Abstract
With the recent explosion in high-resolution protein structures, one of the next frontiers in biology is elucidating the mechanisms by which conformational rearrangements in proteins are regulated to meet the needs of cells under changing conditions. Rigorously measuring protein energetics and dynamics requires the development of new methods that can resolve structural heterogeneity and conformational distributions. We have previously developed steady-state transition metal ion fluorescence resonance energy transfer (tmFRET) approaches using a fluorescent noncanonical amino acid donor (Anap) and transition metal ion acceptor to probe conformational rearrangements in soluble and membrane proteins. Here, we show that the fluorescent noncanonical amino acid Acd has superior photophysical properties that extend its utility as a donor for tmFRET. Using maltose-binding protein (MBP) expressed in mammalian cells as a model system, we show that Acd is comparable to Anap in steady-state tmFRET experiments and that its long, single-exponential lifetime is better suited for probing conformational distributions using time-resolved FRET. These experiments reveal differences in heterogeneity in the apo and holo conformational states of MBP and produce accurate quantification of the distributions among apo and holo conformational states at subsaturating maltose concentrations. Our new approach using Acd for time-resolved tmFRET sets the stage for measuring the energetics of conformational rearrangements in soluble and membrane proteins in near-native conditions.
Highlights
Proteins are exquisite molecular machines that underlie virtually all physiological functions
Acd has a number of fluorescence properties that make it better suited for transition metal ion fluorescence resonance energy transfer (tmFRET) than Anap
This paper describes a significant expansion of the tmFRET method
Summary
Proteins are exquisite molecular machines that underlie virtually all physiological functions. A method should, ideally: (1) measure dynamics with high temporal resolution, over a large range of time scales (from nanoseconds to minutes), (2) measure structure with high spatial resolution, (3) resolve heterogeneity and distributions of conformations, (4) exhibit high sensitivity, allowing measurements from small amounts of protein, even single molecules, (5) work on proteins of arbitrary size, (6) work on proteins in their native environments, including membranes and protein complexes, (7) be minimally perturbing, and (8) measure structural dynamics and function simultaneously. FRET measurements typically measure distances in the 30‐80 Å range, limiting their utility for measuring intramolecular distances and distance changes associated with conformational changes To overcome these limitations, we have previously developed a method called transition metal ion FRET (tmFRET) to accurately measure the structure and dynamics of short‐range interactions in proteins (Taraska et al, 2009a; Taraska et al, 2009b; Yu et al, 2013). This capability can be used, in principle, to measure the energetics of any conformational rearrangement of a protein domain slower than tens of nanoseconds
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