TROSY in NMR studies of the structure and function of large biological macromolecules

Transverse relaxation-optimized spectroscopy (TROSY), in combination with various isotope-labeling techniques, has opened avenues to study biomolecules with molecular masses of up to 1000000Da by solution NMR. Important recent applications of TROSY include the structure determination of membrane proteins in detergent micelles, structural and functional studies of large proteins in both monomeric form and macromolecular complexes, and investigations of intermolecular interactions in large complexes. TROSY improves the measurement of residual dipolar couplings and the detection of scalar couplings across hydrogen bonds - techniques that promise to further enhance the determination of solution structures of large proteins and oligonucleotides.     

4D experiments measured with APSY for automated backbone resonance assignments of large proteins

Detailed structural and functional characterization of proteins by solution NMR requires sequence-specific resonance assignment. We present a set of transverse relaxation optimization (TROSY) based four-dimensional automated projection spectroscopy (APSY) experiments which are designed for resonance assignments of proteins with a size up to 40 kDa, namely HNCACO, HNCOCA, HNCACB and HN(CO)CACB. These higher-dimensional experiments include several sensitivity-optimizing features such as multiple quantum parallel evolution in a ‘just-in-time’ manner, aliased off-resonance evolution, evolution-time optimized APSY acquisition, selective water-handling and TROSY. The experiments were acquired within the concept of APSY, but they can also be used within the framework of sparsely sampled experiments. The multidimensional peak lists derived with APSY provided chemical shifts with an approximately 20 times higher precision than conventional methods usually do, and allowed the assignment of 90 % of the backbone resonances of the perdeuterated primase-polymerase ORF904, which contains 331 amino acid residues and has a molecular weight of 38.4 kDa.     

Recommendations for the presentation of NMR structures of proteins and nucleic acids – IUPAC-IUBMB-IUPAB Inter-Union Task Group on the Standardization of Data Bases of Protein and Nucleic Acid Structures Determined by NMR Spectroscopy

The recommendations presented here are designed to support easier communication of NMR data and NMR structures of proteins and nucleic acids through unified nomenclature and reporting standards. Much of this document pertains to the reporting of data in journal articles; however, in the interest of the future development of structural biology, it is desirable that the bulk of the reported information be stored in computer-accessible form and be freely accessible to the scientific community in standardized formats for data exchange. These recommendations stem from an IUPAC-IUBMB-IUPAB inter-union venture with the direct involvement of ICSU and CODATA. The Task Group has reviewed previous formal recommendations and has extended them in the light of more recent developments in the field of biomolecular NMR spectroscopy. Drafts of the recommendations presented here have been examined critically by more than 50 specialists in the field and have gone through two rounds of extensive modification to incorporate suggestions and criticisms.     

Recent advances in segmental isotope labeling of proteins: NMR applications to large proteins and glycoproteins

In the last 15 years substantial advances have been made to place isotope labels in native and glycosylated proteins for NMR studies and structure determination. Key developments include segmental isotope labeling using Native Chemical Ligation, Expressed Protein Ligation and Protein Trans-Splicing. These advances are pushing the size limit of NMR spectroscopy further making larger proteins accessible for this technique. It is just emerging that segmental isotope labeling can be used to define inter-domain interactions in NMR structure determination. Labeling of post-translational modified proteins like glycoproteins remains difficult but some promising developments were recently achieved. Key achievements are segmental and site-specific labeling schemes that improve resonance assignment and structure determination of the glycan moiety. We adjusted the focus of this perspective article to concentrate on the NMR applications based on recent developments rather than on labeling methods themselves to illustrate the considerable potential for biomolecular NMR.     

Simultaneous NMR assignment of backbone and side chain amides in large proteins with IS-TROSY

A new strategy for the simultaneous NMR assignment of both backbone and side chain amides in large proteins with isotopomer-selective transverse-relaxation-optimized spectroscopy (IS-TROSY) is reported. The method considers aspects of both the NMR sample preparation and the experimental design. First, the protein is dissolved in a buffer with 50%H₂O/50%D₂O in order to promote the population of semideuterated NHD isotopomers in side chain amides of Asn/Gln residues. Second, a ¹³C′-coupled 2D ¹⁵N–¹H IS-TROSY spectrum provides a stereospecific distinction between the geminal protons in the E and Z configurations of the carboxyamide group. Third, a suite of IS-TROSY-based triple-resonance NMR experiments, e.g. 3D IS-TROSY-HNCA and 3D IS-TROSY-HNCACB, are designed to correlate aliphatic carbon atoms with backbone amides and, for Asn/Gln residues, at the same time with side chain amides. The NMR assignment procedure is similar to that for small proteins using conventional 3D HNCA/3D HNCACB spectra, in which, however, signals from NH₂ groups are often very weak or even missing due to the use of broad-band proton decoupling schemes and NOE data have to be used as a remedy. For large proteins, the use of conventional TROSY experiments makes resonances of side chain amides not observable at all. The application of IS-TROSY experiments to the 35-kDa yeast cytosine deaminase has established a complete resonance assignment for the backbone and stereospecific assignment for side chain amides, which otherwise could not be achieved with existing NMR experiments. Thus, the development of IS-TROSY-based method provides new opportunities for the NMR study of important structural and biological roles of carboxyamides and side chain moieties of arginine and lysine residues in large proteins as well as amino moieties in nucleic acids.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

A new approach for obtaining sequential assignment of large proteins

A novel NMR experiment for obtaining sequential assignment of large proteins and protein complexes is described. The proposed method takes full advantage of transverse relaxation optimized spectroscopy (TROSY) and utilizes spin-state-selection to distinguish between intraresidual and sequential connectivities in the HNCA-TROSY-type correlation experiment. Thus, the intra- and interresidual cross peaks can be identified without relaying magnetization via carbonyl carbon, which relaxes very rapidly at the high magnetic fields where TROSY is most efficient. In addition, the presented method enables measurement of several scalar and residual dipolar couplings, which can potentially be used for structure determination of large proteins.     

TROSY and CRINEPT: NMR with large molecular and supramolecular structures in solution

TROSY and CRINEPT are new techniques for solution NMR studies of molecular and supramolecular structures. They allow the collection of high-resolution spectra of structures with molecular weights >100 kDa, significantly extending the range of macromolecular systems that can be studied by NMR in solution. TROSY has already been used to map protein-protein interfaces, to conduct structural studies on membrane proteins and to study nucleic acid conformations in multimolecular assemblies. These techniques will help us to investigate the conformational states of individual macromolecular components and will support de novo protein structure determination in large supramolecular structures.     

Perspective: revisiting the field dependence of TROSY sensitivity

The discovery of the TROSY effect (Pervushin et al. in Proc Natl Acad Sci USA 94:12366–12371, 1997) for reducing transverse relaxation and line sharpening through selecting pathways in which dipole–dipole and CSA Hamiltonians partially cancel each other had a tremendous impact on solution NMR studies of macromolecules. Together with the methyl TROSY (Tugarinov and Kay in J Biomol NMR 28:165–172, 2004) it enabled structural and functional studies of significantly larger systems. The optimal field strengths for TROSY have been estimated to be on spectrometers operating around 900 MHz (21.14 T) for the ¹H_N TROSY (Pervushin et al. in Proc Natl Acad Sci USA 94:12366–12371, 1997) while the aromatic ¹³C (¹³C_aro) TROSY is posited to be optimal at around 600 MHz (14.09 T) (Pervushin et al. in J Am Chem Soc 120:6394–6400, 1998b; Pervushin in Q Rev Biophys 33:161–197, 2000). The initial rational was based on the consideration of where the quadratic B₀ field dependences of the TROSY relaxation rates reach a minimum. For sensitivity consideration, however, it is interesting to estimate which field strengths yield the tallest peaks. Recent studies of ¹⁵N-detected TROSYs suggested that maximal peak heights are expected at 1.15 GHz (27.01 T) although the slowest relaxation rates or longest transverse relaxation times T₂ are indeed expected around 900 MHz (21.14 T) (Takeuchi in J Biomol NMR 63:323–331, 2015; Takeuchi et al. in J Biomol NMR 64:143–151, 2016). This was based on the fact that the heights of Lorentzian lines are proportional to B _o ^3/2 * T₂ (B_o). Thus, multiplying the parabolic T₂(B_o) dependence with the increasing function of B _o ^3/2 shifts the maxima of peak-height field dependence from the T₂ maximum at 900 MHz to higher fields. Moreover, besides shifting the peak height maximum for ¹⁵N TROSY, this analysis yields estimates for optimal peak heights for ¹H_N detected TROSY to 1.5 GHz, and to 900 MHz for ¹³C-detected ¹³C_aroTROSY as is detailed below. To our knowledge, this aspect of field dependence of TROSY sensitivity has not been in the attention of the NMR community but may affect perspectives of NMR at ultra-high fields.     

Overcoming the solubility limit with solubility-enhancement tags: successful applications in biomolecular NMR studies

Although the rapid progress of NMR technology has significantly expanded the range of NMR-trackable systems, preparation of NMR-suitable samples that are highly soluble and stable remains a bottleneck for studies of many biological systems. The application of solubility-enhancement tags (SETs) has been highly effective in overcoming solubility and sample stability issues and has enabled structural studies of important biological systems previously deemed unapproachable by solution NMR techniques. In this review, we provide a brief survey of the development and successful applications of the SET strategy in biomolecular NMR. We also comment on the criteria for choosing optimal SETs, such as for differently charged target proteins, and recent new developments on NMR-invisible SETs.     

A novel NMR method for determining the interfaces of large protein-protein complexes

Identification of the interfaces of large (Mr > 50,000) protein-protein complexes in solution by high resolution NMR has typically been achieved using experiments involving chemical shift perturbation and/or hydrogen-deuterium exchange of the main chain amide groups of the proteins. Interfaces identified using these techniques, however, are not always identical to those revealed using X-ray crystallography. In order to identify the contact residues in a large protein-protein complex more accurately, we developed a novel NMR method that uses cross-saturation phenomena in combination with TROSY detection in an optimally deuterium labeled system.     

Recent developments in structural proteomics for protein structure determination

The major challenges in structural proteomics include identifying all the proteins on the genome-wide scale, determining their structure-function relationships, and outlining the precise three-dimensional structures of the proteins. Protein structures are typically determined by experimental approaches such as X-ray crystallography or nuclear magnetic resonance (NMR) spectroscopy. However, the knowledge of three-dimensional space by these techniques is still limited. Thus, computational methods such as comparative and de novo approaches and molecular dynamic simulations are intensively used as alternative tools to predict the three-dimensional structures and dynamic behavior of proteins. This review summarizes recent developments in structural proteomics for protein structure determination; including instrumental methods such as X-ray crystallography and NMR spectroscopy, and computational methods such as comparative and de novo structure prediction and molecular dynamics simulations.     

Recent developments in isotope-aided NMR methods for supramolecular protein complexes –SAIL aromatic TROSY

BackgroundThe structure-function relationships for large protein complexes at the atomic level would be comprehensively understood, if hitherto unexplored aromatic ring NMR signals became accessible in addition to the currently used backbone amide and side-chain methyl signals.MethodsThe 82 kDa malate synthase G (MSG) proteins, selectively labeled with Trp and Phe bearing relaxation optimized isotope-labeled rings, were prepared to investigate the optimal conditions for obtaining the aromatic TROSY spectra.ResultsThe MSG proteins, selectively labeled with either [δ₁,ε₁,ε₃,η₂]-SAIL Trp or ζ-SAIL Phe, provided well-separated, narrow TROSY signals for the 12 Trp and 19 Phe residues in MSG. The signals were assigned sequence-specifically, using the set of single amino acid substitution mutants. The site-specific substitution of each Phe with Tyr or Leu induced substantial chemical shifts for the other aromatic ring signals, allowing us to identify the aromatic clusters in MSG, which were comparable to the structural domains proposed previously.ConclusionsWe demonstrated that the aromatic ring ¹³CH pairs without directly bonded ¹³C and adjacent ¹H spins provide surprisingly narrow TROSY signals, if the rings are surrounded by fully deuterated amino acids. The observed signals can be readily assigned by either the single amino acid substitution or the NOEs between the aromatic and methyl protons, if the methyl assignments are available.General significanceThe method described here should be generally applicable for difficult targets, such as proteins in lipid bilayers or possibly in living cells, thus providing unprecedented opportunities to use these new probes in structural biology.     

Combination of NMR spectroscopy and X-ray crystallography offers unique advantages for elucidation of the structural basis of protein complex assembly

NMR spectroscopy and X-ray crystallography are two premium methods for determining the atomic structures of macro-biomolecular complexes. Each method has unique strengths and weaknesses. While the two techniques are highly complementary, they have generally been used separately to address the structure and functions of biomolecular complexes. In this review, we emphasize that the combination of NMR spectroscopy and X-ray crystallography offers unique power for elucidating the structures of complicated protein assemblies. We demonstrate, using several recent examples from our own laboratory, that the exquisite sensitivity of NMR spectroscopy in detecting the conformational properties of individual atoms in proteins and their complexes, without any prior knowledge of conformation, is highly valuable for obtaining the high quality crystals necessary for structure determination by X-ray crystallography. Thus NMR spectroscopy, in addition to answering many unique structural biology questions that can be addressed specifically by that technique, can be exceedingly powerful in modern structural biology when combined with other techniques including X-ray crystallography and cryo-electron microscopy.     

核磁共振波谱应用于结构生物学的研究进展

综述了核磁共振波谱在结构生物学研究中的进展。在溶液中测定生物大分子的结构,分子大小的限制正被减少,尽管新结构的测定仍然需要付出比较大的努力。核磁共振是一个有效的手段,可用于研究在许多细胞过程中存在的弱的或者瞬态的蛋白质-蛋白质相互作用。结构的柔性在蛋白质分子功能中起了中心作用。由于最近方法学的发展,使NMR可以表征蛋白质的动力学,从而可以对分子机制有新的认识。核磁共振波谱可以在原子分辨率下表征无序的蛋白质系统,可以研究折叠路径。跨膜蛋白在细胞中起了关键作用,这使它们成为药物的靶标。应用液体和固体核磁共振技术已经成功测定了跨膜蛋白质的结构。     

Solution NMR studies of the integral membrane proteins OmpX and OmpA from Escherichia coli

Membrane proteins are usually solubilized in polar solvents by incorporation into micelles. Even for small membrane proteins these mixed micelles have rather large molecular masses, typically beyond 50000 Da. The NMR technique TROSY (transverse relaxation-optimized spectroscopy) has been developed for studies of structures of this size in solution. In this paper, strategies for the use of TROSY-based NMR experiments with membrane proteins are discussed and illustrated with results obtained with the Escherichia coli integral membrane proteins OmpX and OmpA in mixed micelles with the detergent dihexanoylphosphatidylcholine (DHPC). For OmpX, complete sequence-specific NMR assignments have been obtained for the polypeptide backbone. The 13C chemical shifts and nuclear Overhauser effect data then resulted in the identification of the regular secondary structure elements of OmpX/DHPC in solution, and in the collection of an input of conformational constraints for the computation of the global fold of the protein. For OmpA, the NMR assignments are so far limited to about 80% of the polypeptide chain, indicating different dynamic properties of the reconstituted OmpA beta-barrel from those of OmpX. Overall, the present data demonstrate that relaxation-optimized NMR techniques open novel avenues for studies of structure, function and dynamics of integral membrane proteins.     

Exchange-transferred NOE spectroscopy and bound ligand structure determination

The exchange-transferred nuclear Overhauser effect of NMR spectroscopy provides information on small-molecule ligands in association with high-molecular-weight proteins or nucleic acids, or with biomolecular assemblies such as membranes. The method has proved particularly useful for the structural analysis of proton-rich, flexible ligands and for screening mixtures of ligands for binding activity. Recent analysis has established the accuracy of bound peptide structures determined from transferred nuclear Overhauser effect data and that intermolecular spin diffusion effects do not diminish the reliability of the structural result. New applications of the method involve systems of greater complexity, such as membrane-bound receptors and ribosomes. In addition, new experiments have been developed that exploit the transfer of other types of NMR signal (saturation, cross-correlation, dipolar coupling) to obtain structural information.     

TROSY NMR with partially deuterated proteins

TROSY-type optimization of liquid-state NMR experiments is based on the preservation of unique coherence transfer pathways with distinct transverse relaxation properties. The broadband decoupling of the ¹H spins interchanges the TROSY and anti-TROSY magnetization transfer pathways and thus is not used in TROSY-type triple resonance experiments or is replaced with narrowband selective decoupling. To achieve the full advantage of TROSY, the uniform deuteration of proteins is usually required. Here we propose a new and general method for ¹H broadband decoupling in TROSY NMR, which does not compromise the relaxation optimization in the ¹⁵N–¹H moieties, but uniformly and efficiently refocuses the ¹ J _CH scalar coupling evolution in the ¹³C–¹H moieties. Combined with the conventional ²H decoupling, this method enables obtaining high sensitivity TROSY-type triple resonance spectra with partially deuterated or fully protonated ¹³C,¹⁵N labeled proteins.     

NMR of Redox Proteins of Plants, Yeasts and Photosynthetic Bacteria

NMR spectroscopy has evolved dramatically over the past 15 years, establishing a new, reliable methodology for studying biomacromolecules at atomic resolution. The three-dimensional structure and dynamics of a biomolecule or a biomolecular complex is only one of the main types of information available using NMR. The spectral assignment to the specific nuclei of a biostructure is a very precise reflection of their electronic environment. Any change in this environment due to a structural change, the binding of a ligand or the redox state of a redox cofactor, will be very sensitively reported by changes in the different NMR parameters. The capabilities of the NMR method are currently expanding dramatically and it is turning into a powerful means to study biosystems dynamically in exchange between different conformations, exchanging ligands, transient complexes, or the activation/inhibition of regulated enzymes. We review here several NMR studies that have appeared during the past 5 or 6 years in the field of redox proteins of plants, yeasts and photosynthetic bacteria. These new results illustrate the recent biomolecular NMR evolution and provide new physiological models for understanding the different types of electron transfer, including glutaredoxins, thioredoxins and their dependent enzymes, the ferredoxin-NADP oxidoreductase complex, flavodoxins, the plastocyanin-cytochrome f complex, and cytochromes c.     

Advances of high-resolution NMR techniques in the structural and metabolic analysis of plant biochemistry

Rapid progress in instrumentation and software made nuclear magnetic resonance spectroscopy (NMR) one of the most powerful analytical methods in biological sciences. Whereas the development of multidimensional NMR pulse sequences is an ongoing process, a small subset of two-dimensional NMR experiments is typically sufficient for the rapid structure determination of small metabolites. The use of sophisticated three- and four-dimensional NMR experiments enables the determination of the three-dimensional structures of proteins with a molecular weight up to 100 kDa, and solution structures of more than 100 plant proteins have been established by NMR spectroscopy. NMR has also been introduced to the emerging field of metabolomics where it can provide unbiased information about metabolite profiles of plant extracts. In recent times, high-resolution NMR has become a key technology for the elucidation of biosynthetic pathways and metabolite flux via quantitative assessment of multiple isotopologues. This review summarizes some of the recent advances of high-resolution NMR spectroscopy in the field of plant sciences.