Determination of 13Cα relaxation times in uniformly 13C/15N-enriched proteins

Summary Relaxation times of ¹³C carbons of uniformly ¹³C/¹⁵N-enriched probes have been investigated. The relaxation behaviour was analyzed in terms of a multispin system. Pulse sequences for the determination of T₁, T₂ and the heteronuclear NOE of ¹³C in uniformly ¹³C/¹⁵N-enriched ribonuclease T1 are presented. The experiments performed in order to obtain T₁ and the heteronuclear NOE were similar to those of the corresponding ¹⁵N experiments published previously. The determination of T₂ for the C-carbon in a completely labeled protein is more complicated, since the magnetization transfer during the T₂ evolution period owing to the scalar coupling of C–C must be suppressed. Various different pulse sequences for the T₂ evolution period were simulated in order to optimize the bandwidth for which reliable T₂ relaxation times can be obtained. A proof for the quality of these pulse sequences is given by fitting the intensity decay of individual ¹H–¹³C cross peaks, in a series of (¹H, ¹³C)-ct-HSQC spectra with a modified CPMG sequence as well as a T_1p sequence for the transverse relaxation time, to a single exponential using a simplex algorithm.     

Rapid Measurement of Scalar Three-bond 1HN-1Hα spin coupling constants in 15N-labelled proteins

Two new 2D NMR experiments, CT-HMQC-HA and CT-HMQC-HN, are proposed for the rapid measurement of homonuclear 3JHNH coupling constants of uniformly 15N-enriched proteins in solution. The experiments are based on the comparison of the signal intensities in a pair of constant-time [15N,1H]-HMQC spectra recorded with and without decoupling of the amide proton - proton coupling. Experimental data recorded with the 78-residue N-terminal domain of the E. coli arginine repressor (ArgR-N) and with oxidized E. coli flavodoxin (176 residues) showed good agreement with 3JHNH coupling constants obtained by fitting of the multiplet fine structure of the amide proton resonances or from a 3D HNHA-J experiment, respectively. Quantitative estimates for the effects from different relaxation rates of in-phase and antiphase magnetization are given.     

Determination of HN,Hα and HN,C′ coupling constants in 13C, 15N-labeled proteins

Summary Sensitive three-dimensional NMR experiments, based on the E.COSY principle, are presented for the measurement of the ³J(H^N,H) and ³J(H^N,C) coupling constants in uniformly ¹³C- and ¹⁵N-labeled proteins. They employ gradient coherence selection in combination with the sensitivity enhancement method in HSQC-type spectra (Cavanagh et al., 1991; Palmer et al., 1991). In most cases, the two measured coupling constants unambiguously define the -angle for protein structure determination. The method is applied to uniformly ¹³C, ¹⁵N-labeled ribonuclease T₁.     

Measurement of one-bond 1Hα-13Cα couplings in backbone-labelled proteins

NMR dipole-dipole couplings between protein backbone nuclei (¹H, ¹³C, ¹⁵N, ¹H^N,¹³C) offer enormous scope for the rapid determination of protein global folds. Here, we show that measurement of one-bond splittings in the protein backbone is facilitated by use of protein that is selectively isotopically enriched only in the backbone atoms. In particular, ¹H-¹³C couplings can be measured simply and with high sensitivity by use of conventional heteronuclear single quantum correlation (HSQC) techniques.     

13Cα decoupling during direct observation of carbonyl resonances in solution NMR of isotopically enriched proteins

Direct detection of ¹³C can be advantageous when studying uniformly enriched proteins, in particular for paramagnetic proteins or when hydrogen exchange with solvent is fast. A scheme recently introduced for long-observation-window band-selective homonuclear decoupling in solid state NMR, LOW-BASHD (Struppe et al. in J Magn Reson 236:89–94, 2013) is shown to be effective for ¹³C^α decoupling during direct ¹³C′ observation in solution NMR experiments too. For this purpose, adjustment of the decoupling pulse parameters and delays is demonstrated to be important for increasing spectral resolution, to reduce three-spin effects, and to decrease the intensity of decoupling side-bands. LOW-BASHD then yields ¹³C′ line widths comparable to those obtained with the popular IPAP method, while enhancing sensitivity by ca 35 %. As a practical application of LOW-BASHD decoupling, requiring quantitative intensity measurement over a wide dynamic range, the impact of lipid binding on the ¹³C′-detected NCO spectrum of the intrinsically disordered protein α-synuclein is compared with that on the ¹H-detected ¹H–¹⁵N HSQC spectrum. Results confirm that synuclein’s “dark state” behavior is not caused by paramagnetic relaxation or rapid hydrogen exchange.     

Determination of Hα,Hβ and Hβ,C′ coupling constants in13C-labeled proteins

Summary A sensitive method to assign H protons stereospecifically as well as to determine rotamer populations about ₁, in two 3D experiments is presented. The SOFT-HCCH-COSY experiment allowed us to measure the³J(H,C) couplings, using constant time evolution of C in t₂ and C_aliphatic-selective decoupling during t₃. The SOFT-HCCH-E.COSY experiment allowed us to measure the³J(H,H) couplings, using constant time evolution of C in t₂, a small flip angle¹H excitation pulse in the second mixing time, and double-band-selective decoupling (aliphatic and carbonyl carbons) during t₃. The method was applied to ribonuclease T₁.     

Measurement of 13Cα-13CO cross-relaxation rates in 15N-/13C-labelled proteins

Summary Internal motions play an important role in the biological function of proteins and NMR relaxation studies may characterize them over a wide range of frequencies. An experimental pulse scheme is proposed for the measurement of the ¹³CO-¹³C cross-relaxation rate. For sensitivity reasons, this measurement is performed in an indirect manner through several coherence transfer steps, which should thus be calibrated independently. Contributions of other relaxation pathways can be eliminated by the determination of the initial slope of the buildup curve. The cross-relaxation rates have been determined on a ¹⁵N-/¹³C-labelled 116-residue protein and the significant variations along the sequence have been interpreted as evidence of an increased amount of fast local motion.     

Measurement of one-bond 15N-13C′ dipolar couplings in medium sized proteins

A simple and accurate method is described for measurement of ¹ J _CN splittings in isotopically enriched proteins. The method is of the quantitative J correlation type, and the ¹ J _CN splitting is derived from the relative intensity in two 3D TROSY-HNCO spectra with ¹ J _CN dephasing intervals of 1/(2¹ J _CN) (reference intensity) and 1/¹ J _CN (residual intensity). If the two spectra are recorded under identical conditions and with the same number of scans, the random error in the ¹ J _CN value extracted in this manner is inversely related to the signal-to-noise (S/N) in the reference spectrum. A S/N of 30:1 in the reference spectrum yields random errors of less than 0.2 Hz in the extracted ¹ J _CN value. Dipolar couplings obtained from the difference in ¹ J _CN splitting in the isotropic and liquid crystalline phase for the C-terminal domain of calmodulin are in excellent agreement with its 1.68-Å crystal structure, but agree considerably less with the 2.2-Å structure.     

Determination of 3J(H infi supN,C infi sup′ ) coupling constants in proteins with the C′-FIDS method

Summary We introduce the C-FIDS-¹H,¹⁵N-HSQC experiment, a new method for the determination of ³J(H _infi ^supN ,C _infi ^sup ) coupling constants in proteins, yielding information about the torsional angle . It relies on the ¹H,¹⁵N-HSQC or HNCO experiment, two of the the most sensitive heteronuclear correlation experiments for isotopically labeled proteins. A set of three ¹H,¹⁵N-HSQC or HNCO spectra are recorded: a reference experiment in which the carbonyl spins are decoupled during t₁ and t₂, a second experiment in which they are decoupled exclusively during t₁ and a third one in which they are coupled in t₁ as well as t₂. The last experiment yields an E.COSY-type pattern from which the ²J(H _infi ^supN ,C _infi-1 ^sup ) and ¹J(N_i,C _infi-1 ^sup ) coupling constants can be extracted. By comparison of the coupled multiplet (obtained from the second experiment) with the decoupled multiplet (obtained from the first experiment) convoluted with the ²J(H _infi ^supN ,C _infi-1 ^sup ) coupling, the ³J(H _infi ^supN ,C _infi ^sup ) coupling can be found in a one-parameter fitting procedure. The method is demonstrated for the protein rhodniin, containing 103 amino acids. Systematic errors due to differential relaxation are small for ⁿJ(H^N,C) couplings in biomacromolecules of the size currently under NMR spectroscopic investigation.     

HNCCH-TOCSY,a triple resonance experiment for the correlation of backbone 13Cα and 15N resonances with aliphatic side-chain proton resonances and for measuring vicinal 13CO, 1Hβ coupling constants in proteins

Summary A 3D triple resonance experiment has been designed to provide intraresidual and sequential correlations between amide nitrogens and -carbons in uniformly ¹³C¹⁵N-labeled proteins. In-phase ¹³C magnetization is transferred to the aliphatic side-chain protons via the side-chain carbons using a CC-TOCSY mixing sequence. Thus, the experiment alleviates the resonance assignment process by providing information about the amino acid type as well as establishing sequential connectivities. Leaving the carbonyl spins untouched throughout the transfer from ¹³C to ¹H leads to E.COSY-type cross peaks, from which the ³J_{H co} coupling constants can be evaluated. The pulse sequence is applied to oxidized Desulfovibrio vulgaris flavodoxin.     

Facile measurement of polypeptide JHNHα coupling constants from HMQC-J spectra

A method, based on linewidth measurements, is described which permits the rapid and facile determination of J_HNH coupling constants from ¹⁵N labeled proteins. Using appropriately processed HMQC-J data, we have found that a simple linear relationship exists between the half-height linewidth (_1/2) of ¹⁵N–¹H cross peaks and their corresponding J_HNH coupling constants. Tests indicate that this technique permits the accurate measurement of up to 100 J_HNH coupling constants in less than 30 min. Furthermore, the J_HNH measurements can be done manually – without the need of any computer-based curve-fitting or minimization. Comparisons between J_HNH values predicted from high resolution X-ray structures and those determined using this technique indicate that the method is both accurate and precise (correlation coefficient = 0.90, rmsd = 0.75 Hz).     

An efficient 3D NMR technique for correlating the proton and15N backbone amide resonances with the α-carbon of the preceding residue in uniformly15N/13C enriched proteins

Summary A 3D NMR technique is described which correlates the amide proton and nitrogen resonances of an amino acid residue with the C chemical shift of its preceding residue. The technique uses a relay mechanism, transferring magnetization from¹⁵N to¹³C via the intervening carbonyl nucleus. This method for obtaining sequential connectivity is less sensitive to large line widths than the alternative HNCA experiment. The technique is demonstrated for the protein calmodulin, complexed with a 26 amino acid fragment of skeletal muscle myosin light chain kinase.Abbreviations CaM Calmodulin - HCACO -proton to -carbon to carbonyl correlation - H(CA)NHN -proton (via -carbon) to nitrogen to amide proton correlation - HMQC heteronuclear multiple quantum correlation - HNCA amide proton to nitrogen to C -carbon correlation - M13 a 26-residue fragment of the CaM-binding domain of skeletal muscle myosin light chain kinase comprising residues 577–602.     

Precise vicinal coupling constants3JHNα in proteins from nonlinear fits of J-modulated [15N,1H]-COSY experiments

Summary Improved experimental schemes for the recently introduced J-modulated [¹⁵N,¹H]-correlation experiment for measurements of the homonuclear amide proton-C proton vicinal coupling constants.³J_HN, in uniformly¹⁵N-labeled proteins are described, and a nonlinear fit procedure is presented for quantitative evaluation of³J_HN. The method was first tested with the N-terminal DNA-binding domain of the 434 repressor (M=7.3 kDa), where at 13 C precise values of³J_HN in the range 2.0–9.5 Hz were obtained for all residues with resolved¹⁵N-¹H cross peaks. It was then applied to theAntennapedia homeodomain complexed to a synthetic 14-base pair DNA fragment (molecular weight of the complex 18 kDa). The³J_HN values measured were found to be in excellent agreement with those predicted from the secondary structure of this protein in the complex.Abbreviations and symbols NOE nuclear Overhauser effect - COSY two-dimensional correlated spectroscopy - ³J_HN or J homonuclear vicinal amide proton-C proton coupling constant - 434 repressor(1–69) N-terminal DNA-binding domain of the 434 repressor comprising 69 residues     

Advances towards resonance assignments for uniformly—13C, 15N enriched bacteriorhodopsin at 18.8 T in purple membranes

Solid state NMR spectra from uniformly (13)C, (15)N enriched bacteriorhodospin (bR) purified from H. salinarium were acquired at 18.8 T using magic angle spinning methods. Isolated resonances of 2D (13)C-(13)C spectra exhibited 0.50-0.55 ppm line-widths. Several amino acid types could be assigned, and at least 12 out of 15 Ile peaks could be resolved clearly and identified based on their characteristic chemical shifts and connectivities. This study confirms that high resolution solid state NMR spectra can be obtained for a 248 amino acid uniformly labeled membrane protein in its native membrane environment and indicates that site-specific assignments are likely to be feasible with heteronuclear multidimensional spectra.     

Measurement of homonuclear three-bond J(HNHα) coupling constants in unlabeled peptides complexed with labeled proteins: Application to a decapeptide inhibitor bound to the proteinase domain of the NS3 protein of hepatitis C virus (HCV)

A new isotope-filtered experiment has been designed to measure homonuclear three-bond J(H^NH) coupling constants of unlabeled peptides complexed with labeled proteins. The new experiment is based on the 3D HNHA pulse scheme, and belongs to the `quantitative J-correlation' type. It has been applied to a decapeptide inhibitor bound to the proteinase domain of the NS3 protein of human hepatitis C virus (HCV).     

Enhancement of Th1 immune response by CD8α dendritic cells loaded with heat shock proteins enriched tumor extract in tumor-bearing mice

The discovery of dendritic cells (DCs) as professional antigen presenting cells has opened up new possibilities for their use in the development of tumor vaccines. We investigated the effect of the CD8α⁺ DCs loaded with heat-treated tumor lysate (HTL) as a vaccine in tumor immunotherapy. The HTL loaded CD8α⁺ DCs, TL loaded CD8α⁺ DCs and unloaded CD8α⁺ DCs were subcutaneously injected in the fibrosarcoma-bearing mice. The splenocyte proliferation and the shifting of Th1/Th2 response were measured. The results indicated a significant increase in the lymphocytes proliferation and the IFN-γ production in the test group of mouse splenocytes. According to the results, HTL loaded CD8α⁺ DCs vaccine significantly decreased tumor growth and longer survival than the other immunized animals. These findings show that anti-tumor immune response against the fibrosarcoma can be induced by HTL loaded CD8α⁺ DCs and may provide a useful therapeutic model for development of approaches to tumor treatments.     

Measurement of four-bond HN-Hα J-couplings in staphylococcal nuclease

Summary Quantitative J-correlation and triple-resonance ECOSY-type experiments are used to unambiguously establish the presence of four-bond sequential H^N-H J-couplings in the protein staphylococcal nuclease. Substantially negative values, ranging from -0.8 to -2.3 Hz, are observed when the angle is near +120°, and the following angle near +60°. For other conformations, the four-bond H^N-H J-couplings fall between -0.5 and +0.5 Hz.     

Pulse schemes for the measurement of3 JC′Cγ and3 JNCγ scalar couplings in 15N,13C uniformly labeled proteins

Pulse sequences are presented for the measurement of³J_CC and³J_NC scalar couplings for allC containing residues in¹⁵N,¹³C uniformly labeled proteins. The methodsdescribed are based on quantitative J correlation spectroscopy pioneered byBax and co-workers [Bax et al. (1994) Methods Enzymol., 239, 79–105].The combination of ³J_CC and³J_NC scalar coupling constants allows theassignment of discrete rotameric states about the ₁ torsion angle in cases where such states exist or, alternatively,facilitates the establishment of noncanonical ₁conformations or the presence of rotameric averaging. The methods areapplied to a 1.5 mM sample of staphylococcal nuclease.