NMR Spectroscopy of Native and in Vitro Tissues Implicates PolyADP Ribose in Biomineralization

Chow, Wing Ying; Rajan, Rakesh; Müller, Karin H.; Reid, David G.; Skepper, Jeremy N.; Wong, Wai Ching; Brooks, Roger A.; Green, Maggie; Bihan, Dominique; Farndale, Richard W.; Slatter, David A.; Shanahan, Catherine M.; Duer, Melinda J.

doi:10.1126/science.1248167

Cited by 82 publications

(94 citation statements)

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“…their effective use could be applied to a much wider array of molecules including biomolecules labeled in mammalian systems (44). However, although amide proton assignment is possible for fully protonated proteins above 40-kHz MAS (45)(46)(47)(48), proton resonances remain significantly dipolar broadened at 40-60 kHz, limiting the applicability of this spinning regime for side-chain assignment and structure determination (41,45,(49)(50)(51).…”

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confidence: 99%

Structure of fully protonated proteins by proton-detected magic-angle spinning NMR

Andreas

Jaudzems

Staněk

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

232

293

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Protein structure determination by proton-detected magic-angle spinning (MAS) NMR has focused on highly deuterated samples, in which only a small number of protons are introduced and observation of signals from side chains is extremely limited. Here, we show in two fully protonated proteins that, at 100-kHz MAS and above, spectral resolution is high enough to detect resolved correlations from amide and side-chain protons of all residue types, and to reliably measure a dense network of 1 H-1 H proximities that define a protein structure. The high data quality allowed the correct identification of internuclear distance restraints encoded in 3D spectra with automated data analysis, resulting in accurate, unbiased, and fast structure determination. Additionally, we find that narrower proton resonance lines, longer coherence lifetimes, and improved magnetization transfer offset the reduced sample size at 100-kHz spinning and above. Less than 2 weeks of experiment time and a single 0.5-mg sample was sufficient for the acquisition of all data necessary for backbone and side-chain resonance assignment and unsupervised structure determination. We expect the technique to pave the way for atomic-resolution structure analysis applicable to a wide range of proteins.NMR spectroscopy | magic-angle spinning | protein structures | proton detection | viral nucleocapsids D espite tremendous progress in the analysis of biomolecular samples over the last two decades (1-7), routine application of magic-angle spinning (MAS) NMR in biology is still limited by the inherently low sensitivity. The direct detection of proton resonances is a straightforward way to counter this problem, but entails a trade-off with resolution due to the strong homonuclear dipolar interactions among proton nuclei. High-resolution proton-detected methods were first demonstrated with modest spinning frequencies by today's standards (∼10 kHz) and relied on a reduction of 1 H-1 H couplings by high levels of dilution with deuterium, typically perdeuteration, and complete (8, 9) or partial (10-12) protonation at exchangeable sites. The need for narrow proton resonances without such extreme levels of deuteration has motivated a continuous technological development, resulting in a dramatic increase in the available spinning frequency (13)(14)(15)(16)(17)(18)(19)(20).At MAS frequencies of 40-60 kHz, deuteration and 100% reprotonation at exchangeable sites, primarily amide protons, result in resolved and sensitive spectra, similar in quality to the case of higher dilution levels and lower spinning frequencies (21-23). This opens the way to rapid sequential assignment of backbone resonances (24-27), as well as to the unambiguous measurement of detailed structural and dynamical parameters (28-32). A further increase in the MAS frequency to 100 kHz allows resonance assignment (20), a structure determination of a model protein (16), and interaction studies (15) with as little as 0.5 mg of sample. However, a high deuteration level severely limits observation of side-chain s...

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confidence: 99%

Structure of fully protonated proteins by proton-detected magic-angle spinning NMR

Andreas

Jaudzems

Staněk

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

232

293

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“…Thus, our first work with our NMR-based molecular fingerprints of native bone tissue was to develop an in vitro tissue that at the atomic scale, as judged by NMR and at the nanoscopic lengthscale as judged by SEM and AFM (Fig. 4), was as similar as possible to native tissue [45]. Interestingly, the differences between NMR signals we found from in vitro grown tissues and those from native tissues were from proline-/ glycine-rich peptides with 13 C chemical shifts consistently higher than those for a collagen triple helix structure.…”

Section: Probing the Organic Matrix Structurementioning

confidence: 98%

“…Bone collagen had one of the highest levels of enrichment using this approach, between 80% and 90%. Our aim here [45] was to be able to record multidimensional correlation NMR spectra of intact, native tissues in which the full chemical shift distributions of all essential amino acid 13 C and 15 N were resolved and correlated with the chemical shift distributions of all spatially-close 13 C and 15 N. We argued that a set of such spectra, correlating both 13 C with 13 C and 13 C with 15 N, and for different spectral mixing times, i.e. different upper internuclear distance constraints on the observed spectral correlations, together constituted a ''fingerprint'' of the underlying molecular structures.…”

Section: Probing the Organic Matrix Structurementioning

confidence: 99%

The contribution of solid-state NMR spectroscopy to understanding biomineralization: Atomic and molecular structure of bone

Duer

2015

Journal of Magnetic Resonance

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“…tryptophan, in the algal hydrolysate (see Supplementary Table S1 for comparison of amino acid contents of the two feedstocks). In the rapid turnover bone collagen, feeding with labelled diet during adulthood only produces 2.9-fold spectral enhancement, which corresponds to sufficient labelling for structurally meaningful 2D spectroscopy (Chow et al 2014). The meagre isotope enrichment of only 1.6-fold produced by adult feeding in fur keratin (typifying a slow turnover tissue) is quite insufficient for this purpose.…”

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confidence: 99%

“…In previously published work (Chow et al 2014) we achieved levels of 13 C labelling in some tissues, sufficient for high quality 2D NMR, by simply feeding labelled diet to an adult mouse for about three weeks. Using this protocol, however, the level of labelling varied widely between different tissue types, being among the highest in bone collagen, and barely detectable in slower turnover biomaterials such as fur keratin, among others, precluding any structurally informative 2D experiments in the latter.…”

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Preparation of highly and generally enriched mammalian tissues for solid state NMR

et al. 2015

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An appreciable level of isotope labelling is essential for future NMR structure elucidation of mammalian biomaterials, which are either poorly expressed, or unexpressable, using micro-organisms. We present a detailed protocol for high level 13 C enrichment even in slow turnover murine biomaterials (fur keratin), using a customized diet supplemented with commercial labelled algal hydrolysate and formulated as a gel to minimize wastage, which female mice consumed during pregnancy and lactation. This procedure produced approximately eightfold higher fur keratin labelling in pups, exposed in utero and throughout life to label, than in adults exposed for the same period, showing both the effectiveness, and necessity, of this approach.Keywords Carbon-13 Á In vivo Á Fur keratin Á Bone collagen Á Labelling Á Mouse Biomacromolecular structure determination by NMR has been revolutionized by the availability of target molecules, proteins and nucleic acids, enriched in NMR active ( 13 C, 15 N) or effectively ''invisible'' ( 2 H) isotopes (Saxena et al. 2012;Verardi et al. 2012;Wagner 2010). These are usually, and increasingly routinely, prepared by producing the requisite quantities of the molecular targets in a micro-organism expression system, genetically engineered as necessary, with subsequent isolation and purification. Hitherto the overwhelming focus has been on the production of pure biomolecules for structure elucidation and intermolecular interaction studies, and in the case of solid-state NMR, ordered ensembles of small and fairly pure biomolecules. There is an ongoing effort to increase the molecular weight limits of structures elucidated by solid-state NMR, either of proteins associated with lipid membranes, or fibrils and supramolecular structures formed from soluble subunits. There is increasing realization that, important and enlightening as the resultant information is, this approach cannot be directly applied to a huge body of biomaterials, such as the large (over 300 amino acids per chain) fibrous proteins, most importantly the collagens and keratins, comprising the extracellular matrices (ECM) of connective and structural tissues such as bone, cartilage, skin, and hair. These materials present formidable challenges for atomic level structure determination for other reasons besides their sheer size. Repetitive sequences and structural motifs exacerbate already serious issues of spectral overlap, and the commonly used micro-organism expression systems cannot reproduce the complex and specific post-translational modifications necessary for faithful assembly into native structures and cellular function, or the folding and chaperoning machinery essential for ultimate conformational integrity. To extend the power of

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NMR Spectroscopy of Native and in Vitro Tissues Implicates PolyADP Ribose in Biomineralization

Cited by 82 publications

References 53 publications

Structure of fully protonated proteins by proton-detected magic-angle spinning NMR

Structure of fully protonated proteins by proton-detected magic-angle spinning NMR

The contribution of solid-state NMR spectroscopy to understanding biomineralization: Atomic and molecular structure of bone

Preparation of highly and generally enriched mammalian tissues for solid state NMR

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