Large Temperature‐Jump and Nanosecond Hyperquenching for Time‐Resolved Structural Studies

Cherepanov, Alexey V.; Schwalbe, Harald

doi:10.1002/cmtd.202200050

Chemistry Methods

2023

DOI: 10.1002/cmtd.202200050

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Large Temperature‐Jump and Nanosecond Hyperquenching for Time‐Resolved Structural Studies

Alexey V. Cherepanov

Harald Schwalbe

Abstract: The quest for atomic structures of microsecond reaction intermediates is at the frontline of modern biochemistry. Currently, there is a clear lack of experimental methods for preparing necessary time-resolved samples. Here, we report the development of a single-turnover technique for nanosecond initiation and suspension of biomolecular reactions with kinetic resolution in the microsecond time domain. Reactions can be started by large temperature-jump or direct mixing and arrested by hyperquenching in liquid cr… Show more

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2024

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Quantification of Rapid Cooling of Glycerol/Water Solutions Based on Photoluminescence from Thioflavin T

Tycko,

Jeon

2024

J. Phys. Chem. B

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Rapid cooling to a solid state allows intermediates in chemical and biomolecular processes that occur in solution near room temperature to be trapped for subsequent measurements by magnetic resonance spectroscopies, electron microscopy, or other techniques. In time-resolved solid state nuclear magnetic resonance and rapid freeze-quench electron paramagnetic resonance studies, solutions are typically frozen by spraying into a cold bath or onto a cold metal surface. Although simulations suggest freezing on millisecond or submillisecond time scales, direct experimental measurements of cooling rates have been elusive. Here, we describe a method for quantification of rapid cooling rates based on measurements of temperature-dependent photoluminescence from thioflavin T (ThT). In our experiments, a jet of ThT solution in glycerol/water, with 10.8 m/s jet velocity and 30 μm diameter, freezes on a cold, rotating copper surface. Images of ThT photoluminescence on the copper surface indicate that the cooling rate of the solution increases linearly with the surface velocity over the 0.45−6.2 m/s range. At surface velocities greater than 3.8 m/s, the time to cool from 300 to 260 K or from 300 to 230 K is less than 100 μs or less than 700 μs. The experimental results do not agree quantitatively with calculations in which a layer of glycerol/water cools by thermal conduction when suddenly brought in contact with a cold copper surface. Discrepancies between experimental results and simplistic calculations illustrate the importance of direct measurements of cooling rates.

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Quantification of Rapid Cooling of Glycerol/Water Solutions Based on Photoluminescence from Thioflavin T

Tycko,

Jeon

2024

J. Phys. Chem. B

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Large Temperature‐Jump and Nanosecond Hyperquenching for Time‐Resolved Structural Studies

Cited by 1 publication

References 84 publications

Quantification of Rapid Cooling of Glycerol/Water Solutions Based on Photoluminescence from Thioflavin T

Quantification of Rapid Cooling of Glycerol/Water Solutions Based on Photoluminescence from Thioflavin T

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