH. The proton NMR spectra of the intersubunit hydrogen-bonded protons also showed that the quaternary structures of the two complementary hybrids both remain in the "T-like state" at low pH, suggesting that the T to R structural conversion is induced by ligation of the third ligand molecule. Marked conformational changes in the heme vicinity are observed at high pH only for alpha(Ru-CO)2 beta(Fe)2, and its quaternary structure is converted into the "R state"; the alpha(Fe)2 beta(Ru-CO)2 hybrid does not undergo this change. This implies that the free-energy difference between the two quaternary states is smaller in the alpha-liganded hybrid than in the beta-liganded one.     

Stereospecific synthesis and two-dimensional 1H-NMR investigation of isoursocholic acid.

This report describes the chemical synthesis of isoursocholic acid (3 beta, 7 beta, 12 alpha-trihydroxy-5 beta-cholanoic acid) from its corresponding 3 alpha-analog. The method consists of refluxing a mixture of ursocholic acid, triphenylphosphine, and diethyl azodicarboxylate in benzene solution with an acid such as formic acid. The sterically pure ester (3 beta-formate) so formed after saponification with LiOH-aqueous methanol then allowed an easy access to the epimer of the starting acid. Large scale preparative separation and purification of the final product and synthetic intermediates were accomplished by flash column chromatography of their methyl ester derivatives. Structural assignment of the isourscholic acid molecule was confirmed by complete analysis of proton NMR spectra using 2-D NMR correlation experiments which rigorously established the (3 beta/3 alpha) and (7 beta/7 alpha) hydroxyl configurations in the isoursocholic and ursocholic acids. It is suggested that the isoursocholic acid will be useful as a reference compound and as a substrate in studies dealing with the hepatic inversion of the 3 beta-hydroxy group.     

The interaction of the trp repressor from Escherichia coli with L-tryptophan and indole propanoic acid

The binding of the corepressor, L-tryptophan, and an inducer, indole propanoic acid, to the trp repressor from Escherichia coli was studied by absorbance, fluorescence, circular dichroic and proton NMR spectroscopy. The two ligands bind to the same site on the repressor in the same orientation; they are molecular competitors. The binding site is of relatively low polarity and contains at least one methyl group that lies 0.3 nm over the indole moiety near the C5 proton of the bound ligand, and an aromatic residue, probably tyrosine. The dissociation constant was determined as a function of temperature and pH. At 25 degrees C in 0.1 M phosphate buffer, pH 7.6, the dissociation constant is 18 +/- 2 microM for both ligands. In the same buffer system, the van't Hoff enthalpy for dissociation is 35.5 +/- 1 kJ/mol for tryptophan, and 30.5 +/- 2 kJ/mol for indole propanoic acid. The affinity of the repressor for indole propanoic acid is independent of pH in the range 7 less than 10, but decreases four fold for tryptophan in the same range. The amino group of tryptophan makes a significant contribution to its binding affinity. Difference NMR spectra showed that there are few changes of protein resonances on binding ligands. The NMR signals of the bound resonances were assigned by difference and nuclear Overhauser effect spectroscopy. The properties of the bound resonances are consistent with the ligands being largely immobilised within the binding site. The difference spectra, and the known functional differences of the two ligands, suggest that tryptophan induces a slightly different conformational state in the repressor from that induced by indole propanoic acid. There is no evidence for a global transition. The rate of dissociation of ligands is relatively large, being in the range 400-600 s-1.     

Lack of negative charge in the E46Q mutant of photoactive yellow protein prevents partial unfolding of the blue-shifted intermediate

The long-lived light-induced intermediate (pB) of the E46Q mutant (glutamic acid is replaced by glutamine at position 46) of photoactive yellow protein (PYP) has been investigated by NMR spectroscopy. The ground state of this mutant is very similar to that of wild-type PYP (WT), whereas the pB state, formed upon illumination, appears to be much more structured in E46Q than in WT. The differences are most striking in the N-terminal domain of the protein. In WT, the side-chain carboxylic group of E46 is known to donate its proton to the chromophore upon illumination. The absence of the carboxylic group near the chromophore in the E46Q mutant prohibits the formation of a negative charge at this position upon formation of pB. This prevents the partial unfolding of the mutant, as evidenced from NMR chemical shift comparison and proton/deuterium (H/D) exchange studies.     

Magnetic resonance spectral characterization of the heme active site of Coprinus cinereus peroxidase

Examination of the peroxidase isolated from the inkcap Basidiomycete Coprinus cinereus shows that the 42,000-dalton enzyme contains a protoheme IX prosthetic group. Reactivity assays and the electronic absorption spectra of native Coprinus peroxidase and several of its ligand complexes indicate that this enzyme has characteristics similar to those reported for horseradish peroxidase. In this paper, we characterize the H2O2-oxidized forms of Coprinus peroxidase compounds I, II, and III by electronic absorption and magnetic resonance spectroscopies. Electron paramagnetic resonance (EPR) and nuclear magnetic resonance (NMR) studies of this Coprinus peroxidase indicate the presence of high-spin Fe(III) in the native protein and a number of differences between the heme site of Coprinus peroxidase and horseradish peroxidase. Carbon-13 (of the ferrous CO adduct) and nitrogen-15 (of the cyanide complex) NMR studies together with proton NMR studies of the native and cyanide-complexed Coprinus peroxidase are consistent with coordination of a proximal histidine ligand. The EPR spectrum of the ferrous NO complex is also reported. Protein reconstitution with deuterated hemin has facilitated the assignment of the heme methyl resonances in the proton NMR spectrum.     

Structural identification and synthesis of luciferin from the bioluminescent earthworm, Diplocardia longa.

For the first time, luciferin from a bioluminescent earthworm has been purified, identified, and synthesized. This luciferin from the North American species, Diplocardia longa, is a simple aldehyde compound, N-isovaleryl-3-aminopropanal, with an amide functional group. It is a clear, odorless oil at room temperature. It is nonvolatile and has no near-uv-visible absorption or fluorescence. Derivatives of this compound were made to facilitate its identification: the luciferin 2,4-dinitrophenylhydrazone (mp 174 degrees C), a yellow crystalline solid; and the luciferin alcohol, a clear oil. Synthesis of Diplocardia luciferin yielded an oil of identical spectroscopic (proton nuclear magnetic resonance (NMR), 13C NMR, mass, and ir), chemical (dinitrophenylhydrazone and alcohol derivatives, bioluminescence activity), and physical (thin-layer chromatography, volatility) properties to those of the purified native Diplocardia luciferin.     

蛇毒的核磁共振氢谱在生物化学上的意义

每种蛇毒含有多种蛋白质组分,每种蛋白质分子有其自已的一级结构和相应的氨基酸残基的组成。因此蛇毒的氢谱是其所有组成的谱图的加和,对不同产地和种属的20多种冷冻干燥的蛇毒进行了测定,结果每种蛇毒均显示其特征的核磁共振氢谱,提示各种蛇毒的氨基酸残基组成是不同的。     

Post-translational modification of barley LTP1b: the lipid adduct lies in the hydrophobic cavity and alters the protein dynamics

NMR techniques have been used to characterise the effects of a lipid-like post-translational modification on barley lipid transfer protein (LTP1b). NMR chemical shift data indicate that the lipid-like molecule lies in the hydrophobic cavity of LTP1b, with Tyr 79 being displaced to accommodate the ligand in the cavity. The modified protein has a reduced level of backbone amide hydrogen exchange protection, presumably reflecting increased dynamics in the protein. This may result from a loosening of the protein structure and may explain the enhanced surface properties observed for LTP1b.     

Physical studies on a nucleoprotein from the ribosome of E. coli

Bacterial 5S RNA and its cognate proteins constitute an attractive system to study nucleoprotein interactions. The molecular weights of the components involved are modest and they can be prepared in the quantities necessary to permit the application of material-intensive techniques like NMR and X-ray crystallography. 5S RNA is being examined by proton NMR at 500 MHz with special attention paid to the downfield NH proton region. A substantial number of assignments can be suggested in this region based on nuclear Overhauser results. The binding of protein L25 (E. coli) to the RNA gives rise to a highly characteristic set of perturbations in the spectrum of the RNA. The data suggest a localized and assignable alteration in RNA structure upon formation of the complex. In addition we have grown large crystals of RNAs related to 5S RNA and their complexes with a cognate protein. The properties of these crystals and the progress made in analyzing their structure are discussed.     

A microscopic study of the deoxyhemoglobin-catalyzed generation of nitric oxide from nitrite anion

There is recent evidence suggesting that nitrite anion (NO 2 (-)) represents the major intravascular NO storage molecule whose transduction to NO is facilitated by a reduction mechanism catalyzed by deoxygenated hemoglobin (deoxy-Hb). In this work, we provide a detailed microscopic study of deoxy-Hb nitrite reductase (NIR) activity by combining classical molecular dynamics and hybrid quantum mechanical-molecular mechanical simulations. Our results point out that two alternative mechanisms could be operative and suggest that the most energetic barriers should stem from either reprotonation of the distal histidine or NO dissociation from the ferric heme. In the first proposed mechanism, which is similar to that proposed for bacterial NIRs, nitrite anion or nitrous acid coordinates to the heme through the N atom. This pathway involves HisE7 in a one or two proton transfer process, depending on whether the active species is nitrite anion or nitrous acid, to yield an intermediate Fe(III)NO species which eventually dissociates leading to NO and methemoglobin. In the second mechanism, the nitrite anion coordinates to the heme through the O atom. This pathway requires only one proton transfer from HisE7 and leads directly to the formation of a hydroxo Fe(III) complex and NO.     

A redox-controlled molecular switch revealed by the crystal structure of a bacterial heme PAS sensor

PAS domains, which have been identified in over 1100 proteins from all three kingdoms of life, convert various input stimuli into signals that propagate to downstream components by modifying protein-protein interactions. One such protein is the Escherichia coli redox sensor, Ec DOS, a phosphodiesterase that degrades cyclic adenosine monophosphate in a redox-dependent manner. Here we report the crystal structures of the heme PAS domain of Ec DOS in both inactive Fe(3+) and active Fe(2+) forms at 1.32 and 1.9 A resolution, respectively. The protein folds into a characteristic PAS domain structure and forms a homodimer. In the Fe(3+) form, the heme iron is ligated to a His-77 side chain and a water molecule. Heme iron reduction is accompanied by heme-ligand switching from the water molecule to a side chain of Met-95 from the FG loop. Concomitantly, the flexible FG loop is significantly rigidified, along with a change in the hydrogen bonding pattern and rotation of subunits relative to each other. The present data led us to propose a novel redox-regulated molecular switch in which local heme-ligand switching may trigger a global "scissor-type" subunit movement that facilitates catalytic control.     

Nuclear magnetic resonance studies of Rhodospirillum rubrum cytochrome c'

Cytochrome c' from Rhodospirillum rubrum has been studied by proton magnetic resonance (NMR) at 270 MHz. The pH and temperature-dependence properties as well as proton water relaxation enhancement and bulk susceptibility measurements were examined. We conclude that the fifth ligand to the iron is histidine. The pH-dependent shift of the heme methyl resonances of the ferric protein shows pKa's at 5.8 and 8.7. The low-pH equilibrium causes only minor changes in the properties of the protein. However, the high-pH equilibrium causes large changes throughout the NMR spectra which correlate with the reported visible spectral changes. These NMR spectral changes are compared with the low-temperature EPR and M?ssbauer spectroscopic data. Analyses of the NMR data show that a second histidine, which is present in the sequence of c' from R. rubrum but is not conserved in other cytochromes c', is not a "distal" histidine. The nature of the sixth ligand and the significance of the high-pH transition are discussed.