Site-Directed Spin Labeling EPR for Studying Membrane Proteins

Sahu, Indra D.; Lorigan, Gary A.

doi:10.1155/2018/3248289

Cited by 48 publications

(38 citation statements)

References 128 publications

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“…CW-EPR spectroscopy of these spin-labeled molecules can reveal information about the motion of the nitroxide side chain, solvent accessibility, and the polarity of the surrounding environment. [21,33] The successful spin labeling of the pinholin protein and incorporation into both bicelle and MLV lipid mimetic systems is shown in the CW-EPR spectra in Figure 5. This EPR data was also used to calculate spin labeling efficiency for each peptide which ranged from ~85-90% labeling efficiency.…”

Section: Continuous Wave Epr Measurements Of Pinholinmentioning

confidence: 99%

“…This decrease in the motion of the MTSL will broaden the lines in the EPR spectra and cause a decrease in their amplitude which is present in Figure 5B. [33,34] The broadening of the EPR spectral linewidth is quantitatively determined by measuring the central line width. In Figure 5A the free MTSL spectra shows a central line width of 1.4 G, while the MTSL bound to the pinholin, 5B, has a central line width of 2.9 G. The line broadening of the EPR spectra from Figure 5A to 5B confirms the successful disulfide bond formation between the free MTSL and the Cys side chain of the pinholin due to a more restricted environment for the bound SL.…”

Section: Continuous Wave Epr Measurements Of Pinholinmentioning

confidence: 99%

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Solid phase synthesis and spectroscopic characterization of the active and inactive forms of bacteriophage S21 pinholin protein

Drew

Ahammad

Serafin

et al. 2019

Analytical Biochemistry

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The mechanism for the lysis pathway of double-stranded DNA bacteriophages involves a small hole-forming class of membrane proteins, the holins. This study focuses on a poorly characterized class of holins, the pinholin, of which the S 21 protein of phage φ21 is the prototype. Here we report the first in vitro synthesis of the wildtype form of the S21 pinholin, S 21 68, and negativedominant mutant form, S 21 IRS, both prepared using solid phase peptide synthesis and studied using biophysical techniques. Both forms of the pinholin were labeled with a nitroxide spin label and successfully incorporated into both bicelles and multilamellar vesicles which are membrane mimetic systems. Circular dichroism revealed the two forms were both >80% alpha helical, in agreement with the predictions based on the literature. The molar ellipticity ratio [θ] 222 / [θ] 208 for both forms of the pinholin was 1.4, suggesting a coiled-coil tertiary structure in the bilayer consistent with the proposed oligomerization step in models for the mechanism of hole formation. 31 P solid-state NMR spectroscopic data on pinholin indicate a strong interaction of both forms of the pinholin with the membrane headgroups. The 31 P NMR data has an axially symmetric line shape which is consistent with lamellar phase proteoliposomes lipid mimetics.

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Section: Continuous Wave Epr Measurements Of Pinholinmentioning

confidence: 99%

Section: Continuous Wave Epr Measurements Of Pinholinmentioning

confidence: 99%

Solid phase synthesis and spectroscopic characterization of the active and inactive forms of bacteriophage S21 pinholin protein

Drew

Ahammad

Serafin

et al. 2019

Analytical Biochemistry

Self Cite

View full text Add to dashboard Cite

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“…In nitroxide-labeled proteins lacking native paramagnetic centers, CW EPR records only the absorption spectrum of the nitroxide radical, usually in the form of the first derivative. The spectrum exhibits characteristic three lines, whose linewidths and amplitudes depend on the intrinsic spin label dynamics caused mainly by the rotational diffusion of the nitroxide moiety in the local potential and to some extent by the protein dynamics in its immediate vicinity as well as the protein global tumbling, segmental motion or chemical exchange [ 52 , 53 , 54 ]. In general, the frequencies of these motions observed by nitroxide multifrequency CW EPR fall into the range of rotational correlation time (τ c ) ≅ 10 −12 –10 −8 s. The anisotropy of hyperfine interaction (hfi) tensor and g-tensor, partly averaged by motions, produces typical asymmetric spectrum with the high-field side being broader.…”

Section: Epr Spectroscopy Of Spin-labeled Proteinsmentioning

confidence: 99%

Protein Conformational Dynamics upon Association with the Surfaces of Lipid Membranes and Engineered Nanoparticles: Insights from Electron Paramagnetic Resonance Spectroscopy

Georgieva

2020

Molecules

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Detailed study of conformational rearrangements and dynamics of proteins is central to our understanding of their physiological functions and the loss of function. This review outlines the applications of the electron paramagnetic resonance (EPR) technique to study the structural aspects of proteins transitioning from a solution environment to the states in which they are associated with the surfaces of biological membranes or engineered nanoobjects. In the former case these structural transitions generally underlie functional protein states. The latter case is mostly relevant to the application of protein immobilization in biotechnological industries, developing methods for protein purification, etc. Therefore, evaluating the stability of the protein functional state is particularly important. EPR spectroscopy in the form of continuous-wave EPR or pulse EPR distance measurements in conjunction with protein spin labeling provides highly versatile and sensitive tools to characterize the changes in protein local dynamics as well as large conformational rearrangements. The technique can be widely utilized in studies of both protein-membrane and engineered nanoobject-protein complexes.

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“…First, diffusivities can be determined from a variety of methods, including fluorescence techniques such as fluorescence recovery after photobleaching (FRAP) and fluorescence correlation spectroscopy (FCS), quasi-elastic neutron scattering, EPR, and NMR, amongst others. The length and time scale of study can vary significantly with different methods; for example, EPR and NMR (O(1 nm-100 µm),O(1 ns-1 ms)) [150][151][152][153] and quasi-elastic neutron scattering (O(0.1-10 nm,<1 ns)) [44]. Furthermore, neutron spin echo spectroscopy has recently been shown to probe ∼100 ns and obtain membrane viscosity estimates that can be used to estimate in-plane diffusivity [154].…”

Section: Nuances To Diffusivity Calculationsmentioning

confidence: 99%

Simulation Best Practices for Lipid Membranes [Article v1.0]

Smith¹,

Klauda²,

Sodt³

2019

LiveCoMS

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We establish a reliable and robust standardization of settings for practical molecular dynamics (MD) simulations of pure and mixed (single-and multi-component) lipid bilayer membranes. In lipid membranes research, particle-based molecular simulations are a powerful tool alongside continuum theory, lipidomics, and model, in vitro, and in vivo experiments. Molecular simulations can provide precise and reproducible spatiotemporal (atomic-and femtosecond-level) information about membrane structure, mechanics, thermodynamics, kinetics, and dynamics. Yet the simulation of lipid membranes can be a daunting task, given the uniqueness of lipid membranes relative to conventional liquid-liquid and solid-liquid interfaces, the immense and complex thermodynamic and statistical mechanical theory, the diversity of multiscale lipid models, limitations of modern computing power, the difficulty and ambiguity of simulation controls, finite size effects, competitive continuum simulation alternatives, and the desired application, including vesicle experiments and biological membranes. These issues can complicate an essential understanding of the field of lipid membranes, and create major bottlenecks to simulation advancement. In this article, we clarify these issues and present a consistent, thorough, and user-friendly framework for the design of state-of-the-art lipid membrane MD simulations. We hope to allow early-career researchers to quickly overcome common obstacles in the field of lipid membranes and reach maximal impact in their simulations.

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Site-Directed Spin Labeling EPR for Studying Membrane Proteins

Cited by 48 publications

References 128 publications

Solid phase synthesis and spectroscopic characterization of the active and inactive forms of bacteriophage S21 pinholin protein

Solid phase synthesis and spectroscopic characterization of the active and inactive forms of bacteriophage S21 pinholin protein

Protein Conformational Dynamics upon Association with the Surfaces of Lipid Membranes and Engineered Nanoparticles: Insights from Electron Paramagnetic Resonance Spectroscopy

Simulation Best Practices for Lipid Membranes [Article v1.0]

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