Your search keyword '"Edwards, Devin T."' showing total 2 results

1. Quantifying the Initial Unfolding of Bacteriorhodopsin Reveals Retinal Stabilization.

Author

Yu, Hao, Heenan, Patrick R., Edwards, Devin T., Uyetake, Lyle, and Perkins, Thomas T.

Subjects

BACTERIORHODOPSIN, DENATURATION of proteins, INTERMEDIATES (Chemistry), MEMBRANE proteins, BIOCONJUGATES

Abstract

The forces that stabilize membrane proteins remain elusive to precise quantification. Particularly important, but poorly resolved, are the forces present during the initial unfolding of a membrane protein, where the most native set of interactions is present. A high‐precision, atomic force microscopy assay was developed to study the initial unfolding of bacteriorhodopsin. A rapid near‐equilibrium folding between the first three unfolding states was discovered, the two transitions corresponded to the unfolding of five and three amino acids, respectively, when using a cantilever optimized for 2 μs resolution. The third of these states was retinal‐stabilized and previously undetected, despite being the most mechanically stable state in the whole unfolding pathway, supporting 150 pN for more than 1 min. This ability to measure the dynamics of the initial unfolding of bacteriorhodopsin provides a platform for quantifying the energetics of membrane proteins under native‐like conditions. Retinal stabilization: By precisely probing the initial unfolding dynamics of bacteriorhodopsin, starting when all native contacts are present, a retinal‐stabilized intermediate was discovered and the reversible folding of the first two helical turns of a membrane protein was characterized. This work lays the foundation for a novel platform for quantifying the energetics of membrane proteins under native‐like conditions. [ABSTRACT FROM AUTHOR]

Published

2019

2. Optimizing force spectroscopy by modifying commercial cantilevers: Improved stability, precision, and temporal resolution.

Author

Edwards, Devin T. and Perkins, Thomas T.

Subjects

*ATOMIC force microscopy, *MOLECULAR spectroscopy, *MEMBRANE proteins, *RECEPTOR-ligand complexes, *CANTILEVERS, *DATA quality

Abstract

Atomic force microscopy (AFM)-based single-molecule force spectroscopy (SMFS) enables a wide array of studies, from measuring the strength of a ligand–receptor bond to elucidating the complex folding pathway of individual membrane proteins. Such SMFS studies and, more generally, the diverse applications of AFM across biophysics and nanotechnology are improved by enhancing data quality via improved force stability, force precision, and temporal resolution. For an advanced, small-format commercial AFM, we illustrate how these three metrics are limited by the cantilever itself rather than the larger microscope structure, and then describe three increasingly sophisticated cantilever modifications that yield enhanced data quality. First, sub-pN force precision and stability over a broad bandwidth (Δ f = 0.01–20 Hz) is routinely achieved by removing a long ( L = 100 μm) cantilever’s gold coating. Next, this sub-pN bandwidth is extended by a factor of ∼50 to span five decades of bandwidth (Δ f = 0.01–1000 Hz) by using a focused ion beam (FIB) to modify a shorter ( L = 40 μm) cantilever. Finally, FIB-modifying an ultrashort ( L = 9 μm) cantilever improves its force stability and precision while maintaining 1-μs temporal resolution. These modified ultrashort cantilevers have a reduced quality factor ( Q ≈ 0.5) and therefore do not apply a substantial (30–90 pN), high-frequency force modulation to the molecule, a phenomenon that is unaccounted for in traditional SMFS analysis. Currently, there is no perfect cantilever for all applications. Optimizing AFM-based SMFS requires understanding the tradeoffs inherent to using a specific cantilever and choosing the one best suited to a particular application. [ABSTRACT FROM AUTHOR]

Published

2017