Comprehensive determination of <Superscript>3</Superscript>J<Subscript>HNHα</Subscript> for unfolded proteins using <Superscript>13</Superscript>C′-resolved spin-echo difference spectroscopy

An experiment is presented to determine ³J_HNHα coupling constants, with significant advantages for applications to unfolded proteins. The determination of coupling constants for the peptide chain using 1D ¹H, or 2D and 3D ¹H-¹⁵N correlation spectroscopy is often hampered by extensive resonance overlap when dealing with flexible, disordered proteins. In the experiment detailed here, the overlap problem is largely circumvented by recording ¹H-¹³C′ correlation spectra, which demonstrate superior resolution for unfolded proteins. J-coupling constants are extracted from the peak intensities in a pair of 2D spin-echo difference experiments, affording rapid acquisition of the coupling data. In an application to the cytoplasmic domain of human neuroligin-3 (hNlg3cyt) data were obtained for 78 residues, compared to 54 coupling constants obtained from a 3D HNHA experiment. The coupling constants suggest that hNlg3cyt is intrinsically disordered, with little propensity for structure.     

Effect of deuteration on some structural parameters of methyl groups in proteins as evaluated by residual dipolar couplings

One bond methyl ¹H-¹³C and ¹³C_methyl–¹³C scalar and residual dipolar couplings have been measured at sites in an ¹⁵N, ¹³C, 50% ²H labeled sample of the B1 immunoglobulin binding domain of peptostreptococcal protein L to investigate changes in the structure of methyl groups in response to deuterium substitution. Both one bond methyl ¹H-¹³C and ¹³C_methyl–¹³C scalar coupling constants have been found to decrease slightly with increasing deuterium content. Previous studies have shown that ¹H-¹³C couplings in methyl groups are exquisitely sensitive to electronic structure, with decreases in coupling values as a function of deuteration consistent with a slight lengthening of the remaining H-C bonds. Changes in the H_methylC_methylC angle are found to be small, with average differences on the order of 0.3 ± 0.1° and 0.4 ± 0.2° between CH₃, CH₂D and CH₃, CHD₂ isotopomers, respectively. Knowledge of methyl geometry is a prerequisite for the extraction of accurate dynamics parameters from spin relaxation studies involving these groups.     

Simultaneous measurement of protein one-bond and two-bond nitrogen-carbon coupling constants using an internally referenced quantitative J-correlated [(15)N,(1)H]-TROSY-HNC experiment

A quantitative J-correlation pulse sequence is described that allows simultaneous determination of one-bond and two-bond nitrogen-carbon coupling constants for protonated or deuterated proteins. Coupling constants are calculated from volume ratios between cross peaks and reference axial peaks observed in a single 3D spectrum. Accurate backbone ¹ J _NC, ¹ J _NC, and ² J _NC coupling constants are obtained for the two [¹⁵N;¹³C]-labeled, medium-sized proteins flavodoxin and xylanase and for the [²H;¹⁵N;¹³C]-labeled, large protein DFPase. A dependence of one-bond and two-bond J _NC values on protein backbone torsion angles is readily apparent, in agreement with previously found correlations. In addition, the experiment is performed on isotropic as well as aligned protein to measure associated ¹⁵N-¹³C residual dipolar couplings.     

A Novel Algorithm for Identification of Activated Cryptic 5′ Splice Sites

Abstract

The resonances of the protonated carbons of [d(TAGCGCTA)]₂ have been assigned by the two-dimensional proton-detected double-quantum heteronuclear correlation experiment ([¹H-^l3C]-DQCOSY). ¹³C-coupled and ^l3C-decoupled versions of the experiment were used. The assignment method is discussed in detail. The deoxyribose cross peaks segregate into five well-resolved regions, and the base cross peaks have distinct features that are helpful for assignments. The cross peaks from the ¹H-¹³C pairs at the Cyd5, Ado2 and ThdCH₃ base positions fall in separate regions of the spectrum from each other; they also are resolved from the closely spaced Ado8, Guo8, Cyd6 and Thd6. Additional parameters for distinction of the base signals are their differing J-coupling values and long-range coupling patterns.     

Structural Characterization of Cyclic ADP-Ribose by NMR Spectroscopy

Abstract

Structure of cyclic adenosine diphosphoribose (cADPR) was reinvestigated by using ¹H, ¹³C, and ³¹P NMR spectroscopy. The ¹H-¹H coupling constants and NOE data suggested that the adenosine and ribose moieties have a predominant C2′-endo conformation and an unusual flat conformation, respectively.     

Setosol,a Biologically Active Heptaketide-like Metabolite from the Pleiochaeta setosa Phytopathogen

Setosol, a biologically active natural product, was extracted from Pleiochaeta setosa, an organism isolated from volcanic rock in the Canaries. With molecular formula C₁₅H₁₆O₅ and a melting point of 139°C, this pale yellow and amorphous compound inhibited the growth of Pyricularia oryzae, Drechslera oryzae, and Gerlachia oryzae. Isolation of the new compound was performed by repeated centrifugal TLC on silica gel, and its structure was established as 2,8-dimethyl-4-methoxy-6,10,11-trihydroxy-benzooxaonin by detailed spectral studies, including COSY, 2D ¹H-¹³C direct chemical shift correlation (XHCORR), 2D ¹H-¹³C correlation via long-range coupling (COLOC), heteronuclear-gated decoupling (GATEDEC), and single-frequency heteronuclear-gated decoupling (SFDEC) NMR techniques, as well as UV, IR, and MS.     

Novel multi-dimensional heteronuclear NMR techniques for the study of 13C-O-acetylated oligosaccharides: Expanding the dimensions for carbohydrate structures

Complex carbohydrates have critical roles in a wide variety of biological processes. An understanding of the molecular mechanisms that underlie these processes is essential in the development of novel oligosaccharide-based therapeutic strategies. Unfortunately, obtaining detailed structural information for larger oligosaccharides (>10 residues) can be exceedingly difficult, especially where the amount of sample available is limited. Here we demonstrate the application of ¹³ C O-acetylation in combination with novel NMR experiments to obtain much of the information required to characterize the primary structure of oligosaccharides. (H)C_MeCOH-HEHAHA and H(C_Me)COH-HEHAHA experiments are presented that use heteronuclear Hartmann–Hahn transfer to correlate the acetyl groups with sugar ring protons in peracetylated oligosaccharides. The in-phase, pure absorption nature of the correlation peaks in these experiments allows measurement of both chemical shifts and, importantly, ¹H-¹H coupling constants that are used to define the stereochemistry of the sugar ring. The (HC_Me)COH and (HC_Me)COH-RELAY experiments provide additional methods for obtaining chemical shift assignments for larger oligosaccharides to define the sites of glycosidic linkages from the patterns of acetylation.     

Simultaneous α/β spin-state selection for <Superscript>13</Superscript>C and <Superscript>15</Superscript>N from a time-shared HSQC-IPAP experiment

Two novel HSQC-IPAP approaches are proposed to achieve α/β spin-state editing simultaneously for ¹³C and ¹⁵N in a single NMR experiment. The pulse schemes are based on a time-shared (TS) 2D ¹H,¹³C/¹H,¹⁵N-HSQC correlation experiment that combines concatenated echo elements for simultaneous J(CH) and J(NH) coupling constants evolution, TS evolution of ¹³C and ¹⁵N chemical shifts in the indirect dimension and heteronuclear α/β-spin-state selection by means of the IPAP principle. Heteronuclear α/β-editing for all CH _n (n = 1–3) and NH _n (1–2) multiplicities can be achieved in the detected F2 dimension of a single TS-HSQC-F2-IPAP experiment. On the other hand, an alternative TS-HSQC-F1-IPAP experiment is also proposed to achieve α/β-editing in the indirect F1 dimension. Experimental and simulated data is provided to evaluate these principles in terms of sensitivity and performance simultaneously on backbone and side-chain CH, CH₂, CH₃, NH, and NH₂ spin systems in uniformly ¹³C/¹⁵N-labeled proteins and in small natural-abundance peptides.     

NMR evidence for a type I β-turn in (Pro2)-tetrapeptides and interdependence of cis:Trans isomerism,ring flexibility,and backbone conformation

Tetrapeptides with proline in position 2, asparagine or leucine in position 3, and glycine in positions 1 and 4, with end groups free or blocked on the N-terminal side, were studied in their various ionic states in ²H₂O and in Me₂SO-d₆ by ¹H- and ¹³C-nmr. In order to clarify or refine some details, successive substitutions of the residues in these peptides with amino acids enriched to 85% in ¹³C, or to 85% ¹³C plus 97% ²H were carried out. The ¹H and ¹³C chemical shifts as well as the ¹H-¹H, ¹³C-¹³C, and ¹³C-¹H coupling constants and the signal intensities show strong similarity of behavior between the tetrapeptides of asparagine and leucine. The main conformational characteristics are (1) the almost total stabilization of the trans conformer in the type I β-turn structure when the peptide is in the zwitterion state dissolved in Me₂SO. This is deduced from the ³J and the ³J coupling constants, which both furnish a dihedral angle of ?³ = ?90°, and from the positive value of the temperature coefficient of the glycine-4 amide protons, which suggests a type 4 → 1 hydrogen bond; (2) the evolution of cis and trans isomer fractions which change with the ionic state of the peptides in Me₂SO, whereas they remain constant in aqueous solution; and (3) the conformation of the pyrrolidine ring as it follows the variations in cis:trans isomer populations together with the side-chain rotamer fractions of the residue in position 3. In the β-turn conformation the isomer cis is less abundant and the pyrrolidine ring is more flexible; this explains the perfect accommodation of the proline residue in position 2 of a bend. The interdependence of these phenomena where interactive forces play a predominant role underlines the importance of cooperative effects in the molecule. The results also suggest that the cis isomer of proline can adapt itself just as well as the trans isomer to position 2 of a type I β-turn.     

Residual structure and dynamics in DMSO-d6 denatured dynein light chain protein

Structural and motional features in the denatured state of a protein dictate the early folding events starting from that state and these features vary depending upon the nature of the denaturant used. Here, we have attempted to decipher the early events in the folding of Dynein Light Chain protein (DLC8), starting from DMSO-d6 denatured state. Multinuclear NMR experiments were used to obtain the full spectral assignment. The HSQC spectrum shows the presence of two sets of peaks for the residues Met 1, Ser 2, Arg 4, Ala 11, Met 17, Thr 26, Lys 44, Tyr 50, Asn 51, Trp 54, His 55, Val 58, Gly 59, Ser 64, Tyr 65, His 68, Phe 86, Lys 87 indicating the presence of slow conformational transition in the heterogeneous ensemble. Analysis of residual structural propensities with secondary ¹³C chemical shifts, ³J(H^N₋H^α) coupling constants and ¹H-¹H NOE revealed the presence of local preferences which encompass both native and non-native like structures. The spectral density calculations, as obtained from measured R₁, R₂ and ¹H-¹⁵N steady state NOE values provide insights into the backbone dynamics on the milli to picosecond timescale. The segment Ser 14 - His 55 exhibits slow motions on the milli- to microsecond timescale arising from conformational exchange. The presence of native like structural preference, as well as conformational exchange classifies the above segment as the nucleation site of folding. Based on the observations, we propose here, the probable hierarchy of folding of DLC8 on dilution of denaturant: the two helices are formed first followed by the formation of β2 and β5.     

The trans labilization of cis-[PtCl2(13CH3NH2)2] by glutathione can be monitored at physiological pH by [1H,13C] HSQC NMR

In order to monitor the trans labilization of cisplatin at physiological pH we have prepared the complex cis-[PtCl₂(¹³CH₃NH₂)₂] and studied its interactions with excess glutathione in aqueous solution at neutral pH by two-dimensional [1H,13C] heteronuclear single-quantum correlation (HSQC) NMR spectroscopy. [1H,13C] HSQC spectroscopy is a good method for following the release of ¹³CH₃NH₂ but is not so good for characterizing the Pt species in solution. In the reaction of cisplatin with glutathione, Pt–S bonds are formed and Pt–NH₃ bonds are broken. The best technique for following the formation of Pt–S bonds of cisplatin is by UV spectroscopy. [1H,13C] HSQC spectroscopy is the best method for following the breaking of the Pt–N bonds. [1H,15N] HSQC spectroscopy is the best method for characterizing the different species in solution. However, the intensity of the peaks in the ¹⁵NH₃–Pt–S region, in [1H,15N] HSQC, reflects a balance between the formation of Pt–S bonds, which increases the signal intensity, and the trans labilization, which decreases the signal intensity. [1H,15N] HSQC spectroscopy and [1H,13C] HSQC spectroscopy are complementary techniques that should be used in conjunction in order to obtain the most accurate information on the interaction of platinum complexes with sulfur-containing ligands.     

Conformational studies of diastereoisomeric cyclo(alanyl-phenylalanyl) with the coupling constants 1H–1H, 15N–1H, 13C–1H,and 13C–15N

The cyclodipeptides cyclo(L -alanyl-L -phenylalanyl) and cyclo(D -alanyl-L -phenylalanyl) were synthesized with various atoms substituted by the isotopes ¹⁵N and ¹³C. Thus, the coupling constants ¹⁵N–¹H, ¹³C–¹H, and ¹³C–¹⁵N could be obtained, in addition to the commonly used ¹H–¹H constants. The applicability of these coupling constants for obtaining conformational information on side chains and substituted 2,5-piperazinedione rings is discussed.     

Two-and three-dimensional HCN experiments for correlating base and sugar resonances in 15N, 13C-labeled RNA oligonucleotides

Summary New 2D and 3D ¹H-¹³C-¹⁵N triple resonance experiments are presented which allow unambiguous assignments of intranucleotide H1'-H8(H6) connectivities in ¹³C-and ¹⁵N-labeled RNA oligonucleotides. Two slightly different experiments employing double INEPT forward and back coherence transfers are optimized to obtain the H1'-C1'-N9/N1 and H8/H6-C8/C6-N9/N1 connectivities, respectively. The correlation of H1' protons to glycosidic nitrogens N9/N1 is obtained in a nonselective fashion. To correlate H8/H6 with their respective glycosidic nitrogens, selective ¹³C-refocusing and ¹⁵N-inversion pulses are applied to optimize the magnetization transfers along the desired pathway. The approach employs the heteronuclear one-bond spin-spin interactions and allows the 2D ¹H-¹⁵N and 3D¹H-¹³C-¹⁵N chemical shift correlation of nuclei along and adjacent to the glycosidic bond. Since the intranucleotide correlations obtained are based exclusively on through-bond scalar interactions, these experiments resolve the ambiguity of intra-and internucleotide H1'-H8(H6) assignments obtained from the 2D NOESY spectra. These experiments are applied to a 30-base RNA oligonucleotide which contains the binding site for Rev protein from HIV.     

Effective strategy to assign 1H-15N heteronuclear correlation NMR signals from lysine side-chain NH3 + groups of proteins at low temperature

Recent studies have shown that lysine side-chain NH₃ ⁺ groups are excellent probes for NMR investigations of dynamics involving hydrogen bonds and ion pairs relevant to protein function. However, due to rapid hydrogen exchange, observation of ¹H-¹⁵N NMR cross peaks from lysine NH₃ ⁺ groups often requires use of a relatively low temperature, which renders difficulty in resonance assignment. Here we present an effective strategy to assign ¹H and ¹⁵N resonances of NH₃ ⁺ groups at low temperatures. This strategy involves two new ¹H/¹³C/¹⁵N triple-resonance experiments for lysine side chains. Application to a protein-DNA complex is demonstrated.     

3D Triple-resonance NMR techniques for the sequential assignment of NH and 15N resonances in 15N- and 13C-labelled proteins

Summary Two new 3D ¹H-¹⁵N-¹³C triple-resonance experiments are presented which provide sequential cross peaks between the amide proton of one residue and the amide nitrogen of the preceding and succeeding residues or the amide proton of one residue and the amide proton of the preceding and succeeding residues, respectively. These experiments, which we term 3D-HN(CA)NNH and 3D-H(NCA)NNH, utilize an optimized magnetization transfer via the ²J_NC coupling to establish the sequential assignment of backbone NH and ¹⁵N resonances. In contrast to NH-NH connectivities observable in homonuclear NOESY spectra, the assignments from the 3D-H(NCA)NNH experiment are conformation independent to a first-order approximation. Thus the assignments obtained from these experiments can be used as either confirmation of assignments obtained from a conventional homonuclear approach or as an initial step in the analysis of backbone resonances according to Ikura et al. (1990) [Biochemistry, 29, 4659–4667]. Both techniques were applied to uniformly ¹⁵N- and ¹³C-labelled ribonuclease T1.     

Observation of H-bond mediated 3hJH2H3 coupling constants across Watson-Crick AU base pairs in RNA

^3hJ_H2H3trans-hydrogen bond scalar coupling constants have been observed for the first time in Watson-Crick AU base pairs in uniformly ¹⁵N-labeled RNA oligonucleotides using a new ^2hJ_NN-HNN-E. COSY experiment. The experiment utilizes adenosine H2 (AH2) for original polarization and detection, while employing ^2hJ_NNcouplings for coherence transfer across the hydrogen bonds (H-bonds). The H3 protons of uracil bases are unperturbed throughout the experiment so that these protons appear as passive spins in E. COSY patterns. ^3hJ_H2H3coupling constants can therefore be accurately measured in the acquisition dimension from the displacement of the E. COSY multiplet components, which are separated by the relatively large ¹J_H3N3coupling constants in the indirect dimension of the two-dimensional experiment. The ^3hJ_H2H3scalar coupling constants determined for AU base pairs in the two RNA hairpins examined here have been found to be positive and range in magnitude up to 1.8 Hz. Using a molecular fragment representation of an AU base pair, density functional theory/finite field perturbation theory (DFT/FPT) methods have been applied to attempt to predict the relative contributions of H-bond length and angular geometry to the magnitude of ^3hJ_H2H3coupling constants. Although the DFT/FPT calculations did not reproduce the full range of magnitude observed experimentally for the ^3hJ_H2H3coupling constants, the calculations do predict the correct sign and general trends in variation in size of these coupling constants. The calculations suggest that the magnitude of the coupling constants depends largely on H-bond length, but can also vary with differences in base pair geometry. The dependency of the ^3hJ_H2H3coupling constant on H-bond strength and geometry makes it a new probe for defining base pairs in NMR studies of nucleic acids.     

Direct NMR observation and DFT calculations of a hydrogen bond at the active site of a 44 kDa enzyme

A hydrogen bond between the amide backbone of Arg7 and the remote imidazole side chain of His106 has been directly observed by improved TROSY-NMR techniques in the 44 kDa trimeric enzyme chorismate mutase from Bacillus subtilis. The presence of this hydrogen bond in the free enzyme and its complexes with a transition state analog and the reaction product was demonstrated by measurement of ¹⁵N-¹⁵N and ¹H-¹⁵N trans-hydrogen bond scalar couplings, ^2h J _NN and ^1h J _HN, and by transfer of nuclear polarization across the hydrogen bond. The conformational dependences of these coupling constants were analyzed using sum-over-states density functional perturbation theory (SOS-DFPT). The observed hydrogen bond might stabilize the scaffold at the active site of BsCM. Because the Arg7-His106 hydrogen bond has not been observed in any of the high resolution crystal structures of BsCM, the measured coupling constants provide unique information about the enzyme and its complexes that should prove useful for structural refinement of atomic models.     

Refinement of d(GCGAAGC) hairpin structure using one- and two-bond residual dipolar couplings

The structure of the ¹³C,¹⁵N-labeled d(GCGAAGC) hairpin, as determined by NMR spectroscopy and refined using molecular dynamics with NOE-derived distances, torsion angles, and residual dipolar couplings (RDCs), is presented. Although the studied molecule is of small size, it is demonstrated that the incorporation of diminutive RDCs can significantly improve local structure determination of regions undefined by the conventional restraints. Very good correlation between the experimental and back-calculated small one- and two-bond ¹H-¹³C, ¹H-¹⁵N, ¹³C-¹³C and ¹³C-¹⁵N coupling constants has been attained. The final structures clearly show typical features of the miniloop architecture. The structure is discussed in context of the extraordinary stability of the d(GCGAAGC) hairpin, which originates from a complex interplay between the aromatic base stacking and hydrogen bonding interactions.     

Étude par r.m.n. de quatre disaccharides peracétylés sélectivement enrichis en 13C

Four peracetylated disaccharides ¹³C-labelled at the C-1′ position and having α-d-(1′→3), β-d-(1′→3), α-d-(1′→4), and β-d-(1′→4) linkages were prepared starting from the commercially available d-[1-¹³C]glucose. They were studied on the basis of their ³J_¹³CH coupling constants in relation with the conformation in solution of oligosaccharides as models for the corresponding polymer. A method of analysis of the n.m.r. spectra is described and the coupling constants J_{¹³C-1′H} given, particularly the ²J coupling (in the same cycle and with sign determination) and the ³J coupling (through the glycosidic bond). In that case, the values obtained give experimental information on the ψ angle values. They are compared with the known X-ray data for similar compounds.     

13C-labeled oligodeoxyribonucleotides: A solution study of a CCAAT-containing sequence at the nuclear factor I recognition site of human adenovirus

The solution behavior of the single-stranded CCAAT-containing octamer 1 , d(AGCCAATA), that comprises part of the nuclear factor I (NF-I) recognition site at the origin of replication of human adenovirus has been studied by nmr spectroscopy at 500 and 600 MHz. Proton resonance assignments for 1 were aided by selective ¹³C enrichment at C1′ of A₁ or A₅. High-resolution ¹³C-¹H heteronuclear multiple-bond coherence spectra of the ¹³C-labeled oligomers permitted the selective detection of furanosyl ring protons within each labeled residue due to short- and long-range ¹³C-¹H couplings to the enriched C1′. The resulting assignments provided firm starting points in the interpretation of double quantum filtered correlated spectra, yielding information supplemented by total correlated spectroscopy (TOCSY) and rotating frame nuclear Overhauser effect spectroscopic data to completely assign the ¹H-nmr spectrum of 1 and extract ³J_HH values for furanose con-formational analysis. Several ¹³C-¹H spin-coupling constants within the ¹³C-enriched A₁ or A₅ residues were measured from cross-peak shifts in TOCSY spectra, and their signs determined by inspection of the relative orientations of these shifts. ¹H-²-H and ¹³C-¹H spin-couplings both indicate a preference (> 75%) for south (C2′-endo) conformations by the furanosyl rings of 1 . © 1994 John Wiley & Sons, Inc.