Determination of Membrane Protein Structures Using Solution and Solid-State NMR

Montaville, Pierre; Jamin, Nadège

doi:10.1007/978-1-60761-762-4_14

Cited by 6 publications

(5 citation statements)

References 58 publications

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“…The relative percent yields of the three most important products obtained by chemical trapping with each of these nucleophiles were renormalized and are listed in Table 2. 16-ArN 2 + also reacts with primary and secondary amide 43 The percentage yields substituted into the normalized yields equation can be found in Tables S3b-1, S3b-2, S3c-1, and S3c-2 of the Supporting Information. nitrogens (SLG), and observable products are not formed from tertiary amides such as the amide nitrogen on SLS.…”

Section: ■ Resultsmentioning

confidence: 99%

“…For example, X-ray crystallography (XRC) provides detailed information on the structures of membrane proteins; ,, however, the crystals are located not within a membrane bilayer, but in protein–detergent complexes. ,,− Nuclear magnetic resonance (NMR) spectroscopy provides information on the entire protein structure and potentially the surrounding bilayer lipids. , The polarity of the local environment can be obtained from Hα, 13 Cα, and HN nuclei and also from water–amide exchange measurements . However, high-resolution spectra require substantial protein concentrations, , and both size limits ,, and line broadening can be a problem. Circular dichroism (CD) reports the fractions of the protein in its secondary conformations, − infrared spectroscopy (IR) provides information on the secondary structure of the protein by detecting the change of the hydrogen-bonding interactions of amide groups within the proteins, , and both methods provided information on protein orientation in vesicles .…”

Section: Introductionmentioning

confidence: 99%

“…1,14 The polarity of the local environment can be obtained from Hα, 13 Cα, and HN nuclei and also from water−amide exchange measurements. 15 However, high-resolution spectra require substantial protein concentrations, 7,16 and both size limits 7,14,17 and line broadening 1 can be a problem. Circular dichroism (CD) reports the fractions of the protein in its secondary conformations, 18−21 infrared spectroscopy (IR) provides information on the secondary structure of the protein by detecting the change of the hydrogen-bonding interactions of amide groups within the proteins, 22,23 and both methods provided information on protein orientation in vesicles.…”

Section: ■ Introductionmentioning

confidence: 99%

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Simultaneous Determination of Interfacial Molarities of Amide Bonds, Carboxylate Groups, and Water by Chemical Trapping in Micelles of Amphiphiles Containing Peptide Bond Models

Zhang

Romsted

Zhuang³

et al. 2012

Langmuir

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Chemical trapping is a powerful approach for obtaining experimental estimates of interfacial molarities of weakly basic nucleophiles in the interfacial regions of amphiphile aggregates. Here, we demonstrate that the chemical probe 4-hexadecyl-2,6-dimethylbenzenediazonium ion (16-ArN(2)(+)) reacts competitively with interfacial water, with the amide carbonyl followed by cleavage of the headgroups from the tail at the amide oxygen, and with the terminal carboxylate groups in micelles of two N-acyl amino-acid amphiphiles, sodium N-lauroylsarcosinate (SLS) and sodium N-lauroylglycinate (SLG), simple peptide bond model amphiphiles. Interfacial molarities (in moles per liter of interfacial volume) of these three groups were obtained from product yields, assuming that selectivity toward a particular nucleophile compared to water is the same in an aqueous reference solution and in the interfacial region. Interfacial carboxylate group molarities are ~1.5 M in both SLS and SLG micelles, but the concentration of the amide carbonyl for SLS micelles is ~4.6-5 times less (ca. 0.7 M) than that of SLG micelles (~3 M). The proton on the secondary N of SLG helps solubilize the amide bond in the aqueous region, but the methyl on the tertiary N of SLS helps solubilize the amide bond in the micellar core, reducing its reaction with 16-ArN(2)(+). Application of chemical trapping to proteins in membrane mimetic interfaces should provide insight into the topology of the protein within the interface because trapping of the amide carbonyl and cleavage at the C-N bond occurs only within the interface, and fragment characterization marks those peptide bonds located within the interface.

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Section: ■ Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Simultaneous Determination of Interfacial Molarities of Amide Bonds, Carboxylate Groups, and Water by Chemical Trapping in Micelles of Amphiphiles Containing Peptide Bond Models

Zhang

Romsted

Zhuang³

et al. 2012

Langmuir

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“…43,44 Differentiated mesenchymal stem cells synthesize and secrete neurotrophins. 45 Similarly, it has been reported that differentiated mesenchymal stem cells have the potential to infl uence the expression of growth factors and myelination of axons in different levels.4 6,47 However, Wang et al, 2009, reports that bone marrow induced stem cells increase peripheral nerve regeneration not only by secreting neurotrophic factors, but also indirectly by affecting Schwann cell proliferation rate. 36 Although bone marrow stem cells are more easily obtained when compared with embryonic stem cells, their proliferation capacity is less when compared with embryonic stem cells.…”

Section: Bone Marrow Derived Stem Cellsmentioning

confidence: 99%

Periferik Sinir Rejenerasyonu ve Kök Hücre Tedavileri

Him

Önger

Delibaş

2018

Sakarya Medical Journal

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In this review, authors aimed to give information about the recent development about the use of stem cell transplantation in damaged nerve repair and highlight the key scientifi c studies. Although peripheral nerves show the potential of regenerating the axon and reinnerveting their target tissues, the recovery after intense nerve injury remains relatively poor. Schwann cells play important role in the regeneration success of peripheral nerves. Given that Schwann cells of the denervated peripheral nerve appear to become incapable in regeneration, it has been considered a reasonable approach to support the distal denervated nerve environment with exogenously derived host cells. The effects of various stem cells on peripheral nerve regeneration have been investigated. Skin, bone marrow and adipose derived stem cells were indicated as the most promising candidates with their potentials of converting into Schwann cells. Beside the application of pluripotent induced stem cell trials; recent studies have demonstrated that induced expression of growth factors in stem cells has more potential in regeneration. Although the stem cells were considered as effi cient resources and promising agents in nerve regeneration there is no optimization of these therapies yet for their potential to be realized in a clinical setting.

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“…Since ClC-ec1 is an alpha helical dimer of 50 kD per subunit, we aimed not to attempt the heroic feat of full NMR solution-state structure determination (Montaville and Jamin 2010), but rather to employ sparse labeling strategies that would minimize signal overlap, facilitate peak assignment and allow us to identify additional regions of conformational change. We targeted 13 C-methyl groups because the intrinsic sensitivity of three protons coupled to one carbon together with favorable relaxation properties make them well suited to the solution-state study of high-molecular-weight systems (Beatty et al 1996; Butterfoss et al 2010; DellaVecchia et al 2007; Mainz et al 2013; Religa et al 2011), including membrane proteins, where size is exacerbated by the surrounding detergent micelle or lipid bicelle (Kang and Li 2011; Kim et al 2009; Sanders and Sonnichsen 2006).…”

Section: Introductionmentioning

confidence: 99%

13C NMR detects conformational change in the 100-kD membrane transporter ClC-ec1

et al. 2015

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CLC transporters catalyze the exchange of Cl- for H+ across cellular membranes. To do so, they must couple Cl- and H+ binding and unbinding to protein conformational change. However, the sole conformational changes distinguished crystallographically are small movements of a glutamate side chain that locally gates the ion-transport pathways. Therefore, our understanding of whether and how global protein dynamics contribute to the exchange mechanism has been severely limited. To overcome the limitations of crystallography, we used solution-state 13C-methyl NMR with labels on methionine, lysine, and engineered cysteine residues to investigate substrate (H+) dependent conformational change outside the restraints of crystallization. We show that methyl labels in several regions report H+-dependent spectral changes. We identify one of these regions as Helix R, a helix that extends from the center of the protein, where it forms the part of the inner gate to the Cl--permeation pathway, to the extracellular solution. The H+-dependent spectral change does not occur when a label is positioned just beyond Helix R, on the unstructured C-terminus of the protein. Together, the results suggest that H+ binding is mechanistically coupled to closing of the intracellular access-pathway for Cl-.

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Determination of Membrane Protein Structures Using Solution and Solid-State NMR

Cited by 6 publications

References 58 publications

Simultaneous Determination of Interfacial Molarities of Amide Bonds, Carboxylate Groups, and Water by Chemical Trapping in Micelles of Amphiphiles Containing Peptide Bond Models

Simultaneous Determination of Interfacial Molarities of Amide Bonds, Carboxylate Groups, and Water by Chemical Trapping in Micelles of Amphiphiles Containing Peptide Bond Models

Periferik Sinir Rejenerasyonu ve Kök Hücre Tedavileri

13C NMR detects conformational change in the 100-kD membrane transporter ClC-ec1

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