An on/off resonance rotating frame relaxation experiment to monitor millisecond to microsecond timescale dynamics

Rotating frame relaxation experiments in proteins are used to study slow motions on the microsecond to millisecond timescale. An on/off resonance rotating frame relaxation experiment (R(1)(rho)) has been developed that incorporates adiabatic rotations into a R(1)(rho)-R(1) constant relaxation time experiment with weak radio frequency field strengths in order to effectively lock the magnetization over a wide range of (15)N frequencies. The new pulse sequence allows the measurement of a wide range of chemical exchange timescales on the order of 1.0 to 0.05 ms over an asymmetric bandwidth from +1.7omega(l) to -0.5omega(l) in a single experiment. A total bandwidth of +/-l.7omega(l) is obtained by performing the experiment a second time with a reversed adiabatic rotation.     

A novel NMR experiment for the sequential assignment of proline residues and proline stretches in 13C/15N-labeled proteins

A new pulse sequence is described for the sequential assignment of proline residues in 13C/15N-labeled proteins by correlating C and C chemical shifts of proline residues with the H chemical shift of the preceding residue. Notably, the experiment can provide the sequential connectivities in poly-proline stretches, which cannot be determined using standard triple resonance experiments. Excellent solvent suppression is achieved by coherence selection via a heteronuclear gradient echo. The new pulse sequence has been successfully applied to the 11 kDa HRDC domain.     

Four-dimensional 13C/13C-edited nuclear Overhauser enhancement spectroscopy of a protein in solution: application to interleukin 1 beta

A four-dimensional 13C/13C-edited NOESY experiment is described which dramatically improves the resolution of protein NMR spectra and enables the straightforward assignment of nuclear Overhauser effects involving aliphatic and/or aromatic protons in larger proteins. The experiment is demonstrated for uniformly (greater than 95%) 13C-labeled interleukin 1 beta, a protein of 153 residues and 17.4 kDa, which plays a key role in the immune response. NOEs between aliphatic and/or aromatic protons are first spread out into a third dimension by the 13C chemical shift of the carbon atom attached to the originating proton and subsequently into a fourth dimension by the 13C chemical shift of the carbon atom attached to the destination proton. Thus, each NOE cross peak is labeled by four chemical shifts. By this means, ambiguities in the assignment of NOEs that arise from chemical shift overlap and degeneracy are completely removed. Further, NOEs between protons with the same chemical shifts can readily be detected providing their attached carbon atoms have different 13C chemical shifts. The design of the pulse sequence requires special care to minimize the level of artifacts arising from undesired coherence transfer pathways, and in particular those associated with "diagonal" peaks which correspond to magnetization that has not been transferred from one proton to another.(ABSTRACT TRUNCATED AT 250 WORDS)     

A TROSY relayed HCCH-COSY experiment for correlating adenine H2/H8 resonances in uniformly 13C-labeled RNA molecules

A new TROSY relayed HCCH-COSY pulse sequence is introduced for correlating adenine H2 and H8 resonances in ¹³C-labeled RNA molecules. The pulse scheme provides substantial improvements in signal-to-noise compared to previously suggested experiments, and therefore will be suitable for NMR studies of larger RNA molecules. The experiment provides ¹³C chemical shifts for all carbon nuclei in the adenine base. This is advantageous for resolving spectral overlap in larger RNA molecules and provides a starting point for measuring additional parameters for these carbons in the adenine spin system.     

TROSY-selected ZZ-exchange experiment for characterizing slow chemical exchange in large proteins

A TROSY-selected ZZ-exchange experiment is described for measuring slow chemical exchange rates by monitoring the TROSY component of ¹⁵N longitudinal magnetization. Application of the proposed pulse sequence to the cadherin 8 N-terminal extracelluar domain demonstrates that enhanced sensitivity is obtained, compared to a previously described TROSY-detected ZZ-exchange sequence (Sahu et al. J Am Chem Soc 129: 13232–13237, 2007), by preserving the TROSY effect during the mixing period as well as the frequency encoding periods.     

(H)N(COCA)NH and HN(COCA)NH experiments for 1H-15N backbone assignments in 13C/15N-labeled proteins

Triple resonance HN(COCA)NH pulse sequences for correlating 1H(i), 15N(i),1H(i-1), and 15N(i-1) spins that utilize overlapping coherence transfer periods provide increased sensitivityrelative to pulse sequences that utilize sequential coherence transfer periods. Although theoverlapping sequence elements reduce the overall duration of the pulse sequences, theprincipal benefit derives from a reduction in the number of 180° pulses. Two versions of thetechnique are presented: a 3D (H)N(COCA)NH experiment that correlates 15N(i),1H(i-1), and 15N(i-1) spins, and a 3D HN(COCA)NH experiment that correlates 1H(i), 15N(i),1H(i-1), and 15N(i-1) spins by simultaneously encoding the 1H(i) and 15N(i) chemical shiftsduring the t1 evolution period. The methods are demonstrated on a 13C/15N-enriched sampleof the protein ubiquitin and are easily adapted for application to 2H/13C/15N-enrichedproteins.     

A study of protein-water exchange through the off-resonance ROESY experiment: Application to the DNA-binding domain of AlcR

Summary In this communication a new NMR experiment for the safe observation and quantification of water-protein exchange phenomena is presented. It combines a water-selective pulse, offering chemical shift-based separation, and the off-resonance ROESY dynamic filter, which permits the elimination of the unwanted intramolecular dipolar cross relaxation of protein protons. Moreover, pulsed field gradients are used for the suppression of radiation damping and the solvent signal. The straightforward incorporation of this sequence in heteronuclear experiments is demonstrated for the case of the DNA-binding domain of the alcohol regulator protein.     

Triple Quantum Decoherence under Multiple Refocusing: Slow Correlated Chemical Shift Modulations of C′ and N Nuclei in Proteins

A new experiment allows the identification of residues that feature slow conformational exchange in macromolecules. Rotations about dihedral angles that are slower than the global correlation time tau(c) cause a modulation of the isotropic chemical shifts of the nuclei. If these fluctuations are correlated they induce a differential line broadening between three-spin single-quantum and triple-quantum coherences involving three nuclei such as the carbonyl C', the neighbouring amide nitrogen N and the amide proton H(N) belonging to a pair of consecutive amino acids. A cross-correlated relaxation rate R (CS/CS)(C'N) can be determined that corresponds to the sum of the isotropic and anisotropic contributions to the chemical shift modulations of the carbonyl carbon and nitrogen nuclei. Only the isotropic contributions depend on the pulse repetition rate of a multiple-refocusing sequence. An attenuation of the relaxation rate with increasing pulse repetition rate can therefore be attributed to slow motions. The asparagine N25 residue of ubiquitin, located in the first alpha-helix, is shown to feature significant slow conformational exchange.     

Sugar-to-base correlation in nucleic acids with a 5D APSY-HCNCH or two 3D APSY-HCN experiments

A five-dimensional (5D) APSY (automated projection spectroscopy) HCNCH experiment is presented, which allows unambiguous correlation of sugar to base nuclei in nucleic acids. The pulse sequence uses multiple quantum (MQ) evolution which enables long constant-time evolution periods in all dimensions, an improvement that can also benefit non-APSY applications. Applied with an RNA with 23 nucleotides the 5D APSY-HCNCH experiment produced a complete and highly precise 5D chemical shift list within 1.5 h. Alternatively, and for molecules where the out-and-stay 5D experiment sensitivity is not sufficient, a set of out-and-back 3D APSY-HCN experiments is proposed: an intra-base (3D APSY-b-HCN) experiment in an MQ or in a TROSY version, and an MQ sugar-to-base (3D APSY-s-HCN) experiment. The two 3D peak lists require subsequent matching via the N1/9 chemical shift values to one 5D peak list. Optimization of the 3D APSY experiments for maximal precision in the N1/9 dimension allowed matching of all ¹⁵N chemical shift values contained in both 3D peak lists. The precise 5D chemical shift correlation lists resulting from the 5D experiment or a pair of 3D experiments also provide a valuable basis for subsequent connection to chemical shifts derived with other experiments.     

HNCAN pulse sequences for sequential backbone resonance assignment across proline residues in perdeuterated proteins

A TROSY-based triple-resonance pulse scheme is described which correlates backbone ¹H and ¹⁵N chemical shifts of an amino acid residue with the ¹⁵N chemical shifts of both the sequentially preceding and following residues. The sequence employs ¹ J _NC and ² J _NC couplings in two sequential magnetization transfer steps in an `out-and-back' manner. As a result, N,N connectivities are obtained irrespective of whether the neighbouring amide nitrogens are protonated or not, which makes the experiment suitable for the assignment of proline resonances. Two different three-dimensional variants of the pulse sequence are presented which differ in sensitivity and resolution to be achieved in one of the nitrogen dimensions. The new method is demonstrated with two uniformly ²H/¹³C/¹⁵N-labelled proteins in the 30-kDa range.     

TEDOR with adiabatic inversion pulses: Resonance assignments of <Superscript>13</Superscript>C/<Superscript>15</Superscript>N labelled RNAs

We have examined via numerical simulations the performance characteristics of different 15N RF pulse schemes employed in the transferred echo double resonance (TEDOR) experimental protocol for generating 13C-15N dipolar chemical shift correlation spectra of isotopically labelled biological systems at moderate MAS frequencies (omega(r) approximately 10 kHz). With an 15N field strength of approximately 30-35 kHz that is typically available in 5 mm triple resonance MAS NMR probes, it is shown that a robust TEDOR sequence with significant tolerance to experimental imperfections sa as H1 inhomogeneity and resonance offsets can be effectively implemented using adiabatic heteronuclear dipolar recoupling pulse schemes. TEDOR-based 15N-13C and 15N-13C-13C chemical shift correlation experiments were carried out for obtaining 13C and 15N resonance assignments of an RNA composed of 97 (CUG) repeats which has been implicated in the neuromuscular disease myotonic dystrophy.     

Tuning the HNN experiment: generation of serine–threonine check points

We describe here the tunability of the HNN experiment to obtain certain residue specific peak patterns in the spectra of (¹⁵N, ¹³C) labeled proteins. This is achieved by tuning a band-selective 180° pulse on the carbon channel in the pulse sequence, whereby one can tamper with the C^α–C^β coupling evolutions for the different residues. Specifically, we generate distinctive peak patterns for serine and threonine and their neighbors in the different planes of the three dimensional spectrum. These provide useful anchor points during sequential assignment of backbone resonances. The performance of this experiment, referred to as HNN-ST here, is demonstrated using two proteins, one properly folded and the other completely denatured. With the availability of high field spectrometers, techniques such as TROSY, and ever increasing sensitivities in the probes, this experiment with its large number of check points has a great potential for rapid and unambiguous backbone resonance assignment in large proteins.     

HMQC and HSQC experiments with water flip-back optimized for large proteins

An HMQC experiment is proposed, dubbed FHMQC, where water flip-back is achieved by a single water-selective pulse preceding the basic HMQC pulse sequence. The scheme is demonstrated with a ¹⁵N, ¹H-HMQC spectrum of uniformly ¹⁵N/²H-labelled S. aureus DNA gyrase B with a molecular weight of 45 kDa for the unlabelled protein. The sensitivity of the experiment is improved compared to that of an FHSQC spectrum. It is further shown that the original FHSQC experiment can be shortened by the use of bipolar gradients. Relaxation times of different ¹⁵N magnetizations and coherences were measured. The new FHMQC scheme is implemented in 3D NOESY-¹⁵N-HMQC and 3D¹⁵ N-HMQC-NOESY-¹⁵N-HMQC pulse sequences which are demonstrated with a 24 kDa fragment of uniformly ¹⁵N/¹³C/²H-labelled S. aureus DNA gyrase B.     

Transverse relaxation optimized HCN experiment for nucleic acids: Combining the advantages of TROSY and MQ spin evolution

A three-dimensional MQ-TROSY-HCN pulse sequence is presented which provides intra-base and sugar-to-base correlations for ¹³C, ¹⁵N labeled nucleic acids (RNA, DNA). The experiment simultaneously exploits the favorable relaxation properties of ¹H-¹³C multiple quantum coherence for sugar carbons and of ¹³C TROSY-type spin evolution for base carbons. MQ-TROSY-HCN thus combines the advantages of MQ-HCN for sugar-to-base and TROSY-HCN for intra-base correlations in a single experiment. In addition, two slightly different implementations of the MQ-TROSY-HCN experiment ensure optimal performance for small and larger oligonucleotides, respectively. The advantages of the MQ-TROSY-HCN experiment compared to the best previous implementations of HCN are demonstrated for a 33 nucleotide RNA aptamer.     

Direct amide <Superscript>15</Superscript>N to <Superscript>13</Superscript>C transfers for solid-state assignment experiments in deuterated proteins

The assignment of protein backbone and side-chain NMR chemical shifts is the first step towards the characterization of protein structure. The recent introduction of proton detection in combination with fast MAS has opened up novel opportunities for assignment experiments. However, typical 3D sequential-assignment experiments using proton detection under fast MAS lead to signal intensities much smaller than the theoretically expected ones due to the low transfer efficiency of some of the steps. Here, we present a selective 3D experiment for deuterated and (amide) proton back-exchanged proteins where polarization is directly transferred from backbone nitrogen to selected backbone or sidechain carbons. The proposed pulse sequence uses only ¹H–¹⁵N cross-polarization (CP) transfers, which are, for deuterated proteins, about 30% more efficient than ¹H–¹³C CP transfers, and employs a dipolar version of the INEPT experiment for N–C transfer. By avoiding H^N–C (H^N stands for amide protons) and C–C CP transfers, we could achieve higher selectivity and increased signal intensities compared to other pulse sequences containing long-range CP transfers. The REDOR transfer is designed with an additional selective π pulse, which enables the selective transfer of the polarization to the desired ¹³C spins.     

Three-dimensional experiment for solid-state NMR of aligned protein samples in high field magnets

A pulse sequence that yields three-dimensional ¹H chemical shift / ¹H-¹⁵N heteronuclear dipolar coupling / ¹⁵N chemical shift solid-state NMR spectra is demonstrated on a uniformly ¹⁵N labeled membrane protein in magnetically aligned phospholipid bilayers. Based on SAMPI4, the pulse sequence yields high resolution in all three dimensions at a ¹H resonance frequency of 900 MHz with the relatively low rf field strength (33 kHz) available for a lossy aqueous sample with a commercial spectrometer and probe. The ¹H chemical shift frequency dimension is shown to select among amide resonances, which will be useful in studies of larger polytopic membrane proteins where the resonances overlap in two-dimensional spectra. Moreover, the ¹H chemical shift, which can be measured from these spectra, provides an additional orientationally dependent frequency as input for structure calculations. Both Alexander A. Nevzorov and Sang Ho Park contributed equally to this work.     

Suppression of radiation damping during selective excitation of the water signal: The WANTED sequence

Summary A new pulse sequence is presented allowing the use of long selective pulses at the water frequency using standard equipment. Radiation damping is suppressed during the pulse by the use of gradient echoes programmed between the single pulses of a DANTE train. This WANTED (water-selective DANTE using gradients) sequence thus allows the observation of interactions with water without the use of special probe heads or filtering of undesired resonances. By combining the WANTED sequence with NOESY, ROESY and NOESY-GSQC experiments, we obtain selective 1D and 2D spectra fit to the observation of chemical exchange and dipolar interactions between water and protein protons.     

NMR studies of conformational states and dynamics of DNA

The application of high resolution NMR techniques to the investigation of DNA double helices in solution is currently in a rapid state of change as a result of advances in three different fields. First, new methods (cloning, enzymatic degradation, sonication, and chemical synthesis) have been developed for producing large quantities of short DNA suitable for NMR studies. Second, there have been major advances in the field of NMR in terms of the introduction of new pulse techniques and improvements in instrumentation. Finally, as a result of recent X-ray diffraction studies on short DNA helices and the discovery of left-handed Z-DNA there is heightened interest in the study of DNA structures in solution and the effect of sequence on structure. In the present review, we discuss the way in which NMR techniques have been used to probe various aspects of the DNA properties, including base pairing structure, dynamics of breathing, effect of sequence on DNA structure, internal molecular motions, the effect of environment on the DNA, and the interaction of DNA with small ligands.     

Probing conformational dynamics in biomolecules via chemical exchange saturation transfer: a primer

Although Chemical Exchange Saturation Transfer (CEST) type NMR experiments have been used to study chemical exchange processes in molecules since the early 1960s, there has been renewed interest in the past several years in using this approach to study biomolecular conformational dynamics. The methodology is particularly powerful for the study of sparsely populated, transiently formed conformers that are recalcitrant to investigation using traditional biophysical tools, and it is complementary to relaxation dispersion and magnetization transfer experiments that have traditionally been used to study chemical exchange processes. Here we discuss the concepts behind the CEST experiment, focusing on practical aspects as well, we review some of the pulse sequences that have been developed to characterize protein and RNA conformational dynamics, and we discuss a number of examples where the CEST methodology has provided important insights into the role of dynamics in biomolecular function.     

Detecting pulsatile hormone secretions using nonlinear mixed effects partial spline models

Neuroendocrine ensembles communicate with their remote and proximal target cells via an intermittent pattern of chemical signaling. The identification of episodic releases of hormonal pulse signals constitutes a major emphasis of endocrine investigation. Estimating the number, temporal locations, secretion rate, and elimination rate from hormone concentration measurements is of critical importance in endocrinology. In this article, we propose a new flexible statistical method for pulse detection based on nonlinear mixed effects partial spline models. We model pulsatile secretions using biophysical models and investigate biological variation between pulses using random effects. Pooling information from different pulses provides more efficient and stable estimation for parameters of interest. We combine all nuisance parameters including a nonconstant basal secretion rate and biological variations into a baseline function that is modeled nonparametrically using smoothing splines. We develop model selection and parameter estimation methods for the general nonlinear mixed effects partial spline models and an R package for pulse detection and estimation. We evaluate performance and the benefit of shrinkage by simulations and apply our methods to data from a medical experiment.