2,253 research outputs found
Measurement of (15)N longitudinal relaxation rates in (15)NH4(+) spin systems to characterise rotational correlation times and chemical exchange.
Many chemical and biological processes rely on the movement of monovalent cations and an understanding of such processes can therefore only be achieved by characterising the dynamics of the involved ions. It has recently been shown that (15)N-ammonium can be used as a proxy for potassium to probe potassium binding in bio-molecules such as DNA quadruplexes and enzymes. Moreover, equations have been derived to describe the time-evolution of (15)N-based spin density operator elements of (15)NH4(+) spin systems. Herein NMR pulse sequences are derived to select specific spin density matrix elements of the (15)NH4(+) spin system and to measure their longitudinal relaxation in order to characterise the rotational correlation time of the (15)NH4(+) ion as well as report on chemical exchange events of the (15)NH4(+) ion. Applications to (15)NH4(+) in acidic aqueous solutions are used to cross-validate the developed pulse sequence while measurements of spin-relaxation rates of (15)NH4(+) bound to a 41kDa domain of the bacterial Hsp70 homologue DnaK are presented to show the general applicability of the derived pulse sequence. The rotational correlation time obtained for (15)N-ammonium bound to DnaK is similar to the correlation time that describes the rotation about the threefold axis of a methyl group. The methodology presented here provides, together with the previous theoretical framework, an important step towards characterising the motional properties of cations in macromolecular systems
A 13C-detected 15N double-quantum NMR experiment to probe arginine side-chain guanidinium 15Nη chemical shifts.
Arginine side-chains are often key for enzyme catalysis, protein-ligand and protein-protein interactions. The importance of arginine stems from the ability of the terminal guanidinium group to form many key interactions, such as hydrogen bonds and salt bridges, as well as its perpetual positive charge. We present here an arginine 13Cζ-detected NMR experiment in which a double-quantum coherence involving the two 15Nη nuclei is evolved during the indirect chemical shift evolution period. As the precession frequency of the double-quantum coherence is insensitive to exchange of the two 15Nη; this new approach is shown to eliminate the previously deleterious line broadenings of 15Nη resonances caused by the partially restricted rotation about the Cζ-Nε bond. Consequently, sharp and well-resolved 15Nη resonances can be observed. The utility of the presented method is demonstrated on the L99A mutant of the 19 kDa protein T4 lysozyme, where the measurement of small chemical shift perturbations, such as one-bond deuterium isotope shifts, of the arginine amine 15Nη nuclei becomes possible using the double-quantum experiment
Relaxation Dispersion NMR Spectroscopy
Relaxation dispersion nuclear magnetic resonance (NMR) spectroscopy has been developed since the 1950s and has now evolved into a very sensitive and versatile tool to study chemical and conformational exchange processes on the micro- to milliseconds (µs–ms) time scale. While relaxation dispersion NMR was originally designed with small molecules in mind, it has become a very attractive tool to also study the dynamics of biological macromolecules, after major advances had been made in hardware, experimental design and isotope labelling
The range of axial rotation of the glenohumeral joint.
Accepted versio
Determining rotational dynamics of the guanidino group of arginine side chains in proteins by carbon-detected NMR
Arginine residues are imperative for many active sites and protein-interaction interfaces. A new NMR-based method is presented to determine the rotational dynamics around the Nε-Cζ bond of arginine side chains. An application to a 19 kDa protein shows that the strengths of interactions involving arginine side chains can be characterised
Methodological Advancements for Characterising Protein Side Chains by NMR Spectroscopy
The surface of proteins is covered by side chains of polar amino acids that are imperative for modulating protein functionality through the formation non-covalent intermolecular interactions. However, despite their tremendous importance, the unique structures of protein side chains require tailored approaches for investigation by NMR spectroscopy, and so have traditionally been understudied compared to the protein backbone. Here, we review substantial recent methodological advancements within NMR spectroscopy to address this issue. Specifically, we consider advancements that provide new insight into methyl-bearing side chains, show the potential of using non-natural amino acids, and reveal the actions of charged side chains. Combined, the new methods promise unprecedented characterisations of side chains that will further elucidate protein function
Virtual Homonuclear Decoupling in Direct Detection Nuclear Magnetic Resonance Experiments using Deep Neural Networks
Nuclear magnetic resonance (NMR) experiments are frequently complicated by the presence of homonuclear scalar couplings. For the growing body of biomolecular 13C-detected NMR methods, one-bond 13C–13C couplings significantly reduce sensitivity and resolution. The solution to this problem has typically been to perform virtual decoupling by recording multiple spectra and taking linear combinations. Here, we propose an alternative method of virtual decoupling using deep neural networks, which only requires a single spectrum and gives a significant boost in resolution while reducing the minimum effective phase cycles of the experiments by at least a factor of 2. We successfully apply this methodology to virtually decouple in-phase CON (13CO–15N) protein NMR spectra, 13C–13C correlation spectra of protein side chains, and 13Cα-detected protein 13Cα–13CO spectra where two large homonuclear couplings are present. The deep neural network approach effectively decouples spectra with a high degree of flexibility, including in cases where existing methods fail, and facilitates the use of simpler pulse sequences
Multi-Quantum Chemical Exchange Saturation Transfer NMR to Quantify Symmetrical Exchange: Application to Rotational Dynamics of the Guanidinium Group in Arginine Side Chains
Chemical exchange saturation transfer (CEST) NMR experiments have
emerged as a powerful tool for characterizing dynamics in proteins. We show here that the
CEST approach can be extended to systems with symmetrical exchange, where the NMR
signals of all exchanging species are severely broadened. To achieve this, multiquantum CEST
(MQ-CEST) is introduced, where the CEST pulse is applied to a longitudinal multispin order
density element and the CEST profiles are encoded onto nonbroadened nuclei. The MQCEST approach is demonstrated on the restricted rotation of guanidinium groups in arginine
residues within proteins. These groups and their dynamics are essential for many enzymes and
for noncovalent interactions through the formation of hydrogen bonds, salt-bridges, and πstacking interactions, and their rate of rotation is highly indicative of the extent of interactions
formed. The MQ-CEST method is successfully applied to guanidinium groups in the 19 kDa
L99A mutant of T4 lysozyme
Using Deep Neural Networks to Reconstruct Non-uniformly Sampled NMR Spectra
Non-uniform and sparse sampling of multi-dimensional NMR spectra has over the last decade become an important tool to allow for fast acquisition of multi-dimensional NMR spectra with high resolution. The success of non-uniform sampling NMR hinge on both the development of algorithms to accurately reconstruct the sparsely sampled spectra and the design of sampling schedules that maximise the information contained in the sampled data. Traditionally, the reconstruction tools and algorithms have aimed at reconstructing the full spectrum and thus 'fill out the missing points' in the time-domain spectrum, although other techniques are based on multi-dimensional decomposition and extraction of multi-dimensional shapes. Also over the last decade, machine learning, deep neural networks, and artificial intelligence have seen new applications in an enormous range of sciences, including analysis of MRI spectra. As a proof-of-principle, it is shown here that simple deep neural networks can be trained to reconstruct sparsely sampled NMR spectra. For the reconstruction of two-dimensional NMR spectra, reconstruction using a deep neural network performs as well, if not better than, the currently and widely used techniques. It is therefore anticipated that deep neural networks provide a very valuable tool for the reconstruction of sparsely sampled NMR spectra in the future to come
Intra-residue methyl-methyl correlations for valine and leucine residues in large proteins from a 3D-HMBC-HMQC experiment
Methyl-TROSY based NMR experiments have over the last two decades become one of the most important means to characterise dynamics and functional mechanisms of large proteins and macromolecular machines in solution. The chemical shift assignment of methyl groups in large proteins is, however, still not trivial and it is typically performed using backbone-dependent experiments in a ‘divide and conquer’ approach, mutations, structure-based assignments or a combination of these. Structure-based assignment of methyl groups is an emerging strategy, which reduces the time and cost required as well as providing a method that is independent of a backbone assignment. One crucial step in available structure-based assignment protocols is linking the two prochiral methyl groups of leucine and valine residues. This has previously been achieved by recording NOESY spectra with short mixing times or by comparing NOESY spectra. Herein, we present a method based on through-bond scalar coupling transfers, a 3D-HMBC-HMQC experiment, to link the intra-residue methyl groups of leucine and valine. It is shown that the HMBC-HMQC method has several advantages over solely using NOESY spectra since a unique intra-residue cross-peak is observed. Moreover, overlap in the methyl-TROSY HMQC spectrum can easily be identified with the HMBC-HMQC experiment, thereby removing possible ambiguities in the assignment
- …