Probing slow timescale dynamics in proteins using methyl <Superscript>1</Superscript>H CEST

Although ¹⁵N- and ¹³C-based chemical exchange saturation transfer (CEST) experiments have assumed an important role in studies of biomolecular conformational exchange, ¹H CEST experiments are only beginning to emerge. We present a methyl-TROSY ¹H CEST experiment that eliminates deleterious ¹H–¹H NOE dips so that CEST profiles can be analyzed robustly to extract methyl proton chemical shifts of rare protein conformers. The utility of the experiment, along with a version that is optimized for ¹³CHD₂ labeled proteins, is established through studies of exchanging protein systems. A comparison between methyl ¹H CEST and methyl ¹H CPMG approaches is presented to highlight the complementarity of the two experiments.     

<Superscript>1</Superscript>H, <Superscript>15</Superscript>N, <Superscript>13</Superscript>C backbone resonance assignment of the C-terminal domain of enzyme I from <Emphasis Type="Italic">Thermoanaerobacter tengcongensis</Emphasis>

Phosphoenolpyruvate binding to the C-terminal domain (EIC) of enzyme I of the bacterial phosphotransferase system (PTS) initiates a phosphorylation cascade that results in sugar translocation across the cell membrane and controls a large number of essential pathways in bacterial metabolism. EIC undergoes an expanded to compact conformational equilibrium that is regulated by ligand binding and determines the phosphorylation state of the overall PTS. Here, we report the backbone ¹H, ¹⁵N and ¹³C chemical shift assignments of the 70 kDa EIC dimer from the thermophilic bacterium Thermoanaerobacter tengcongensis. Assignments were obtained at 70 °C by heteronuclear multidimensional NMR spectroscopy. In total, 90% of all backbone resonances were assigned, with 264 out of a possible 299 residues assigned in the ¹H–¹⁵N TROSY spectrum. The secondary structure predicted from the assigned backbone resonance using the program TALOS+ is in good agreement with the X-ray crystal structure of T. tengcongensis EIC. The reported assignments will allow detailed structural and thermodynamic investigations on the coupling between ligand binding and conformational dynamics in EIC.     

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.     

A new class of CEST experiment based on selecting different magnetization components at the start and end of the CEST relaxation element: an application to <Superscript>1</Superscript>H CEST

Chemical exchange saturation transfer (CEST) experiments are becoming increasingly popular for investigating biomolecular exchange dynamics with rates on the order of approximately 50–500 s^?1 and a rich toolkit of different methods has emerged over the past few years. Typically, experiments are based on the evolution of longitudinal magnetization, or in some cases two-spin order, during a fixed CEST relaxation delay, with the same class of magnetization prepared at the start and selected at end of the CEST period. Here we present a pair of TROSY-based pulse schemes for recording amide and methyl ¹H CEST profiles where longitudinal magnetization at the start evolves to produce two-spin order that is then selected at the completion of the CEST element. This selection process subtracts out contributions from ¹H–¹H cross-relaxation on the fly that would otherwise complicate analysis of the data. It also obviates the need to record spin-state selective CEST profiles as an alternative to eliminating NOE effects, leading to significant improvements in sensitivity. The utility of the approach is demonstrated on a sample of a cavity mutant of T4 lysozyme that undergoes chemical exchange between conformations where the cavity is free and occupied.     

Histidine side-chain dynamics and protonation monitored by 13C CPMG NMR relaxation dispersion

The use of ¹³C NMR relaxation dispersion experiments to monitor micro-millisecond fluctuations in the protonation states of histidine residues in proteins is investigated. To illustrate the approach, measurements on three specifically ¹³C labeled histidine residues in plastocyanin (PCu) from Anabaena variabilis (A.v.) are presented. Significant Carr-Purcell-Meiboom-Gill (CPMG) relaxation dispersion is observed for ¹³C^ε1 nuclei in the histidine imidazole rings of A.v. PCu. The chemical shift changes obtained from the CPMG dispersion data are in good agreement with those obtained from the chemical shift titration experiments, and the CPMG derived exchange rates agree with those obtained previously from ¹⁵N backbone relaxation measurements. Compared to measurements of backbone nuclei, ¹³C^ε1 dispersion provides a more direct method to monitor interchanging protonation states or other kinds of conformational changes of histidine side chains or their environment. Advantages and shortcomings of using the ¹³C^ε1 dispersion experiments in combination with chemical shift titration experiments to obtain information on exchange dynamics of the histidine side chains are discussed.     

Protein dynamics detected in a membrane-embedded potassium channel using two-dimensional solid-state NMR spectroscopy

We report longitudinal ¹⁵N relaxation rates derived from two-dimensional (¹⁵N, ¹³C) chemical shift correlation experiments obtained under magic angle spinning for the potassium channel KcsA-Kv1.3 reconstituted in multilamellar vesicles. Thus, we demonstrate that solid-state NMR can be used to probe residue-specific backbone dynamics in a membrane-embedded protein. Enhanced backbone mobility was detected for two glycine residues within the selectivity filter that are highly conserved in potassium channels and that are of core relevance to the filter structure and ion selectivity.     

1H, 15N and 13C chemical shifts of the D. melanogaster myosin VI light chain androcam in high calcium

Androcam is a calmodulin-like protein that acts as a testis-specific light chain to myosin VI during spermatogenesis in D. melanogaster. Modest, localized chemical shift changes that accompany Ca²⁺ binding to the androcam N-terminal lobe indicate that unlike calmodulin, androcam does not undergo a dramatic conformational change upon binding calcium. Here we report the ¹H, ¹⁵N and ¹³C resonances of androcam in the high calcium (10 mM) state and show the extent of chemical shift changes for backbone resonances relative to the low calcium state.     

Modeling of Hidden Structures Using Sparse Chemical Shift Data from NMR Relaxation Dispersion

NMR relaxation dispersion measurements report on conformational changes occurring on the μs-ms timescale. Chemical shift information derived from relaxation dispersion can be used to generate structural models of weakly populated alternative conformational states. Current methods to obtain such models rely on determining the signs of chemical shift changes between the conformational states, which are difficult to obtain in many situations. Here, we use a “sample and select” method to generate relevant structural models of alternative conformations of the C-terminal-associated region of Escherichia coli dihydrofolate reductase (DHFR), using only unsigned chemical shift changes for backbone amides and carbonyls (¹H, ¹⁵N, and ¹³C′). We find that CS-Rosetta sampling with unsigned chemical shift changes generates a diversity of structures that are sufficient to characterize a minor conformational state of the C-terminal region of DHFR. The excited state differs from the ground state by a change in secondary structure, consistent with previous predictions from chemical shift hypersurfaces and validated by the x-ray structure of a partially humanized mutant of E. coli DHFR (N23PP/G51PEKN). The results demonstrate that the combination of fragment modeling with sparse chemical shift data can determine the structure of an alternative conformation of DHFR sampled on the μs-ms timescale. Such methods will be useful for characterizing alternative states, which can potentially be used for in silico drug screening, as well as contributing to understanding the role of minor states in biology and molecular evolution.     

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.     

PCS-based structure determination of protein–protein complexes

A simple and fast nuclear magnetic resonance method for docking proteins using pseudo-contact shift (PCS) and ¹H^N/¹⁵N chemical shift perturbation is presented. PCS is induced by a paramagnetic lanthanide ion that is attached to a target protein using a lanthanide binding peptide tag anchored at two points. PCS provides long-range (~40 Å) distance and angular restraints between the lanthanide ion and the observed nuclei, while the ¹H^N/¹⁵N chemical shift perturbation data provide loose contact-surface information. The usefulness of this method was demonstrated through the structure determination of the p62 PB1-PB1 complex, which forms a front-to-back 20 kDa homo-oligomer. As p62 PB1 does not intrinsically bind metal ions, the lanthanide binding peptide tag was attached to one subunit of the dimer at two anchoring points. Each monomer was treated as a rigid body and was docked based on the backbone PCS and backbone chemical shift perturbation data. Unlike NOE-based structural determination, this method only requires resonance assignments of the backbone ¹H^N/¹⁵N signals and the PCS data obtained from several sets of two-dimensional ¹⁵N-heteronuclear single quantum coherence spectra, thus facilitating rapid structure determination of the protein–protein complex.     

Improved HSQC experiments for the observation of exchange broadened signals

Summary We present here HSQC experiments with improved sensitivity for signals in the presence of exchange broadening. During periods of coherence transfer through scalar coupling the experiments employ CPMG-derived pulse trains to reduce loss of dephasing of spin coherence due to chemical exchange. ¹⁵N–¹H gradient CPMG-HSQC and SE-CPMG-HSQC experiments have been developed and applied to complexes of lac repressor headpiece with operator DNA. Improved sensitivity is demonstrated for many protein backbone and side-chain resonances in the complex, markedly for signals of protons located at the protein-DNA interface. In addition, a significant increase in intensity is observed for arginine guanidino groups undergoing conformational exchange.     

The use of TROSY for detection and suppression of conformational exchange NMR line broadening in biological macromolecules

The interference between conformational exchange-induced time-dependent variations of chemical shifts in a pair of scalar coupled ¹H and ¹⁵N spins is used to construct novel TROSY-type NMR experiments to suppress NMR signal loss in [¹⁵N,¹H]-correlation spectra of a 14-mer DNA duplex free in solution and complexed with the Antp homeodomain. An analysis of double- and zero-quantum relaxation rates of base ¹H–¹⁵N moieties showed that for certain residues the contribution of conformational exchange-induced transverse relaxation might represent a dominant relaxation mechanism, which, in turn, can be effectively suppressed by TROSY. The use of the new TROSY method for exchange-induced transverse relaxation optimization is illustrated with two new experiments, 2D ^h1 J _HN,^h2 J _NN-quantitative [¹⁵N,¹H]-TROSY to measure ^h1 J _HN and ^h2 J _NN scalar coupling constants across hydrogen bonds in nucleic acids, and 2D (^h2 J _NN+^h1 J _NH)-correlation-[¹⁵N,¹H]-TROSY to correlate ¹H^N chemical shifts of bases with the chemical shifts of the tertiary ¹⁵N spins across hydrogen bonds using the sum of the trans-hydrogen bond coupling constants in nucleic acids.     

Quantification of protein backbone hydrogen-deuterium exchange rates by solid state NMR spectroscopy

We present the quantification of backbone amide hydrogen-deuterium exchange rates (HDX) for immobilized proteins. The experiments make use of the deuterium isotope effect on the amide nitrogen chemical shift, as well as on proton dilution by deuteration. We find that backbone amides in the microcrystalline α-spectrin SH3 domain exchange rather slowly with the solvent (with exchange rates negligible within the individual ¹⁵N–T ₁ timescales). We observed chemical exchange for 6 residues with HDX exchange rates in the range from 0.2 to 5 s⁻¹. Backbone amide ¹⁵N longitudinal relaxation times that we determined previously are not significantly affected for most residues, yielding no systematic artifacts upon quantification of backbone dynamics (Chevelkov et al. 2008b). Significant exchange was observed for the backbone amides of R21, S36 and K60, as well as for the sidechain amides of N38, N35 and for W41ε. These residues could not be fit in our previous motional analysis, demonstrating that amide proton chemical exchange needs to be considered in the analysis of protein dynamics in the solid-state, in case D₂O is employed as a solvent for sample preparation. Due to the intrinsically long ¹⁵N relaxation times in the solid-state, the approach proposed here can expand the range of accessible HDX rates in the intermediate regime that is not accessible so far with exchange quench and MEXICO type experiments.     

Prospects for resonance assignments in multidimensional solid-state NMR spectra of uniformly labeled proteins

Summary The feasibility of assigning the backbone ¹⁵N and ¹³C NMR chemical shifts in multidimensional magic angle spinning NMR spectra of uniformly isotopically labeled proteins and peptides in unoriented solid samples is assessed by means of numerical simulations. The goal of these simulations is to examine how the upper limit on the size of a peptide for which unique assignments can be made depends on the spectral resolution, i.e., the NMR line widths. Sets of simulated three-dimensional chemical shift correlation spectra for artificial peptides of varying length are constructed from published liquid-state NMR chemical shift data for ubiquitin, a well-characterized soluble protein. Resonance assignments consistent with these spectra to within the assumed spectral resolution are found by a numerical search algorithm. The dependence of the number of consistent assignments on the assumed spectral resolution and on the length of the peptide is reported. If only three-dimensional chemical shift correlation data for backbone ¹⁵N and ¹³C nuclei are used, and no residue-specific chemical shift information, information from amino acid side-chain signals, and proton chemical shift information are available, a spectral resolution of 1 ppm or less is generally required for a unique assignment of backbone chemical shifts for a peptide of 30 amino acid residues.     

Triple Resonance MAS NMR with (13C, 15N) Labelled Molecules: Reduced Dimensionality Data Acquisition Via 13C-15N Heteronuclear Two-Spin Coherence Transfer Pathways

A reduced dimensionality magic angle spinning solid-state NMR experimental protocol for obtaining chemical shift correlation spectra of dipolar coupled nuclei in uniformly (¹³C, ¹⁵N) labelled biological systems is described and demonstrated. The method involves a mapping of the evolution frequencies of heteronuclear ¹³C-¹⁵N zero- and double-quantum coherences. In comparison to a reduced dimensionality procedure involving the simultaneous incrementation of two single-quantum chemical shift evolution periods, the approach described here could be potentially advantageous for minimising the heat dissipated in the probe by high power ¹H decoupling in experiments requiring long t ₁ acquisition times.     

Characterisation of hydrogen bonding networks in RNAs via magic angle spinning solid state NMR spectroscopy

It is demonstrated that the spatial proximity of ¹H nuclei in hydrogen bonded base-pairs in RNAs can be conveniently mapped via magic angle spinning solid state NMR experiments involving proton spin diffusion driven chemical shift correlation of low gamma nuclei such as the imino and amino nitrogens of nucleic acid bases. As different canonical and non-canonical base-pairing schemes encountered in nucleic acids are characterised by topologically different networks of proton dipolar couplings, different base-pairing schemes lead to characteristic cross-peak intensity patterns in such correlation spectra. The method was employed in a study of a 100 kDa RNA composed of 97 CUG repeats, or (CUG)₉₇ that has been implicated in the neuromuscular disease myotonic dystrophy. ¹⁵N–¹⁵N chemical shift correlation studies confirm the presence of Watson–Crick GC base pairs in (CUG)₉₇.     

Extension of the HA-detection based approach: (HCA)CON(CA)H and (HCA)NCO(CA)H experiments for the main-chain assignment of intrinsically disordered proteins

Extensive resonance overlap exacerbates assignment of intrinsically disordered proteins (IDPs). This issue can be circumvented by utilizing ¹⁵N, ¹³C′ and ¹H^N spins, where the chemical shift dispersion is mainly dictated by the characteristics of consecutive amino acid residues. Especially ¹⁵N and ¹³C′ spins offer superior chemical shift dispersion in comparison to ¹³C^α and ¹³C^β spins. However, HN-detected experiments suffer from exchange broadening of amide proton signals on IDPs especially under alkali conditions. To that end, we propose here two novel HA-detected experiments, (HCA)CON(CA)H and (HCA)NCO(CA)H and a new assignment protocol based on panoply of unidirectional HA-detected experiments that enable robust backbone assignment of IDPs also at high pH. The new approach was tested at pH 6.5 and pH 8.5 on cancer/testis antigen CT16, a 110-residue IDP, and virtually complete backbone assignment of CT16 was obtained by employing the novel HA-detected experiments together with the previously introduced iH(CA)NCO scheme. Remarkably, also those 10 N-terminal residues that remained unassigned in our earlier HN-detection based assignment approach even at pH 6.5 were now readily assigned. Moreover, theoretical calculations and experimental results suggest that overall sensitivity of the new experiments is also applicable to small or medium sized globular proteins that require alkaline conditions.     

Off-resonance effects in 15N T2 CPMG measurements

The systematic difference between T ₂ values obtained from CPMG and T ₁ experiments was observed for backbone ¹⁵N nuclei of bacterial ribonuclease barnase. Theoretical consideration suggests that the observed difference is caused by off-resonance effects of 180° pulses of the CPMG pulse train. Namely, at off-resonance conditions T ₁-dependent secondary echo coherence pathways considerably contribute to the signal decay in the CPMG experiment and result in systematic (up to 10%) offset-dependent overestimation of ¹⁵N T ₂ measured by the CPMG technique. Under certain circumstances off-resonance effects result in dependence of ¹⁵N T ₂ on CPMG frequency, which might be erroneously interpreted as conformational exchange on the millisecond time-scale. A procedure for numerical correction of ¹⁵N T ₂ (CPMG) data is proposed.     

Solution NMR Studies of Chlorella Virus DNA Ligase-adenylate

DNA ligases are essential guardians of genome integrity by virtue of their ability to recognize and seal 3′-OH/5′-phosphate nicks in duplex DNA. The substrate binding and three chemical steps of the ligation pathway are coupled to global and local changes in ligase structure, involving both massive protein domain movements and subtle remodeling of atomic contacts in the active site. Here we applied solution NMR spectroscopy to study the conformational dynamics of the Chlorella virus DNA ligase (ChVLig), a minimized eukaryal ATP-dependent ligase consisting of nucleotidyltransferase, OB, and latch domains. Our analysis of backbone ¹⁵N spin relaxation and ¹⁵N,¹H residual dipolar couplings of the covalent ChVLig-AMP intermediate revealed conformational sampling on fast (picosecond to nanosecond) and slow timescales (microsecond to millisecond), indicative of interdomain and intradomain flexibility. We identified local and global changes in ChVLig-AMP structure and dynamics induced by phosphate. In particular, the chemical shift perturbations elicited by phosphate were clustered in the peptide motifs that comprise the active site. We hypothesize that phosphate anion mimics some of the conformational transitions that occur when ligase-adenylate interacts with the nick 5′-phosphate.