Chiral Sulfur Compounds Studied by Raman Optical Activity: tert-Butanesulfinamide and its Precursor tert-Butyl tert-Butanethiosulfinate

Two chiral sulfur compounds, tert-butyl tert-butanethiosulfinate (1) and tert-butanesulfinamide (2), with inversion of configuration, have been studied by Raman optical activity (ROA) and electronic circular dichroism combined with density functional theory calculation. With the S-S linkage in 1, the couplings between the two tertiary carbon atoms often generate large ROA signals, whereas the tertiary carbon atom itself generally makes a large contribution to ROA signals in 2 for similar vibrational modes. The conformational dependence of ROA parameters provides probing conformation around the S-S bond from a new perspective. The simultaneous use of electronic circular dichroism and ROA is warranted to extract reliable conformational information. ROA provides a suitable candidate for the stereochemical study of chiral sulfur compounds, especially its capability of sensing the conformation around the S-S bond. Chirality 24:731-740, 2012. ? 2012 Wiley Periodicals, Inc.     

A new view of water dynamics in immobilized proteins.

The inflection frequency of the deuteron magnetic relaxation dispersion from water in rotationally immobilized protein samples has recently been found to be essentially independent of temperature and protein structure. This remarkable invariance has been interpreted in terms of a universal residence time of 1 microseconds for protein-associated water molecules. We demonstrate here that this interpretation is an artifact of the conventional perturbation theory of spin relaxation, which is not valid for rotationally immobile proteins. Using a newly developed non-perturbative, stochastic theory of spin relaxation, we identify the apparent correlation time of 1 microseconds with the inverse of the nuclear quadrupole frequency, thus explaining its invariance. The observed dispersion profiles are consistent with a broad distribution of residence times, spanning the microseconds range. Furthermore, we argue that the deuteron dispersion is due to buried water molecules rather than to the traditional surface hydration previously invoked, and that the contribution from rapidly exchanging protein hydrogens cannot be neglected. The conclusions of the present work are also relevant to proton relaxation in immobilized protein samples and to magnetic resonance imaging of soft tissue.     

Accelerated exchange of a buried water molecule in selectively disulfide-reduced bovine pancreatic trypsin inhibitor

Using magnetic relaxation dispersion (MRD), we have previously shown that the four internal water molecules in bovine pancreatic trypsin inhibitor (BPTI) exchange with bulk water on time scales between 10(-8) and 10(-4) s at room temperature. Because this exchange is controlled by the protein structure, internal water molecules can be used to probe rare conformational fluctuations. Here, we report (2)H and (17)O MRD data at three temperatures for wild-type BPTI and two BPTI variants where the 14-38 disulfide bond has been cleaved by a double Cys --> Ser mutation or by disulfide reduction and carboxamidomethylation. The MRD data show that the internal water molecules are conserved on disulfide cleavage. However, the exchange rate of the water molecule buried near the disulfide bond is enhanced by 2-4 orders of magnitude. The relation of water exchange to other dynamic processes in BPTI is discussed.     

The structure of bovine liver rhodanese. II. The active site in the sulfur-substituted and the sulfur-free enzyme.

X-ray studies at 2.5 Å resolution show that the active site of bovine liver rhodanese is a depression between the two domains. In sulfur-substituted rhodanese the density of the essential Cys247 corresponds with that of a persulfide. Both sulfur atoms are interacting via hydrogen bonds with several peptide NH and side-chain OH groups. One side of the active site pocket contains mainly hydrophylic, the other side mainly hydrophobic residues. None of these hydrophylic or hydrophobic groups appears to interact strongly with the persulfide.Crystals of the sulfur-substituted enzyme were treated with cyanide, a sulfur acceptor. Subsequent difference Fourier studies show that the extra sulfur atom has been removed. Only minor conformational differences appear to exist between the two rhodanese species studied. These are a movement of the Sγ atom of Cys247 and some rearrangement of solvent molecules near the active site.The combination of these observations with the results of experiments performed by other investigators suggest a mechanism for sulfur transfer by rhodanese in which the thiol group of Cys247 is the essential nucleophile, whereas the positive charges on Arg186 and Lys249 act in various ways as “electrophilic assistants”. The transition state and the persulfide in the sulfur-substituted enzyme are stabilized by several hydrogen bonds.     

Magnetic resonance studies on the copper site of dopamine beta-monooxygenase in the presence of cyanide and azide anions

In order to elucidate the coordination state of water molecules in the Cu(II) site of dopamine [( 3,4-dihydroxyphenyl)ethylamine] beta-monooxygenase, measurements of the paramagnetic 1H nuclear magnetic relaxation rate of solvent water in the enzyme solution containing cyanide or azide as an exogenous ligand were carried out to obtain the values of intrinsic paramagnetic relaxation rate decrements Rp1 and Rp2 for the ligand-enzyme 1:1 and 2:1 complexes, respectively. Rp1 (percent) values were 53 (pH 5.5) and 52 (pH 7.0) for cyanide and 38 (pH 5.5) and 32 (pH 7.0) for azide, while Rp2 (percent) values were 98 (pH 5.5) and 96 (pH 7.0) for azide. Although no Rp2 values for cyanide were obtained because of its reducing power at the Cu(II) site, the Rp1 and Rp2 values obtained above prove that the Cu(II) center has two coordinated water molecules that are exchangeable for exogenous ligands at either pH. Supporting evidence was provided by electron paramagnetic resonance (EPR) titration, in which the enzyme solution containing cyanide-enzyme (1:1) complex in an equal proportion to uncomplexed enzyme gave an observed paramagnetic relaxation rate decrement, Rp, of 23%. Another characteristic of the Rp1 and Rp2 values was their invariability with respect to pH, indicating that the three-dimensional structure of the Cu(II) site is pH-invariant within the range examined. Binding constants of ligand to enzyme Kb1 and Kb2 for 1:1 and 2:1 complex formation, respectively, were also determined through an analysis of the Rp values; it was found that Kb1 was larger than Kb2 irrespective of pH. (ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions of asparagine-linked carbohydrates with concanavalin A. Nuclear magnetic relaxation dispersion and circular dichroism studies

By using near-UV circular dichroism (CD) and solvent proton nuclear magnetic relaxation dispersion measurements, three different conformational states have been detected in Ca(2+)-Mn(2+)-concanavalin A upon binding a variety of asparagine-linked carbohydrates. Two of these transitions have been described previously, one for the binding of monosaccharides such as methyl alpha-D-mannopyranoside and oligosaccharides with terminal alpha-Glc or alpha-Man residues, and the second for the binding of oligomannose and complex type carbohydrates (Brewer, C. F., and Bhattacharyya, L. (1986) J. Biol. Chem. 261, 7306-7310). The third transition occurs upon binding a bisected biantennary complex type carbohydrate with terminal GlcNAc residues. Temperature-dependent nuclear magnetic relaxation dispersion and CD measurements have identified regions of the protein near the two metal ion binding sites that are associated with the conformation changes, and Tyr-12, which is part of the monosaccharide binding site, as responsible for the CD changes. The results support our previous conclusions that the rotamer conformation of the (alpha 1,6) arm of bisected complex type oligosaccharides binds to concanavalin A with dihedral angle omega = -60 degrees whereas nonbisected complex type oligosaccharides bind with omega = 180 degrees (Bhattacharyya, L., Haraldsson, M., and Brewer, C. F. (1987) J. Biol. Chem. 262, 1294-1299). The present findings also explain the effects of increasing chain length of bisected complex type carbohydrates on their interactions with the lectin.     

Deflavination of flavo-oxidases by nucleophilic reagents

Using spectroscopic techniques we studied the effect of the nucleophilic reagents cyanide, cyanate and thiocyanate on three flavo-oxidases namely alcohol oxidase (AO), glucose oxidase (GOX) and D-amino acid oxidase (DAOX). All three ions, added at concentrations in the mM range, caused release of the flavin adenine dinucleotide (FAD) co-factors from the enzyme molecules. In the case of AO this was accompanied by significant conformational perturbations, which was not observed for GOX and DAOX. As suggested from fluorescence, absorption and circular dichroism spectral changes at least one phenolic hydroxyl group became ionized upon FAD release from AO and a new class of Trp residues, fluorescent only in apo-AO protein, was demasked.     

Physicochemical studies of the protein-lipid interactions in melittin-containing micelles

Complexes of melittin with detergents and phospholipids have been characterized by fluorescence, circular dichroism, ultracentrifugation, quasi-elastic light scattering and 1H nuclear magnetic resonance (NMR) experiments. By ultracentrifugation and quasi-elastic light-scattering measurements it is shown that melittin forms stoichiometrically well-defined complexes with dodecylphosphocholine micelles consisting of one melittin molecule and approximately forty detergent molecules. Evidence from fluorescence, circular dichroism and 1H nuclear magnetic resonance experiments indicates that the conformation of melittin bound to micelles of various detergents or of diheptanoyl phosphatidylcholine is largely independent of the type of lipid and furthermore appears to be quite closely related to the conformation of melittin bound to phosphatidylcholine bilayers. 1H NMR is used to investigate the conformation of micelle-bound melittin in more detail and to compare certain aspects of the melittin conformation in the micelles with the spatial structures of monomeric and self-aggregated tetrameric melittin in aqueous solution. The experience gained with this system demonstrates that high resolution NMR of complexes of membrane proteins with micelles provides a viable method for conformational studies of membrane proteins.     

Rate-limiting domain and loop motions in arginine kinase

Arginine kinase catalyzes the reversible transfer of a phosphoryl group between ATP and arginine. It is the arthropod homologue of creatine kinase, buffering cellular ATP levels. Crystal structures of arginine kinase, in substrate-free and substrate-bound forms, have revealed large conformational changes associated with the catalytic cycle. Recent nuclear magnetic resonance identified movements of the N-terminal domain and a loop comprising residues I182--G209 with conformational exchange rates in the substrate-free enzyme similar to the turnover rate. Here, to understand whether these motions might be rate-limiting, we determined activation barriers for both the intrinsic dynamics and enzyme turnover using measurements over a temperature range of 15-30 °C. (15)N transverse relaxation dispersion yields activation barriers of 46 ± 8 and 34 ± 12 kJ/mol for the N-terminal domain and I182--G209 loop, respectively. An activation barrier of 34 ± 13 kJ/mol was obtained for enzyme turnover from steady-state kinetics. The similarity between the activation barriers is indeed consistent with turnover being limited by backbone conformational dynamics and pinpoints the locations of potentially rate-limiting motions.     

Immunological and spectroscopic studies of poly(dG-dC).poly(dG-dC) modified by cis-diamminedichloroplatinum(II)

The conformational changes induced by the binding of cis-diamminedichloroplatinum(II) to poly(dG-dC).poly(dG-dC) have been studied by reaction with specific antibodies, by circular dichroism and 31P nuclear magnetic resonance. Polyclonal and monoclonal antibodies to Z-DNA bind to platinated poly(dG-dC).poly(dG-dC) at low and high ionic strength. Antibodies elicited in rabbits immunized with the platinated polynucleotide bind to double stranded polynucleotides known to adopt the Z-conformation. At low and high ionic strength the circular dichroism spectrum of platinated poly(dG-dC).poly(dG- dC) does not resemble that of poly(dG-dC).poly(dG-dC) (B or Z conformation). At low ionic strength, the characteristic 31P nuclear magnetic resonance spectrum of the Z-form is not detected. It appears only at high ionic strength, as a component of a more complex spectrum.     

Structural rearrangements of the two domains of Azotobacter vinelandii rhodanese upon sulfane sulfur release: essential molecular dynamics, 15N NMR relaxation and deuterium exchange on the uniformly labeled protein

The Azotobacter vinelandii rhodanese is a 31 kDa sulfurtransferase protein that catalyzes the transfer of sulfur atom from thiosulfate to cyanide in the detoxification process from cyanide and is able to insert sulfur atom in the iron–sulfur cluster. A study of the uniformly ¹⁵N isotopic labeling by high resolution NMR, before obtaining the backbone sequential assignment, has been carried out. The sulfur loaded and the sulfur discharged forms of the enzyme show very similar HSQC spectra with a good spectral dispersion. Few resonances show changes in chemical shift between the two forms. Relaxation parameters T₁, T₂ and ¹H–¹⁵N NOE of all amide nitrogen atoms, as well as isotope exchange kinetics, show that the two forms exhibit the same global correlation time and hydrodynamic properties. In parallel, essential dynamics studies show that formation and discharging of catalytic cysteine persulfide group has no significant impact on the overall conformation of the protein. These results, taken together, give a clearcut answer to the question if the catalytic mechanism of the enzyme involves a change in the conformation and/or in the mutual orientation of the two domains. On the contrary these results clearly indicate that upon the catalytic mechanism the two domains of the protein behave as a unique fold.     

Effects of metal ions on the structure and spectra of the peptide group.

The interaction between salts of Groups IA and IIA and model aliphatic amides has been studied. The interaction has been monitored by calorimetry and spectroscopy. Among the alkali cations, lithium ion interacts strongest, while in Group II calcium appears to interact somewhat stronger than magnesium. The metal cation binds to the amide oxygen atom and causes alteration in the amide group geometry. As a consequence, significant alterations are seen in the infrared, nuclear magnetic resonance, ultraviolet, and circular dichroism spectra of the ligand peptide. These findings are suggested to be of importance to the conformational studies of polypeptides and proteins.     

Stereospecific sulfur oxidation of 7-methylthioxanthone-2-carboxylic acid by Calonectria decora.

Thin-layer chromatography was used to determine the ability of three microorganisms capable of sulfur oxygenation, including Aspergillus niger, Streptomyces armentosus subsp. armentosus, and Calonectria decora, to oxidize 7-methylthioxanthone-2-carboxylic acid to the corresponding sulfoxide in growing cultures. In addition, optical rotary dispersion, circular dichroism, and nuclear magnetic resonance analysis in the presence of chiral shift reagent were used variously to access reaction stereoselectivity, absolute configuration, and optical purity of isolated products. The data indicated that C. decora produced the sulfoxide in high yield (69%) and optical purity (97%), most probably in the S-configuration.     

NMRD studies on phthalate dioxygenase: evidence for displacement of water on binding substrate

 Water proton T ₁ ^–1 measurements at magnetic fields between 0.01 and 50 MHz [nuclear magnetic relaxation dispersion (NMRD) measurements] have been performed on solutions of phthalate dioxygenase (PDO) reconstituted at the catalytic iron site with copper(II) or manganese(II). The data show evidence of a weakly coordinated water molecule in CuPDO; in the presence of the substrate, phthalate, this water appears to become even less tightly bound, and an additional tightly coordinated water can be detected. In PDO reconstituted with manganese, one tightly coordinated water is detected in the presence and in the absence of phthalate. An attempt is made to reconcile these data with low-temperature near-IR magnetic circular dichroism and X-ray absorption data, which show that PDO reconstituted with iron or cobalt is six-coordinate in the absence of substrate and five-coordinate in the presence of substrate. Received: 24 April 1996 / Accepted: 17 July 1996     

Water and Backbone Dynamics in a Hydrated Protein

Rotational immobilization of proteins permits characterization of the internal peptide and water molecule dynamics by magnetic relaxation dispersion spectroscopy. Using different experimental approaches, we have extended measurements of the magnetic field dependence of the proton-spin-lattice-relaxation rate by one decade from 0.01 to 300 MHz for ¹H and showed that the underlying dynamics driving the protein ¹H spin-lattice relaxation is preserved over 4.5 decades in frequency. This extension is critical to understanding the role of ¹H₂O in the total proton-spin-relaxation process. The fact that the protein-proton-relaxation-dispersion profile is a power law in frequency with constant coefficient and exponent over nearly 5 decades indicates that the characteristics of the native protein structural fluctuations that cause proton nuclear spin-lattice relaxation are remarkably constant over this wide frequency and length-scale interval. Comparison of protein-proton-spin-lattice-relaxation rate constants in protein gels equilibrated with ²H₂O rather than ¹H₂O shows that water protons make an important contribution to the total spin-lattice relaxation in the middle of this frequency range for hydrated proteins because of water molecule dynamics in the time range of tens of ns. This water contribution is with the motion of relatively rare, long-lived, and perhaps buried water molecules constrained by the confinement. The presence of water molecule reorientational dynamics in the tens of ns range that are sufficient to affect the spin-lattice relaxation driven by ¹H dipole-dipole fluctuations should make the local dielectric properties in the protein frequency dependent in a regime relevant to catalytically important kinetic barriers to conformational rearrangements.     

Folding of immunogenic peptide fragments of proteins in water solution. II. The nascent helix

1H nuclear magnetic resonance experiments indicate formation of secondary structures in water solutions of a synthetic immunogenic peptide of sequence EVVPHKKMHKDFLEKIGGL corresponding to the C-helix (residues 69 to 87) of myohemerythrin. The conformational ensemble consists of a set of turn-like structures, distributed over the C-terminal half of the peptide and rapidly interconverting by way of unfolded states. These structures, termed nascent helix, are stabilized into helical structure with long-range order in water/trifluorethanol mixtures. Circular dichroism measurements confirm the presence of 50% helix in water/trifluoroethanol but show no evidence of helicity in water solutions of the peptide. It is apparent that no one member of the transient set of helical conformations which constitutes the nascent helix is sufficiently long to be detectable by circular dichroism experiments. No preferred conformations could be detected by nuclear magnetic resonance in the N-terminal half of the peptide, either in water or water/trifluoroethanol mixtures. This region of the peptide is stabilized in helix by long-range interactions in the folded protein. The possible role of nascent secondary structure in induction of antipeptide antibodies and in initiation of protein folding is discussed.     

Microsecond exchange of internal water molecules in bacteriorhodopsin

The proton-conducting pathway of bacteriorhodopsin (BR) contains at least nine internal water molecules that are thought to be key players in the proton translocation mechanism. Here, we report the results of a multinuclear (1H, 2H, 17O) magnetic relaxation dispersion (MRD) study with the primary goal of determining the rate of exchange of these internal water molecules with bulk water. This rate is of interest in current attempts to elucidate the molecular details of the proton translocation mechanism. The relevance of water exchange kinetics is underscored by recent crystallographic findings of substantial variations in the number and locations of internal water molecules during the photocycle. Moreover, internal water exchange is believed to be governed by conformational fluctuations in the protein and can therefore provide information about the thermal accessibility of functionally important conformational substates. The present 2H and 17O MRD data show that at least seven water molecules, or more if they are orientationally disordered, in BR have residence times (inverse exchange rate constant) in the range 0.1-10 micros at 277 K. At least five of these water molecules have residence times in the more restrictive range 0.1-0.5 micros. These results show that most or all of the deeply buried water molecules in BR exchange on a time-scale that is short compared to the rate-limiting step in the photocycle. The MRD measurements were performed on BR solubilized in micelles of octyl glucoside. From the MRD data, the rotational correlation time of detergent-solubilized BR was determined to 35 ns at 300 K, consistent with a monomeric protein in complex with about 150 detergent molecules. The solubilized protein was found to be stable in the dark for at least eight months at 277 K.     

A new spatial structure for the axial methionine observed in cytochrome c5 from Pseudomonas mendocina. Correlations with the electronic structure of heme c

Cytochrome c5 from Pseudomonas mendocina has been isolated and the coordination geometry at the heme iron was investigated by 1H nuclear magnetic resonance and circular dichroism spectroscopy. Individual assignments were obtained for heme c and the axial ligands. From studies of nuclear Overhauser enhancements the axial histidine imidazole ring orientation relative to the heme group was found to coincide with that of other c-type cytochromes. In contrast, a new structure was observed for the axial methionine. This includes S chirality at the iron-bound sulfur atom, but compared to cytochromes c-551 from Pseudomonads and Rhodopseudomonas gelatinosa, which also contain S-chiral methionine, the spatial arrangement of the gamma- and beta-methylene groups and the alpha carbon of methionine is markedly different. Analysis of the electron spin density distribution in ferricytochrome c5 in the light of this new coordination geometry provides additional support for the hypothesis that the electronic structure of heme c is primarily governed by the orientation of the sp3 lone-pair orbital of the axial sulfur atom with respect to the heme plane.     

Optical and magnetic resonance studies of formate binding to horse liver catalase and sperm whale myoglobin.

The binding of formate ion, a substrate for the peroxidatic reaction of catalase, has been investigated by magnetic resonance techniques. Comparative studies of formate binding to ferric myoglobin have also been performed. The nuclear magnetic relaxation (NMR) rate of formate and water protons is enhanced by the presence of ferric horse liver catalase. The enhancement is not changed significantly by the addition of cyanide, indicating that water and formate are still bound in the presence of cyanide. Formate proton to heme iron distances determined by magnetic resonance techniques indicate that formate does not directly bind to the heme iron of catalase or myoglobin but to the globin, and NMR relaxation occurs as a result of outersphere mechanisms. Evidence that water forms an innersphere complex with the iron atom of the catalase heme is presented. In similar experiments with ferric myoglobin, the addition of cyanide caused a large decrease in the enhancement of the proton relaxation rate of both formate and water, indicating the displacement of water and formate from the heme and the vicinity of the heme, respectively. Broad, high-spin, ferric ion electron paramagnetic resonance absorptions of catalase and myoglobin at room temperature obtained in the presence and absence of formate show that formate does not alter appreciably the heme environment of catalase or myoglobin or the spin state of the heme iron. Studies on the binding of formate to catalase as monitored by changes in the heme absorption spectrum in the visible region show one-to-one stoichiometry with heme concentration. However, the small changes observed in the visible region of the optical spectrum on addition of formate ion are attributed to a secondary effect of formate on the heme environment, rather than direct binding of formate to the heme moiety.     

An MCD spectroscopic study of the molybdenum active site in sulfite oxidase: insight into the role of coordinated cysteine

Temperature-dependent magnetic circular dichroism (MCD) spectroscopy has been used for the first time to probe the electronic structure of the Mo active site in sulfite oxidase (SO). The enzyme was poised in the catalytically relevant [Mo(V):Fe(II)] state by anaerobic reduction of the enzyme with the natural substrate, sulfite, in the absence of the physiological oxidant cytochrome c. The [Mo(V):Fe(II)] state is of particular importance, as it is proposed to be a catalytic intermediate in the oxidative half reaction, where SO is reoxidized to the resting [Mo(VI):Fe(III)] state by two sequential one-electron transfers to cytochrome c. The MCD spectrum of the enzyme shows no charge transfer transitions below 17 000 cm⁻¹. This has been interpreted to result from (1) a severe reduction in ene-1,2-dithiolate sulfur in-plane and out-of-plane p orbital mixing, (2) a decrease in the dithiolate sulfur out-of-plane p-Mo d_xy orbital overlap, and (3) an orthogonal orientation between the vertical cysteine sulfur p (perpendicular to the Mo–S_cys σ-bond) and Mo d_xy orbitals. The spectroscopically determined cysteine sulfur p-Mo d_xy bonding scheme in the [Mo(V):Fe(II)] state is consistent with the crystallographically determined O–Mo–S_cys–C dihedral angle of 90° and precludes a covalent interaction between the vertical cysteine sulfur p orbital and Mo d_xy, effectively decoupling the cysteine from an effective through-bond electron transfer pathway. We have tentatively assigned a 22 250 cm⁻¹ positive C-term feature in the MCD as the cysteine S(σ)→Mo d_xy charge transfer that becomes allowed by a combination of configuration interaction and low-symmetry; however, the orbital overlap is anticipated to be quite small due to the near orthogonality of these orbitals. Therefore, we propose that the primary role of the coordinated cysteine is to decrease the effective nuclear charge on Mo by charge donation to the metal, statically poising the active site at more negative reduction potentials during electron transfer (ET) regeneration. Finally, the results of this study are consistent with the pyranopterin ene-1,2-dithiolate acting to couple the Mo site into efficient superexchange pathways for ET regeneration following oxygen atom transfer to the substrate.