Bacteriophage Tail‐Tube Assembly Studied by Proton‐Detected 4D Solid‐State NMR

Zinke, Maximilian; Fricke, Pascal; Samson, Camille; Hwang, Songhwan; Wall, Joseph S.; Zinn‐Justin, Sophie; Lange, Adam

doi:10.1002/ange.201706060

Cited by 6 publications

(2 citation statements)

References 46 publications

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“…(See an elaborate comparison of efficiencies for a deuterated protein spun at 100 kHz by Penzel et al) Figure A and C displays some of those experiments, here employed as purely dipolar versions for assignments of hCAII. These experiments have also been expanded to four dimensions by us and others. ,− More sophisticated magnetization transfer pathways enable correlation between one amide group and either one (3D) or both shifts (4D) of the next one (Figure A (fourth scheme) and D) . At around 60 kHz MAS, the exclusively dipolar transfer pathway of this hNcacoNH (or HNcacoNH) is highly efficient and yields better sensitivity than an hcaCBcaNH under comparable conditions.…”

Section: Assignment Experimentsmentioning

confidence: 96%

Protons as Versatile Reporters in Solid-State NMR Spectroscopy

2018

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Solid-state nuclear magnetic resonance (ssNMR) is a spectroscopic technique that is used for characterization of molecular properties in the solid phase at atomic resolution. In particular, using the approach of magic-angle spinning (MAS), ssNMR has seen widespread applications for topics ranging from material sciences to catalysis, metabolomics, and structural biology, where both isotropic and anisotropic parameters can be exploited for a detailed assessment of molecular properties. High-resolution detection of protons long represented the holy grail of the field. With its high natural abundance and high gyromagnetic ratio, H has naturally been the most important nucleus type for the solution counterpart of NMR spectroscopy. In the solid state, similar benefits are obtained over detection of heteronuclei, however, a rocky road led to its success as their high gyromagnetic ratio has also been associated with various detrimental effects. Two exciting approaches have been developed in recent years that enable proton detection: After partial deuteration of the sample to reduce the proton spin density, the exploitation of protons could begin. Also, faster MAS, nowadays using tiny rotors with frequencies up to 130 kHz, has relieved the need for expensive deuteration. Apart from the sheer gain in sensitivity from choosing protons as the detection nucleus, the proton chemical shift and several other useful aspects of protons have revolutionized the field. In this Account, we are describing the fundamentals of proton detection as well as the arising possibilities for characterization of biomolecules as associated with the developments in our own lab. In particular, we focus on facilitated chemical-shift assignment, structure calculation based on protons, and on assessment of dynamics in solid proteins. For example, the proton chemical-shift dimension adds additional information for resonance assignments in the protein backbone and side chains. Chemical shifts and high gyromagnetic ratio of protons enable direct readout of spatial information over large distances. Dynamics in the protein backbone or side chains can be characterized efficiently using protons as reporters. For all of this, the sample amounts necessary for a given signal-to-noise have drastically shrunk, and new methodology enables assessment of molecules with increasing monomer molecular weight and complexity. Taken together, protons are able to overcome previous limitations, by speeding up processes, enhancing accuracies, and increasing the accessible ranges of ssNMR spectroscopy, as we shall discuss in detail in the following. In particular, these methodological developments have been pushing solid-state NMR into a new regime of biological topics as they realistically allow access to complex cellular molecules, elucidating their functions and interactions in a multitude of ways.

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Section: Assignment Experimentsmentioning

confidence: 96%

Protons as Versatile Reporters in Solid-State NMR Spectroscopy

2018

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“…Solid-state NMR overcomes critical molecular-weight limitations of solution NMR and thus is amenable for characterization of large proteins or protein assemblies. For example, it has been used extensively for structural elucidation of amyloid proteins, which are poorly accessible for more standard structural-biology techniques. − Similarly, detailed insights for supramolecular assemblies like bacterial needle proteins, virus capsid structures, and structural components of bacteriophages are obtained more and more routinely. − Based on partial protein deuteration and/or fast spinning, the detection of protons has recently been used to increase sensitivity and resolution for residue assignment. − Additional advantages include chemical shifts of protons for resonance assignment, − their high gyromagnetic ratio for proton–proton distance restraints, − and assessment of the amide HN pair for characterization of protein backbone dynamics. − Most solid-state NMR’s target proteins comprise large polymeric networks; however, apart from some larger exceptions in the 30 kDa range, − the monomer size of the structures successfully elucidated has rarely been above 15 kDa. This is because the difficulty in assigning proteins with increasing size scales steeply with the molecular weight due to challenges from sensitivity, spectral overlap, and resolution.…”

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Dynamics and Interactions of a 29 kDa Human Enzyme Studied by Solid-State NMR

Vasa

Singh

Rovó

et al. 2018

J. Phys. Chem. Lett.

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Solid-state NMR has been employed for characterization of a broad range of biomacromolecules and supramolecular assemblies. However, because of limitations in sensitivity and resolution, the size of the individual monomeric units has rarely exceeded 15 kDa. As such, enzymes, which are often more complex and comprise long peptide chains, have not been easily accessible, even though manifold desirable information could potentially be provided by solid-state NMR studies. Here, we demonstrate that more than 1200 backbone and side-chain chemical shifts can be reliably assessed from minimal sample quantities for a 29 kDa human enzyme of the carbonic anhydrase family, giving access to its backbone dynamics and intermolecular interactions with a small-molecule inhibitor. The possibility of comprehensive assessment of enzymes in this molecular-weight regime without molecular-tumbling-derived limitations enables the study of residue-specific properties important for their mode of action as well as for pharmacological interference in this and many other enzymes.

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Charakterisierung eines großen Enzym‐Wirkstoff‐Komplexes mittels protonendetektierter Festkörper‐NMR ohne Deuterierung

et al. 2019

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Festkçrper-NMR-Spektroskopie ermçglicht seit einiger Zeit Strukturbiologie mit Kleinstmengen nichtdeuterierter Proteinproben, wodurchd ie biochemische Probenbereitstellung signifikant erleichtert wird. Trotz dieses Fortschrittes hat sich die erfolgreiche und umfassende Charakterisierung komplexerer Spinsysteme bisher auf traditionelle 13 C-detektierte Methodik oder Deuterierung gestützt. Dies gilt insbesondere fürProteine mit hçchstem Molekulargewicht. Anhand eines 29 kDa Carboanhydrase-Acetazolamid-Komplexes zeigen wir hier,d ass verschiedene Bereiche festkçrper-NMRspektroskopischer Charakterisierung eines komplexen Spinsystems mithilfe einer nichtdeuterierten 500 mgP robenmenge erfolgreich bestritten werden kçnnen, wenn adäquate spektroskopische Methodik verwendet wird.

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Bacteriophage Tail‐Tube Assembly Studied by Proton‐Detected 4D Solid‐State NMR

Cited by 6 publications

References 46 publications

Protons as Versatile Reporters in Solid-State NMR Spectroscopy

Protons as Versatile Reporters in Solid-State NMR Spectroscopy

Dynamics and Interactions of a 29 kDa Human Enzyme Studied by Solid-State NMR

Charakterisierung eines großen Enzym‐Wirkstoff‐Komplexes mittels protonendetektierter Festkörper‐NMR ohne Deuterierung

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