Insight into small molecule binding to the neonatal Fc receptor by X-ray crystallography and 100 kHz magic-angle-spinning NMR

Stöppler, Daniel; Macpherson, Alex; Smith-Penzel, Susanne; Basse, Nicolas; Lecomte, Fabien; Deboves, Hervé; Norman, Tim; Porter, John; Waters, Lorna C.; Westwood, Marta; Cossins, Ben; Cain, Katharine; White, James H.; Griffin, Robert; Prosser, Christine E.; Kelm, Sebastian; Sullivan, Amy; Fox, David; Carr, Mark D.; Henry, Alistair J.; Taylor, Richard D.; Meier, Beat H.; Oschkinat, Hartmut; Lawson, Alastair D. G.

doi:10.1371/journal.pbio.2006192

Cited by 30 publications

(30 citation statements)

References 77 publications

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“…Sample preparation by sedimentation allowed for the investigation of proteins that are difficult (or even impossible) to crystallize. Theoretically, the molecular mass of the protein determines the success of sedimentation, and proteins, such as the RNA polymerase subunits Rpo4/7 * (the * indicates that the Rpo7 unit is uniformly 13 C/ 15 N labeled) with a molecular weight of 34 kDa (Torosyan et al, 2019), the pRN1 primase with 40 kDa (Boudet et al, 2019), the neonatal Fc receptor with 40 kDa (Stöppler et al, 2018) as well as the human superoxide dismutase with 32 kDa (Fragai et al, 2013), the bacterial helicase DnaB with 708 kDa (Gardiennet et al, 2012), the iron-storage protein ferritin with 480 kDa (Bertini et al, 2012), a variety of supramolecular assemblies (Lecoq et al, 2018;Gauto et al, 2019), and PEGylated proteins (Ravera et al, 2016), were shown to form sediments suitable for solid-state NMR. This is for some of these systems probably a consequence of oligomerization that has been induced by the high protein concentrations (Bertini et al, 2013;Fragai et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Sedimentation Yields Long-Term Stable Protein Samples as Shown by Solid-State NMR

Wiegand

Lacabanne

Torosyan

et al. 2020

Front. Mol. Biosci.

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Today, the sedimentation of proteins into a magic-angle spinning (MAS) rotor gives access to fast and reliable sample preparation for solid-state Nuclear Magnetic Resonance (NMR), and this has allowed for the investigation of a variety of noncrystalline protein samples. High protein concentrations on the order of 400 mg/mL can be achieved, meaning that around 50-60% of the NMR rotor content is protein; the rest is a buffer solution, which includes counter ions to compensate for the charge of the protein. We have demonstrated herein the long-term stability of four sedimented proteins and complexes thereof with nucleotides, comprising a bacterial DnaB helicase, an ABC transporter, an archaeal primase, and an RNA polymerase subunit. Solid-state NMR spectra recorded directly after sample filling and up to 5 years later indicated no spectral differences and no loss in signal intensity, allowing us to conclude that protein sediments in the rotor can be stable over many years. We have illustrated, using an example of an ABC transporter, that not only the structure is maintained, but that the protein is still functional after long-term storage in the sedimented state.

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Section: Introductionmentioning

confidence: 99%

“…Protein-protein complexes were studied by co-sedimentation (Gardiennet et al, 2016;Xiang et al, 2018) and protein-ligand complexes by sedimentation with the respective ligand (e.g. nucleic acids) directly into the NMR rotor (Wiegand et al, 2016a;Kaur et al, 2018;Stöppler et al, 2018;Lacabanne et al, 2019b).…”

Section: Introductionmentioning

confidence: 99%

Sedimentation Yields Long-Term Stable Protein Samples as Shown by Solid-State NMR

Wiegand

Lacabanne

Torosyan

et al. 2020

Front. Mol. Biosci.

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“…These interactions have been typicallys tudied in the past by high-resolution X-ray crystallography. [14][15][16][17][18][19][20][21][22][23] Proton chemical-shift values are highly sensitivet oh ydrogen bonding [24][25][26][27] as shown in theoretical, [26,27] buta lso in experimental studies. [8] And indeed, solid-state NMR spectroscopy has been used to identify residues at protein-RNA interfaces in smaller proteins.…”

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confidence: 96%

“…[9] Intermolecular information can also be obtained from 31 P-detected, heteronuclear correlation experimentsp robingt he spatial proximity of nucleotide 31 Pa nd protein 15 No r 13 Cn uclei. [14][15][16][17][18][19][20][21][22][23] Proton chemical-shift values are highly sensitivet oh ydrogen bonding [24][25][26][27] as shown in theoretical, [26,27] buta lso in experimental studies. [14][15][16][17][18][19][20][21][22][23] Proton chemical-shift values are highly sensitivet oh ydrogen bonding [24][25][26][27] as shown in theoretical, [26,27] buta lso in experimental studies.…”

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confidence: 96%

Nucleotide Binding Modes in a Motor Protein Revealed by ³¹P‐ and ¹H‐Detected MAS Solid‐State NMR Spectroscopy

et al. 2019

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Protein-nucleic acidi nteractions play important roles not only in energy-providing reactions,s uch as ATPh ydrolysis, but also in reading, extending, packaging, or repairing genomes. Althought hey can often be analyzed in detail with X-ray crystallography, complementary methods are neededt ov isualize them in complexes, which are not crystalline. Here, we show how solid-stateN MR spectroscopy can detecta nd classify protein-nucleic interactions through site-specific 1 H-and 31 P-detected spectroscopicm ethods. The sensitivity of 1 Hc hemicalshift values on noncovalent interactions involved in these molecular recognition processes is exploiteda llowing us to probe directly the chemical bonding state, an information, which is not directly accessible from an X-ray structure. We show that these methods can characterize interactions in easy-to-prepare sediments of the 708 kDa dodecamericD naB helicasei nc omplex with ADP:AlF 4 À :DNA, and this despite the very challenging size of the complex.Nucleotide-protein interactions playacentral role in two major biological functions:i ne nergy-providing reactions, where ATPi sh ydrolyzed to yield energy to motor domains driving reactions [1,2] and in interactions with RNA or DNA, central in al arge variety of biomolecular functions. Binding of nucleotides, such as ATPa nd DNA, occurs throughn oncovalent interactions includingh ydrogen bonds, electrostatic (salt bridges), and van der Waals interactions [3,4] (the latter also comprising interactions between aromatic rings [5] ). These interactions have been typicallys tudied in the past by high-resolution X-ray crystallography. [4,6,7] Still, many of the scenarios described above involve protein complexes, which are difficult to crystallize, and when they do so, might reflect at insufficient resolution to clearly identify interactions.A lternative methods are therefore neededa nd can be providedt hrough solid-state NMR spectroscopy,w hich can access also large biomolecular complexes,a nd importantly in sample formats where the assemblies are simply sedimented into the NMR rotor. [8] And indeed, solid-state NMR spectroscopy has been used to identify residues at protein-RNA interfaces in smaller proteins. [9][10][11][12] Twoa pproaches are particularly promising to probe nucleotide interactions:p hosphorus-( 31 P) and proton-( 1 H) detected spectroscopy.D istances between 31 Ps pins of DNA and 15 N spins of ap rotein have been measuredb yu sing transferredecho, double-resonance (TEDOR) experiments. [9] Intermolecular information can also be obtained from 31 P-detected, heteronuclear correlation experimentsp robingt he spatial proximity of nucleotide 31 Pa nd protein 15 No r 13 Cn uclei. [9,13] Proton-detected solid-state NMR spectroscopy at fast MAS frequencies has emerged in the last years and needs today only af ew hundred micrograms of fully protonated protein sample. [14][15][16][17][18][19][20][21][22][23] Proton chemical-shift values are highly sensitivet oh ydrogen bonding [24][25][26][27] as shown in theoretical, [26,27] ...

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“…Continuous technological and conceptual developments have endowed contemporary high‐resolution solid‐state nuclear magnetic resonance (NMR) spectroscopy, with capabilities that rival those of solution‐state NMR when tackling structural and dynamic investigations of large biomolecules . When performing such studies the problem of spectral assignment and resolution nearly invariably arises, demanding the use of high‐dimensional NMR experiments correlating labeled 13 C‐ and/or 15 N sites in the biomolecule.…”

Section: Introductionmentioning

confidence: 99%

An Efficient, Robust New Scheme for Establishing Broadband Homonuclear Correlations in Biomolecular Solid State NMR

Frydman

2020

ChemPhysChem

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An efficient mixing scheme is introduced for establishing two‐dimensional (2D) homonuclear correlations based on dipolar couplings. This mixing scheme achieves broadband dipolar recoupling using remarkably low powers even under ultrafast magic‐angle spinning (MAS) rates. This Adiabatic Linearly FREquency Swept reCOupling (AL FRESCO) method applies a series of weak frequency‐chirped pluses on the 1H channel, for performing efficient 13C−13C magnetization transfers leading to cross peaks between sites separated over small or large chemical shift differences. The mixing scheme is nearly free from dipolar truncation effects, and thanks to the low RF powers it involves it can act over long mixing times (≥1.5 sec). Key considerations required for optimizing this chirped pulse mixing scheme are discussed, and the new kind of correlations that can emerge from this method are demonstrated using uniformly 13C‐labeled Barstar as test protein sample.

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Insight into small molecule binding to the neonatal Fc receptor by X-ray crystallography and 100 kHz magic-angle-spinning NMR

Cited by 30 publications

References 77 publications

Sedimentation Yields Long-Term Stable Protein Samples as Shown by Solid-State NMR

Sedimentation Yields Long-Term Stable Protein Samples as Shown by Solid-State NMR

Nucleotide Binding Modes in a Motor Protein Revealed by ³¹P‐ and ¹H‐Detected MAS Solid‐State NMR Spectroscopy

An Efficient, Robust New Scheme for Establishing Broadband Homonuclear Correlations in Biomolecular Solid State NMR

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Insight into small molecule binding to the neonatal Fc receptor by X-ray crystallography and 100 kHz magic-angle-spinning NMR

Cited by 30 publications

References 77 publications

Sedimentation Yields Long-Term Stable Protein Samples as Shown by Solid-State NMR

Sedimentation Yields Long-Term Stable Protein Samples as Shown by Solid-State NMR

Nucleotide Binding Modes in a Motor Protein Revealed by 31P‐ and 1H‐Detected MAS Solid‐State NMR Spectroscopy

An Efficient, Robust New Scheme for Establishing Broadband Homonuclear Correlations in Biomolecular Solid State NMR

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Nucleotide Binding Modes in a Motor Protein Revealed by ³¹P‐ and ¹H‐Detected MAS Solid‐State NMR Spectroscopy