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Abstract
Hydrogen/deuterium exchange (HDX) methods for studying protein dynamics would benefit from millisecond-scale incubations to probe intrinsically disordered proteins, highly dynamic regions and conformation changes. Here we investigate droplet microfluidics for rapid mixing to trigger D2O labelling, uniform incubations and rapid droplet merging for acid quenching in advance of mass spectrometry. A surfactant-free merging approach combining expansion elements for synchronised droplet collision proved robust. The high diffusive flux of D2O and protons enable microsecond mixing to trigger and arrest D2O labelling, respectively, affording the possibility of single millisecond incubations. Droplet HDX processors were used to measure the fast uptake characteristics of a model peptide. Forward exchange measurements demonstrate D2O labelling to be the rate-limiting step, in essence defining 10 milliseconds as the minimum practical incubation time. With the ability to access millisecond time scales the fast dynamics of calmodulin, a model of calcium-triggered allostery with rapid conformational switching, was investigated. Fast reorganisation of the EF-hand motifs provoked by calcium binding was observed. The millisecond precision of droplet microfluidic HDX paves the way to advance understanding of protein structural dynamics.
Supplementary materials
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SI Table S1
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Calmodulin peptides observed and theoretical uptake values for 1, 10, 100 ms, 1 and 10 sec for both pD 7.4 and pD 9.4
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SI Figure S1: Droplet generation
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Images of droplet generation and D2O mixing.
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SI Figure S2: Droplet merging
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Images of droplet merging for microfluidic devices (A) 10-100 millisecond device (B) 1 millisecond device.
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SI Figure S3: Calmodulin peptides uptake
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Calmodulin peptides time-dependent D2O labelling with Ca2+ (red) and without Ca2+ (blue). HDX is shown as percentage of peptides’
maximum theoretical uptake at 90% D2O labelling.
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SI Figure S4: Calmodulin high and low regions uptake
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Uptake plot of calmodulin peptides from high uptake regions compared to low uptake regions at 1ms, 100ms, 1s and 10s.
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SI Video 1
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Chop and exchange droplet merging.
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SI Video 2
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Drag and merge droplet merging.
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SI Video S3
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Collide and merge droplet merging.
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SI CAD
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CAD drawings for microfluidic devices.
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Supplementary weblinks
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Droplet microfluidic hydrogen/deuterium exchange-MS data at the PRIDE repository
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Raw files, and processed Waters DynamX outputs associated with the forwards exchange experiments (Figure 3 in the manuscript) and the differential uptake experiments (Figure 4 in the manuscript). For the forwards exchange experiments the column Condition in the csv files contain the experimental condition. The Bovine calmodulin sequence is provided as a fasta file.
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