[NMR paper] Single-Molecule Force Spectroscopy Trajectories of a Single Protein and Its Polyproteins Are Equivalent: A Direct Experimental Validation Based on A Small Protein NuG2
Single-Molecule Force Spectroscopy Trajectories of a Single Protein and Its Polyproteins Are Equivalent: A Direct Experimental Validation Based on A Small Protein NuG2
Single-molecule force spectroscopy (SMFS) has become a powerful tool in investigating the mechanical unfolding/folding of proteins at the single-molecule level. Polyproteins made of tandem identical repeats have been widely used in atomic force microscopy (AFM)-based SMFS studies, where polyproteins not only serve as fingerprints to identify single-molecule stretching events, but may also improve statistics of data collection. However, the inherent assumption of such experiments is that all the domains in the polyprotein are equivalent and one SMFS trajectory of stretching a polyprotein made of n domains is equivalent to n trajectories of stretching a single domain. Such an assumption has not been validated experimentally. Using a small protein NuG2 and its polyprotein (NuG2)4 as model systems, here we use optical trapping (OT) to directly validate this assumption. Our results show that OT experiments on NuG2 and (NuG2)4 lead to identical parameters describing the unfolding and folding kinetics of NuG2, demonstrating that indeed stretching a polyprotein of NuG2 is equivalent to stretching single NuG2 in force spectroscopy experiments and thus validating the use of polyproteins in SMFS experiments.Direct experimental validation: Using optical tweezers, the equivalency of single-molecule force spectroscopy trajectories of a single domain and its polyprotein is directly demonstrated on a small protein NuG2. The results not only lay a solid foundation for atomic force microscopy experiments using polyproteins, but also pave the way for other force spectroscopy methods to make use of and benefit from polyproteins.
[NMR paper] Comprehensive structural and dynamical view of an unfolded protein from the combination of single-molecule FRET, NMR, and SAXS.
Comprehensive structural and dynamical view of an unfolded protein from the combination of single-molecule FRET, NMR, and SAXS.
Comprehensive structural and dynamical view of an unfolded protein from the combination of single-molecule FRET, NMR, and SAXS.
Proc Natl Acad Sci U S A. 2016 Aug 26;
Authors: Aznauryan M, Delgado L, Soranno A, Nettels D, Huang JR, Labhardt AM, Grzesiek S, Schuler B
Abstract
The properties of unfolded proteins are essential both for the mechanisms of protein folding and for the function of the large...
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08-28-2016 11:03 AM
[NMR paper] Experimental Protein Structure Verification by Scoring with a Single, Unassigned NMR Spectrum.
Experimental Protein Structure Verification by Scoring with a Single, Unassigned NMR Spectrum.
Experimental Protein Structure Verification by Scoring with a Single, Unassigned NMR Spectrum.
Structure. 2015 Sep 9;
Authors: Courtney JM, Ye Q, Nesbitt AE, Tang M, Tuttle MD, Watt ED, Nuzzio KM, Sperling LJ, Comellas G, Peterson JR, Morrissey JH, Rienstra CM
Abstract
Standard methods for de novo protein structure determination by nuclear magnetic resonance (NMR) require time-consuming data collection and interpretation efforts. Here...
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09-15-2015 11:12 AM
Experimental Protein Structure Verification by Scoring with a Single, Unassigned NMR Spectrum
Experimental Protein Structure Verification by Scoring with a Single, Unassigned NMR Spectrum
Publication date: Available online 10 September 2015
Source:Structure</br>
Author(s): Joseph*M. Courtney, Qing Ye, Anna*E. Nesbitt, Ming Tang, Marcus*D. Tuttle, Eric*D. Watt, Kristin*M. Nuzzio, Lindsay*J. Sperling, Gemma Comellas, Joseph*R. Peterson, James*H. Morrissey, Chad*M. Rienstra</br>
Standard methods for de novo protein structure determination by nuclear magnetic resonance (NMR) require time-consuming data collection and interpretation...
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09-11-2015 06:48 AM
[NMR paper] CHARMM36 all-atom additive protein force field: Validation based on comparison to NMR data.
CHARMM36 all-atom additive protein force field: Validation based on comparison to NMR data.
CHARMM36 all-atom additive protein force field: Validation based on comparison to NMR data.
J Comput Chem. 2013 Jul 6;
Authors: Huang J, Mackerell AD
Abstract
Protein structure and dynamics can be characterized on the atomistic level with both nuclear magnetic resonance (NMR) experiments and molecular dynamics (MD) simulations. Here, we quantify the ability of the recently presented CHARMM36 (C36) force field (FF) to reproduce various NMR...
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07-09-2013 02:47 PM
[NMR paper] Gradual Disordering of the Native State on a Slow Two-State Folding Protein Monitored by Single-Molecule Fluorescence Spectroscopy and NMR.
Gradual Disordering of the Native State on a Slow Two-State Folding Protein Monitored by Single-Molecule Fluorescence Spectroscopy and NMR.
Gradual Disordering of the Native State on a Slow Two-State Folding Protein Monitored by Single-Molecule Fluorescence Spectroscopy and NMR.
J Phys Chem B. 2013 Jun 24;
Authors: Campos LA, Sadqi M, Liu J, Wang X, English DS, Munoz V
Abstract
Theory predicts that folding free energy landscapes are intrinsically malleable, and as such are expected to respond to perturbations in topographically complex...
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06-27-2013 01:52 AM
Single-Cell NMR? How About Single-Protein NMR? - Corante
Single-Cell NMR? How About Single-Protein NMR? - Corante
<img alt="" height="1" width="1" />
Single-Cell NMR? How About Single-Protein NMR?
Corante
Two different research teams have reported a completely different way to run NMR experiments, one that looks like it could take the resolution down to cellular (or even large protein) levels. These two papers in Science have the details (and there's an ...
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02-04-2013 08:00 PM
Rotational velocity rescaling of molecular dynamics trajectories for direct prediction of protein NMR relaxation
Rotational velocity rescaling of molecular dynamics trajectories for direct prediction of protein NMR relaxation
July 2012
Publication year: 2012
Source:Biophysical Chemistry, Volumes 168–169</br>
</br>
Rotational velocity rescaling (RVR) enables 15N relaxation data for the anisotropically tumbling B3 domain of Protein G (GB3) to be accurately predicted from 1?s of constant energy molecular dynamics simulation without recourse to any system-specific adjustable parameters. Superposition of adjacent trajectory frames yields the unique rotation axis and angle of rotation...
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02-03-2013 10:13 AM
3D-TROSY-based backbone and ILV-methyl resonance assignments of a 319-residue homodimer from a single protein sample
3D-TROSY-based backbone and ILV-methyl resonance assignments of a 319-residue homodimer from a single protein sample
Abstract The feasibility of practically complete backbone and ILV methyl chemical shift assignments from a single -labeled protein sample of the truncated form of ligand-free Bst-Tyrosyl tRNA Synthetase (Bst-Î?YRS), a 319-residue predominantly helical homodimer, is established. Protonation of ILV residues at methyl positions does not appreciably detract from the quality of TROSY triple resonance data. The assignments are performed at 40 °C to improve the sensitivity of...
Single-Molecule Force Spectroscopy Trajectories of a Single Protein and Its Polyproteins Are Equivalent: A Direct Experimental Validation Based on A Small Protein NuG2
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