Alternative SAIL-Trp for robust aromatic signal assignment and determination of the χ<Subscript>2</Subscript> conformation by intra-residue NOEs

Tryptophan (Trp) residues are frequently found in the hydrophobic cores of proteins, and therefore, their side-chain conformations, especially the precise locations of the bulky indole rings, are critical for determining structures by NMR. However, when analyzing [U–¹³C,¹⁵N]-proteins, the observation and assignment of the ring signals are often hampered by excessive overlaps and tight spin couplings. These difficulties have been greatly alleviated by using stereo-array isotope labeled (SAIL) proteins, which are composed of isotope-labeled amino acids optimized for unambiguous side-chain NMR assignment, exclusively through the ¹³C–¹³C and ¹³C–¹H spin coupling networks (Kainosho et al. in Nature 440:52–57, 2006). In this paper, we propose an alternative type of SAIL-Trp with the [ζ2,ζ3-²H₂; δ1,ε3,η2-¹³C₃; ε1-¹⁵N]-indole ring ([¹²C_γ, ¹²C_ε2] SAIL-Trp), which provides a more robust way to correlate the ¹H_β, ¹H_α, and ¹H_N to the ¹H_δ1 and ¹H_ε3 through the intra-residue NOEs. The assignment of the ¹H_δ1/¹³C_δ1 and ¹H_ε3/¹³C_ε3 signals can thus be transferred to the ¹H_ε1/¹⁵N_ε1 and ¹H_η2/¹³C_η2 signals, as with the previous type of SAIL-Trp, which has an extra ¹³C at the C_γ of the ring. By taking advantage of the stereospecific deuteration of one of the prochiral β-methylene protons, which was ¹H_β2 in this experiment, one can determine the side-chain conformation of the Trp residue including the χ₂ angle, which is especially important for Trp residues, as they can adopt three preferred conformations. We demonstrated the usefulness of [¹²C_γ,¹²C_ε2] SAIL-Trp for the 12 kDa DNA binding domain of mouse c-Myb protein (Myb-R2R3), which contains six Trp residues.     

Application of SAIL phenylalanine and tyrosine with alternative isotope-labeling patterns for protein structure determination

The extensive collection of NOE constraint data involving the aromatic ring signals is essential for accurate protein structure determination, although it is often hampered in practice by the pervasive signal overlapping and tight spin couplings for aromatic rings. We have prepared various types of stereo-array isotope labeled phenylalanines (ε- and ζ-SAIL Phe) and tyrosine (ε-SAIL Tyr) to overcome these problems (Torizawa et al. 2005), and proven that these SAIL amino acids provide dramatic spectral simplification and sensitivity enhancement for the aromatic ring NMR signals. In addition to these SAIL aromatic amino acids, we recently synthesized δ-SAIL Phe and δ-SAIL Tyr, which allow us to observe and assign δ-¹³C/¹H signals very efficiently. Each of the various types of SAIL Phe and SAIL Tyr yields well-resolved resonances for the δ-, ε- or ζ-¹³C/¹H signals, respectively, which can readily be assigned by simple and robust pulse sequences. Since the δ-, ε-, and ζ-proton signals of Phe/Tyr residues give rise to complementary NOE constraints, the concomitant use of various types of SAIL-Phe and SAIL-Tyr would generate more accurate protein structures, as compared to those obtained by using conventional uniformly ¹³C, ¹⁵N-double labeled proteins. We illustrated this with the case of an 18.2 kDa protein, Escherichia coli peptidyl-prolyl cis-trans isomerase b (EPPIb), and concluded that the combined use of ζ-SAIL Phe and ε-SAIL Tyr would be practically the best choice for protein structural determinations.     

Hydrogen exchange during cell-free incorporation of deuterated amino acids and an approach to its inhibition

Perdeuteration, selective deuteration, and stereo array isotope labeling (SAIL) are valuable strategies for NMR studies of larger proteins and membrane proteins. To minimize scrambling of the label, it is best to use cell-free methods to prepare selectively labeled proteins. However, when proteins are prepared from deuterated amino acids by cell-free translation in H₂O, exchange reactions can lead to contamination of ²H sites by ¹H from the solvent. Examination of a sample of SAIL-chlorella ubiquitin prepared by Escherichia coli cell-free synthesis revealed that exchange had occurred at several residues (mainly at Gly, Ala, Asp, Asn, Glu, and Gln). We present results from a study aimed at identifying the exchanging sites and level of exchange and at testing a strategy for minimizing ¹H contamination during wheat germ cell-free translation of proteins produced from deuterated amino acids by adding known inhibitors of transaminases (1 mM aminooxyacetic acid) and glutamate synthetase (0.1 mM l-methionine sulfoximine). By using a wheat germ cell-free expression system, we produced [U–²H, ¹⁵N]-chlorella ubiquitin without and with added inhibitors, and [U–¹⁵N]-chlorella ubiquitin as a reference to determine the extent of deuterium incorporation. We also prepared a sample of [U–¹³C, ¹⁵N]-chlorella ubiquitin, for use in assigning the sites of exchange. The added inhibitors did not reduce the protein yield and were successful in blocking hydrogen exchange at C^α sites, with the exception of Gly, and at C^β sites of Ala. We discovered, in addition, that partial exchange occurred with or without the inhibitors at certain side-chain methyl and methylene groups: Asn–H^β, Asp–H^β, Gln–H^γ, Glu–H^γ, and Lys–H^ε. The side-chain labeling pattern, in particular the mixed chiral labeling resulting from partial exchange at certain sites, should be of interest in studies of large proteins, protein complexes, and membrane proteins.     

Sensitivity improvement for correlations involving arginine side-chain Nε/Hε resonances in multi-dimensional NMR experiments using broadband 15N 180° pulses

Due to practical limitations in available ¹⁵N rf field strength, imperfections in ¹⁵N 180° pulses arising from off-resonance effects can result in significant sensitivity loss, even if the chemical shift offset is relatively small. Indeed, in multi-dimensional NMR experiments optimized for protein backbone amide groups, cross-peaks arising from the Arg guanidino ¹⁵Nε (~85 ppm) are highly attenuated by the presence of multiple INEPT transfer steps. To improve the sensitivity for correlations involving Arg Nε–Hε groups, we have incorporated ¹⁵N broadband 180° pulses into 3D ¹⁵N-separated NOE-HSQC and HNCACB experiments. Two ¹⁵N-WURST pulses incorporated at the INEPT transfer steps of the 3D ¹⁵N-separated NOE-HSQC pulse sequence resulted in a ~1.5-fold increase in sensitivity for the Arg Nε–Hε signals at 800 MHz. For the 3D HNCACB experiment, five ¹⁵N Abramovich-Vega pulses were incorporated for broadband inversion and refocusing, and the sensitivity of Arg¹Hε-¹⁵Nε-¹³Cγ/¹³Cδ correlation peaks was enhanced by a factor of ~1.7 at 500 MHz. These experiments eliminate the necessity for additional experiments to assign Arg ¹Hε and ¹⁵Nε resonances. In addition, the increased sensitivity afforded for the detection of NOE cross-peaks involving correlations with the ¹⁵Nε/¹Hε of Arg in 3D ¹⁵N-separated NOE experiments should prove to be very useful for structural analysis of interactions involving Arg side-chains.     

Sequential nearest-neighbor effects on computed <Superscript>13</Superscript>C<Superscript>α</Superscript> chemical shifts

To evaluate sequential nearest-neighbor effects on quantum-chemical calculations of ¹³C^α chemical shifts, we selected the structure of the nucleic acid binding (NAB) protein from the SARS coronavirus determined by NMR in solution (PDB id 2K87). NAB is a 116-residue α/β protein, which contains 9 prolines and has 50% of its residues located in loops and turns. Overall, the results presented here show that sizeable nearest-neighbor effects are seen only for residues preceding proline, where Pro introduces an overestimation, on average, of 1.73 ppm in the computed ¹³C^α chemical shifts. A new ensemble of 20 conformers representing the NMR structure of the NAB, which was calculated with an input containing backbone torsion angle constraints derived from the theoretical ¹³C^α chemical shifts as supplementary data to the NOE distance constraints, exhibits very similar topology and comparable agreement with the NOE constraints as the published NMR structure. However, the two structures differ in the patterns of differences between observed and computed ¹³C^α chemical shifts, Δ _ca,i , for the individual residues along the sequence. This indicates that the Δ _ca,i -values for the NAB protein are primarily a consequence of the limited sampling by the bundles of 20 conformers used, as in common practice, to represent the two NMR structures, rather than of local flaws in the structures.     

Triple-Resonance Methods for Complete Resonance Assignment of Aromatic Protons and Directly Bound Heteronuclei in Histidine and Tryptophan Residues

A set of three experiments is described which correlate aromatic resonances of histidine and tryptophan residues with amide resonances in ¹³C/¹⁵N-labelled proteins. Provided that backbone ¹H and ¹⁵N positions of the sequentially following residues are known, this results in sequence-specific assignment of histidine ¹H^δ2/¹³C^δ2 and ¹H^ε1/¹³C^ε1 as well as tryptophan ¹H^δ1/¹³C^δ1, ¹H^ζ2/¹³C^{ζ 2}, ¹H^η2/¹³C^η2, ¹H^ε3/¹³C^ε3, ¹H^ζ3/¹³C^ζ3 and ¹H^ε1/¹⁵N^ε1 chemical shifts. In the reverse situation, these residues can be located in the ¹H–¹⁵N correlation map to faciliate backbone assignments. It may be chosen between selective versions for either of the two amino acid types or simultaneous detection of both with complete discrimination against phenylalanine or tyrosine residues in each case. The linkages between δ-proton/carbon and the remaining aromatic as well as backbone resonances do not rely on through-space interactions, which may be ambiguous, but exlusively employ one-bond scalar couplings for magnetization transfer instead. Knowledge of these aromatic chemical shifts is the prerequisite for the analysis of NOESY spectra, the study of protein–ligand interactions involving histidine and tryptophan residues and the monitoring of imidazole protonation states during pH titrations. The new methods are demonstrated with five different proteins with molecular weights ranging from 11 to 28 kDa.     

Detection and characterization of serine and threonine hydroxyl protons in Bacillus circulans xylanase by NMR spectroscopy

Hydroxyl protons on serine and threonine residues are not well characterized in protein structures determined by both NMR spectroscopy and X-ray crystallography. In the case of NMR spectroscopy, this is in large part because hydroxyl proton signals are usually hidden under crowded regions of ¹H-NMR spectra and remain undetected by conventional heteronuclear correlation approaches that rely on strong one-bond ¹H–¹⁵N or ¹H–¹³C couplings. However, by filtering against protons directly bonded to ¹³C or ¹⁵N nuclei, signals from slowly-exchanging hydroxyls can be observed in the ¹H-NMR spectrum of a uniformly ¹³C/¹⁵N-labeled protein. Here we demonstrate the use of a simple selective labeling scheme in combination with long-range heteronuclear scalar correlation experiments as an easy and relatively inexpensive way to detect and assign these hydroxyl proton signals. Using auxtrophic Escherichia coli strains, we produced Bacillus circulans xylanase (BcX) labeled with ¹³C/¹⁵N-serine or ¹³C/¹⁵N-threonine. Signals from two serine and three threonine hydroxyls in these protein samples were readily observed via ³J_C–OH couplings in long-range ¹³C-HSQC spectra. These scalar couplings (~5–7 Hz) were measured in a sample of uniformly ¹³C/¹⁵N-labeled BcX using a quantitative ¹³C/¹⁵N-filtered spin-echo difference experiment. In a similar approach, the threonine and serine hydroxyl hydrogen exchange kinetics were measured using a ¹³C/¹⁵N-filtered CLEANEX-PM pulse sequence. Collectively, these experiments provide insights into the structural and dynamic properties of several serine and threonine hydroxyls within this model protein.     

Methods of NMR structure refinement: molecular dynamics simulations improve the agreement with measured NMR data of a C-terminal peptide of GCN4-p1

The C-terminal trigger sequence is essential in the coiled-coil formation of GCN4-p1; its conformational properties are thus of importance for understanding this process at the atomic level. A solution NMR model structure of a peptide, GCN4p16–31, encompassing the GCN4-p1 trigger sequence was proposed a few years ago. Derived using a standard single-structure refinement protocol based on 172 nuclear Overhauser effect (NOE) distance restraints, 14 hydrogen-bond and 11 ϕ torsional-angle restraints, the resulting set of 20 NMR model structures exhibits regular α-helical structure. However, the set slightly violates some measured NOE bounds and does not reproduce all 15 measured ³J(H_N-H_Cα)-coupling constants, indicating that different conformers of GCN4p16–31 might be present in solution. With the aim to resolve structures compatible with all NOE upper distance bounds and ³J-coupling constants, we executed several structure refinement protocols employing unrestrained and restrained molecular dynamics (MD) simulations with two force fields. We find that only configurational ensembles obtained by applying simultaneously time-averaged NOE distance and ³J-coupling constant restraining with either force field reproduce all the experimental data. Additionally, analyses of the simulated ensembles show that the conformational variability of GCN4p16–31 in solution admitted by the available set of 187 measured NMR data is larger than represented by the set of the NMR model structures. The conformations of GCN4p16–31 in solution differ in the orientation not only of the side-chains but also of the backbone. The inconsistencies between the NMR model structures and the measured NMR data are due to the neglect of averaging effects and the inclusion of hydrogen-bond and torsional-angle restraints that have little basis in the primary, i.e. measured NMR data.     

Residue Specific Ribose and Nucleobase Dynamics of the cUUCGg RNA Tetraloop Motif by MNMR 13C Relaxation

The dynamics of the nucleobase and the ribose moieties in a 14-nt RNA cUUCGg hairpin-loop uniformly labeled with ¹³C and ¹⁵N were studied by ¹³C spin relaxation experiments. R₁, R_1ρ and the ¹³C-{¹H} steady-state NOE of C₆ and C_1′ in pyrimidine and C₈ and C_1′ in purine residues were obtained at 298 K. The relaxation data were analyzed by the model-free formalism to yield dynamic information on timescales of pico-, nano- and milli-seconds. An axially symmetric diffusion tensor with an overall rotational correlation time τ_c of 2.31±0.13 ns and an axial ratio of 1.35±0.02 were determined. Both findings are in agreement with hydrodynamic calculations. For the nucleobase carbons, the validity of different reported ¹³C chemical shift anisotropy values (Stueber, D. and Grant, D. M., 2002 J. Am. Chem. Soc. 124, 10539–10551; Fiala et al., 2000 J. Biomol. NMR 16, 291–302; Sitkoff, D. and Case, D. A., 1998 Prog. NMR Spectroscopy 32, 165–190) is discussed. The resulting dynamics are in agreement with the structural features of the cUUCGg motif in that all residues are mostly rigid (0.82 < S² < 0.96) in both the nucleobase and the ribose moiety except for the nucleobase of U7, which is protruding into solution (S² = 0.76). In general, ribose mobility follows nucleobase dynamics, but is less pronounced. Nucleobase dynamics resulting from the analysis of ¹³C relaxation rates were found to be in agreement with ¹⁵N relaxation data derived dynamic information (Akke et al., 1997 RNA 3, 702–709). Electronic supplementary material Electronic supplementary material is available for this article at and accessible for authorised users.     

Strong coupling effects during <Emphasis Type="Italic">X</Emphasis>-pulse CPMG experiments recorded on heteronuclear <Emphasis Type="Italic">ABX</Emphasis> spin systems: artifacts and a simple solution

Simulation and experiment have been used to establish that significant artifacts can be generated in X-pulse CPMG relaxation dispersion experiments recorded on heteronuclear ABX spin-systems, such as ¹³C _i –¹³C _j –¹H, where ¹³C _i and ¹³C _j are strongly coupled. A qualitative explanation of the origin of these artifacts is presented along with a simple method to significantly reduce them. An application to the measurement of ¹H CPMG relaxation dispersion profiles in an HIV-2 TAR RNA molecule where all ribose sugars are protonated at the 2′ position, deuterated at all other sugar positions and ¹³C labeled at all sugar carbons is presented to illustrate the problems that strong ¹³C–¹³C coupling introduces and a simple solution is proposed.     

Structure and dynamics of photosynthetic membrane-bound proteins in Rhodobacter Sphaeroides,studied with solid-state NMR spectroscopy

The photosynthetic purple bacteria such as Rb. sphaeroides possesses an intracytoplasmic membrane (ICM) and a variety of pigment-binding membrane proteins located in the ICM, acting as photoreceptor. Such photosynthetic apparatus is concentrated in the ICM. It is composed of three multimeric membrane-bound proteins; light-harvesting complexes (LH 1, LH 2), a reaction center (RC) and a cytochrome b/c1 complex. We have purified these membranes, which are called chromatophores, and characterized the structure and dynamics of the photosynthetic membrane-bound proteins by means of multi-nuclear solid state NMR. First, the isotropic chemical shift of carbonyl carbons in natural abundance and [1-¹³C] Phe labeled chromatophores indicates that the membrane-bound proteins take mainly the helical conformation. Second, the chemical shifts of side-chain resonances of uniformly ¹⁵N-labeled chromatophores indicate the side-chain histidine residue is mainly hydrogen bonded, whereas structural heterogeneity of arginine and lysine side-chains are probed by those wide distribution of ¹⁵N shifts. Thirdly, the [β-²H₃]Ala and [ε-²H₂]Tyr labeling of the chromatophores are performed and dynamics of the [β-²H]Ala and the [ε-²H₂]Tyr labeled chromatophores are studied by means of ²H solid state NMR. The dynamics of [β-²H₃]Ala is found to be a 10⁸Hz three-site jump motion with 10° liberation along the Cα-Cβ bond axis. The ²H-NMR powder pattern spectrum of [ε-²H₂] Tyr labeled chromatophores was interpreted with an averaged correlation time of 5×10⁵ Hz with 180° two-fold flips, the result of the averaging of two kinds of split spectra in terms of motional time scale. This revised version was published online in June 2006 with corrections to the Cover Date.     

Relevance of phenylalanine 216 in the affinity of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> phosphoenolpyruvate carboxykinase for Mn(II)

Saccharomyces cerevisiae phosphoenolpyruvate (PEP) carboxykinase catalyzes the reversible formation of oxaloacetate and adenosine triphosphate from PEP, adenosine diphosphate and carbon dioxide, and uses Mn²⁺ as the activating metal ion. Comparison with the crystalline structure of homologous Escherichia coli PEP carboxykinase [Tari et al. (1997) Nature Struct. Biol. 4, 990–994] shows that Lys²¹³ is one of the ligands to Mn²⁺ at the enzyme active site. Coordination of Mn²⁺ to a lysyl residue is not common and suggests a low pK _a value for the ε-NH₂ group of Lys²¹³. In this work, we evaluate the role of neighboring Phe²¹⁶ in contributing to provide a low polarity microenvironment suitable to keep the ε-NH₂ of Lys²¹³ in the unprotonated form. Mutation Phe216Tyr shows that the introduction of a hydroxyl group in the lateral chain of the residue produces a substantial loss in the enzyme affinity for Mn²⁺, suggesting an increase of the pK _a of Lys²¹³. In agreement with this interpretation, theoretical calculations indicate an alkaline shift of 2.8 pH units in the pK _a of the ε-amino group of Lys²¹³ upon Phe216Tyr mutation.     

A hydrogen-bonding network formed by the B10–E7–E11 residues of a truncated hemoglobin from <Emphasis Type="Italic">Tetrahymena pyriformis</Emphasis> is critical for stability of bound oxygen and nitric oxide detoxification

Abstract  

Truncated hemoglobins (trHbs) are distributed from bacteria to unicellular eukaryotes and have roles in oxygen transport and nitric oxide detoxification. It is known that trHbs exist in ciliates of the Tetrahymena group, but trHb structure and function remain poorly understood. To investigate trHb function with respect to stability of bound oxygen and protein structure, we measured the oxygen binding kinetics of Tetrahymena pyriformis trHb, and determined the crystal structure of the protein. The O₂ association and dissociation rate constants of T. pyriformis trHb were 5.5 μM⁻¹ s⁻¹ and 0.18 s⁻¹, respectively. The autooxidation rate constant was 3.8 × 10⁻³ h⁻¹. These values are similar to those of HbN from Mycobacterium tuberculosis. The three-dimensional structure of an Fe(II)–O₂ complex of T. pyriformis trHb was determined at 1.73-? resolution. Tyr25 (B10) and Gln46 (E7) were hydrogen-bonded to a heme-bound O₂ molecule. Tyr25 donated a hydrogen bond to the terminal oxygen atom, whereas Gln46 hydrogen-bonded to the proximal oxygen atom. Furthermore, Tyr25 was hydrogen-bonded to the Gln46 and Gln50 (E11) residues. Mutations at Tyr25, Gln46, and Gln50 increased the O₂ dissociation and autooxidation rate constants. An Fe(III)–H₂O complex of T. pyriformis trHb was formed following reaction of the Fe(II)–O₂ complex of T. pyriformis trHb, in a crystal state, with nitric oxide. This suggests that T. pyriformis trHb functions in nitric oxide detoxification.     

Using the water signal to detect invisible exchanging protons in the catalytic triad of a serine protease

Chemical Exchange Saturation Transfer (CEST) is an MRI approach that can indirectly detect exchange broadened protons that are invisible in traditional NMR spectra. We modified the CEST pulse sequence for use on high-resolution spectrometers and developed a quantitative approach for measuring exchange rates based upon CEST spectra. This new methodology was applied to the rapidly exchanging Hδ1 and Hε2 protons of His57 in the catalytic triad of bovine chymotrypsinogen-A (bCT-A). CEST enabled observation of Hε2 at neutral pH values, and also allowed measurement of solvent exchange rates for His57-Hδ1 and His57-Hε2 across a wide pH range (3–10). Hδ1 exchange was only dependent upon the charge state of the His57 (k _ex,Im+ = 470 s⁻¹, k _ex,Im = 50 s⁻¹), while Hε2 exchange was found to be catalyzed by hydroxide ion and phosphate base ( k_{\textOH ^-} k_{{{\text{OH}}^{ - } }}  = 1.7 × 10¹⁰ M⁻¹ s⁻¹, k_{\textHPO4^{2 -}} k_{{{\text{HPO}}_{4}^{2 - } }}  = 1.7 × 10⁶ M⁻¹ s⁻¹), reflecting its greater exposure to solute catalysts. Concomitant with the disappearance of the Hε2 signal as the pH was increased above its pK _a, was the appearance of a novel signal (δ = 12 ppm), which we assigned to Hγ of the nearby Ser195 nucleophile, that is hydrogen bonded to Nε2 of neutral His57. The chemical shift of Hγ is about 7 ppm downfield from a typical hydroxyl proton, suggesting a highly polarized O–Hγ bond. The significant alkoxide character of Oγ indicates that Ser195 is preactivated for nucleophilic attack before substrate binding. CEST should be generally useful for mechanistic investigations of many enzymes with labile protons involved in active site chemistry.     

Spectral editing: selection of methyl groups in multidimensional solid-state magic-angle spinning NMR

A simple spectroscopic filtering technique is presented that may aid the assignment of ¹³C and ¹⁵N resonances of methyl-containing amino-acids in solid-state magic-angle spinning (MAS) NMR. A filtering block that selects methyl resonances is introduced in two-dimensional (2D) ¹³C-homonuclear and ¹⁵N–¹³C heteronuclear correlation experiments. The 2D ¹³C–¹³C correlation spectra are recorded with the methyl filter implemented prior to a ¹³C–¹³C mixing step. It is shown that these methyl-filtered ¹³C-homonuclear correlation spectra are instrumental in the assignment of C_δ resonances of leucines by suppression of C_γ–C_δ cross peaks. Further, a methyl filter is implemented prior to a ¹⁵N–¹³C transferred-echo double resonance (TEDOR) exchange scheme to obtain 2D ¹⁵N–¹³C heteronuclear correlation spectra. These experiments provide correlations between methyl groups and backbone amides. Some of the observed sequential ¹⁵N–¹³C correlations form the basis for initial sequence-specific assignments of backbone signals of the outer-membrane protein G.     

An investigation of the dynamics of spermine bound to duplex and quadruplex DNA by <Superscript>13</Superscript>C NMR spectroscopy

A detailed analysis of the ¹³C relaxation of ¹³C-labelled spermine bound to duplex and quadruplex DNA is presented. T₁, T₂ and heteronuclear NOE data were collected at four ¹³C frequencies (75.4, 125.7, 150.9 and 201.2 MHz). The data were analyzed in terms of a frequency-dependent order parameter, S ²(ω), to estimate the generalized order parameter and the contributions to the relaxation from different motional frequencies in the picosecond–nanosecond timescale and from any exchange processes that may be occurring on the microsecond–millisecond timescale. The relaxation data was surprisingly similar for spermine bound to two different duplexes and a linear parallel quadruplex. Analysis of the relaxation data from these complexes confirmed the conclusions of previous studies that the dominant motion of spermine is independent of the macroscopic tumbling of the DNA and has an effective correlation time of ∼50 ps. In contrast, spermine bound to a folded antiparallel quadruplex had faster relaxation rates, especially R ₂. As with the other complexes, a fast internal motion of the order of 50 ps makes a substantial contribution to the relaxation. The generalized order parameter for spermine bound to duplex DNA and the linear quadruplex is small but is larger for spermine bound to the folded quadruplex. In the latter case, there is evidence for exchange between at least two populations of spermine occurring on the microsecond–millisecond timescale. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

<Emphasis Type="Italic">Desulfovibrio legallis</Emphasis> sp. nov.: A Moderately Halophilic,Sulfate-Reducing Bacterium Isolated from a Wastewater Digestor in Tunisia

A new moderately halophilic sulfate-reducing bacterium (strain H₁^T) was enriched and isolated from a wastewater digestor in Tunisia. Cells were curved, motile rods (2–3 x 0.5 μm). Strain H₁^T grew at temperatures between 22 and 43°C (optimum 35°C), and at pH between 5.0 and 9.2 (optimum 7.3–7.5). Strain H₁^T required salt for growth (1–45 g of NaCl/l), with an optimum at 20–30 g/l. Sulfate, sulfite, thiosulfate, and elemental sulfur were used as terminal electron acceptors but not nitrate and nitrite. Strain H₁^T utilized lactate, pyruvate, succinate, fumarate, ethanol, and hydrogen (in the presence of acetate and CO₂) as electron donors in the presence of sulfate as electron acceptor. The main end-products from lactate oxidation were acetate with H₂ and CO₂. The G + C content of the genomic DNA was 55%. The predominant fatty acids of strain H₁^T were C_15:0 iso (38.8%), C_16:0 (19%), and C_14:0 iso 3OH (12.2%), and menaquinone MK-6 was the major respiratory quinone. Phylogenetic analysis of the small-subunit (SSU) ribosomal RNA (rRNA) gene sequence indicated that strain H₁^T was affiliated to the genus Desulfovibrio. On the basis of SSU rRNA gene sequence comparisons and physiological characteristics, strain H₁^T is proposed to be assigned to a novel species of sulfate reducers of the genus Desulfovibrio, Desulfovibrio legallis sp. nov. (= DSM 19129^T = CCUG 54389^T).     

Conformational dependence of <Superscript>13</Superscript>C shielding and coupling constants for methionine methyl groups

Methionine residues fulfill a broad range of roles in protein function related to conformational plasticity, ligand binding, and sensing/mediating the effects of oxidative stress. A high degree of internal mobility, intrinsic detection sensitivity of the methyl group, and low copy number have made methionine labeling a popular approach for NMR investigation of selectively labeled protein macromolecules. However, selective labeling approaches are subject to more limited information content. In order to optimize the information available from such studies, we have performed DFT calculations on model systems to evaluate the conformational dependence of ³ J _CSCC, ³ J _CSCH, and the isotropic shielding, σ_iso. Results have been compared with experimental data reported in the literature, as well as data obtained on [methyl-¹³C]methionine and on model compounds. These studies indicate that relative to oxygen, the presence of the sulfur atom in the coupling pathway results in a significantly smaller coupling constant, ³ J _CSCC/³ J _COCC ~ 0.7. It is further demonstrated that the ³ J _CSCH coupling constant depends primarily on the subtended CSCH dihedral angle, and secondarily on the CSCC dihedral angle. Comparison of theoretical shielding calculations with the experimental shift range of the methyl group for methionine residues in proteins supports the conclusion that the intra-residue conformationally-dependent shift perturbation is the dominant determinant of δ¹³Cε. Analysis of calmodulin data based on these calculations indicates that several residues adopt non-standard rotamers characterized by very large ~100° χ³ values. The utility of the δ¹³Cε as a basis for estimating the gauche/trans ratio for χ³ is evaluated, and physical and technical factors that limit the accuracy of both the NMR and crystallographic analyses are discussed.     

Copper (II) complex of 1,10-phenanthroline and <Emphasis Type="SmallCaps">l</Emphasis>-tyrosine with DNA oxidative cleavage activity in the gallic acid

Copper (II) complex of formulation [Cu–Phen–Tyr](H₂O)](ClO₄) (Phen = 1,10-phenanthroline, l-Tyr = l-tyrosine), has been prepared, and their induced DNA oxidative cleavage activity studied. The complex binds to DNA by intercalation, as deduced from the absorption and fluorescence spectral data. Scatchard plots constructed from the absorption titration data gave binding constant 2.44 × 10⁴ M⁻¹ of base pairs. Extensive hypochromism, broadening, and red shifts in the absorption spectra were observed. Upon binding to DNA, the fluorescence from the DNA–ethidium bromide system was efficiently quenched by the copper (II) complex. Stern–Volmer quenching constant 0.61 × 10³ M⁻¹ obtained from the linear quenching plots. [Cu–Phen–Tyr] complex efficiently cleave the supercoiled DNA to its nicked circular form with gallic acid as biological reductant at appropriate complex concentration. The gallic acid as reductant could observably improve copper (II) complex to DNA damage. The pseudo-Michaelis–Menten kinetic parameters (k _cat, K _M) were calculated to be 1.32 h⁻¹ and 5.46 × 10⁻⁵ M for [Cu–Phen–Tyr] complex. Mechanistic studies reveal the involvement of superoxide anions and hydroxyl radical (HO^·) as the reactive species under an aerobic medium.     

Basis of the 1:1 stoichiometry of the high affinity receptor FcεRI-IgE complex

A soluble fragment of the high-affinity IgE receptor FcεRI α-chain (sFcεRIα) binds to the Fc fragment of IgE (IgE-Fc) as a 1:1 complex. IgE-Fc consists of a dimer of the Cε2, Cε3 and Cε4 domains of the ε-heavy chain of IgE. This region of IgE has been modelled on the crystal structure of the Fc region of IgG₁, which exhibits twofold rotational symmetry. This implies that IgE should be divalent with respect to its ligands. X-ray scattering studies reveal however that the twofold rotational symmetry of IgE-Fc is perturbed by a bend in the linker region between the Cε2 and Cε3 domains. The 1:1 stoichiometry could then arise from the conformational asymmetry or from steric occlusion of one of the sites by the overhanging Cε2 domains. To test this hypothesis we have expressed a recombinant ε-chain fragment containing Cε3 and Cε4. This product, Fcε3–4, is secreted from cells as a disulphide linked dimer and binds with higher affinity than either IgE or IgE-Fc to cell surface FcεRI. Titration experiments, together with molecular mass measurements of the Fcε3–4/sFcεRIα complex, reveal that Fcε3–4 binds only a single receptor molecule. This excludes the possibility that steric hindrance by Cε2 accounts for the unexpected stoichiometry. Received: 31 July 1996 / Accepted: 1 December 1996