Putting the Disulfide Bridge at Risk: How UV-C Radiation Leads to Ultrafast Rupture of the S-S Bond

Martin Alex Bjørnholst; Anders Bo Skov; Christian M. Clausen; Jennifer Ruddock; Brian Stankus; Peter M. Weber; Theis Ivan Sølling

doi:10.1002/cphc.201800610

Putting the Disulfide Bridge at Risk: How UV-C Radiation Leads to Ultrafast Rupture of the S-S Bond

Martin Alex Bjørnholst, Anders Bo Skov, Christian M. Clausen, Jennifer Ruddock, Brian Stankus, Peter M. Weber, Theis Ivan Sølling

Abstract

We investigate the ultrafast photoinduced dynamics of the cyclic disulfide 1,2-dithiane upon 200 nm excitation by time-resolved photoelectron spectroscopy and show that the S−S bond breaks on an ultrafast time scale. This stands in stark contrast to excitation at longer wavelengths where the initially excited S₁ state evolves as the wavepacket is guided towards a conical intersection with S₀ by a torsional motion involving a partially broken bond between the sulfur atoms. This process at lower excitation energy allows for efficient (re-)population of S₀, rendering dithiane intact. At 200 nm, in contrast, the excitation leads to a manifold of higher excited states, S_n, that are primarily of Rydberg character. We are able to follow the gradual transition from the initially excited state to the dissociative receiver state in real time. The Rydberg states are intersected by a repulsive valence state that mediates a transition to the repulsive S₂ surface. Therefore, we propose that the resulting diradical will eventually break apart on a longer timescale. The findings imply that upon going from UV−B to UV−C light the structural integrity of the disulfide moiety is compromised and proteins irradiated in this range will not be able to reform the initial tertiary structure, leading to loss of function.

Original language	English
Journal	ChemPhysChem
Volume	19
Issue number	21
Pages (from-to)	2829-2834
ISSN	1439-4235
DOIs	https://doi.org/10.1002/cphc.201800610
Publication status	Published - 5 Nov 2018

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@article{1c36d8ae9eaf418db7ce5421703999e0,

title = "Putting the Disulfide Bridge at Risk: How UV-C Radiation Leads to Ultrafast Rupture of the S-S Bond",

abstract = "We investigate the ultrafast photoinduced dynamics of the cyclic disulfide 1,2-dithiane upon 200 nm excitation by time-resolved photoelectron spectroscopy and show that the S−S bond breaks on an ultrafast time scale. This stands in stark contrast to excitation at longer wavelengths where the initially excited S1 state evolves as the wavepacket is guided towards a conical intersection with S0 by a torsional motion involving a partially broken bond between the sulfur atoms. This process at lower excitation energy allows for efficient (re-)population of S0, rendering dithiane intact. At 200 nm, in contrast, the excitation leads to a manifold of higher excited states, Sn, that are primarily of Rydberg character. We are able to follow the gradual transition from the initially excited state to the dissociative receiver state in real time. The Rydberg states are intersected by a repulsive valence state that mediates a transition to the repulsive S2 surface. Therefore, we propose that the resulting diradical will eventually break apart on a longer timescale. The findings imply that upon going from UV−B to UV−C light the structural integrity of the disulfide moiety is compromised and proteins irradiated in this range will not be able to reform the initial tertiary structure, leading to loss of function.",

author = "Bj{\o}rnholst, {Martin Alex} and Skov, {Anders Bo} and Clausen, {Christian M.} and Jennifer Ruddock and Brian Stankus and Weber, {Peter M.} and S{\o}lling, {Theis Ivan}",

year = "2018",

month = nov,

day = "5",

doi = "10.1002/cphc.201800610",

language = "English",

volume = "19",

pages = "2829--2834",

journal = "ChemPhysChem",

issn = "1439-4235",

publisher = "Wiley - V C H Verlag GmbH & Co. KGaA",

number = "21",

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TY - JOUR

T1 - Putting the Disulfide Bridge at Risk

T2 - How UV-C Radiation Leads to Ultrafast Rupture of the S-S Bond

AU - Bjørnholst, Martin Alex

AU - Skov, Anders Bo

AU - Clausen, Christian M.

AU - Ruddock, Jennifer

AU - Stankus, Brian

AU - Weber, Peter M.

AU - Sølling, Theis Ivan

PY - 2018/11/5

Y1 - 2018/11/5

N2 - We investigate the ultrafast photoinduced dynamics of the cyclic disulfide 1,2-dithiane upon 200 nm excitation by time-resolved photoelectron spectroscopy and show that the S−S bond breaks on an ultrafast time scale. This stands in stark contrast to excitation at longer wavelengths where the initially excited S1 state evolves as the wavepacket is guided towards a conical intersection with S0 by a torsional motion involving a partially broken bond between the sulfur atoms. This process at lower excitation energy allows for efficient (re-)population of S0, rendering dithiane intact. At 200 nm, in contrast, the excitation leads to a manifold of higher excited states, Sn, that are primarily of Rydberg character. We are able to follow the gradual transition from the initially excited state to the dissociative receiver state in real time. The Rydberg states are intersected by a repulsive valence state that mediates a transition to the repulsive S2 surface. Therefore, we propose that the resulting diradical will eventually break apart on a longer timescale. The findings imply that upon going from UV−B to UV−C light the structural integrity of the disulfide moiety is compromised and proteins irradiated in this range will not be able to reform the initial tertiary structure, leading to loss of function.

AB - We investigate the ultrafast photoinduced dynamics of the cyclic disulfide 1,2-dithiane upon 200 nm excitation by time-resolved photoelectron spectroscopy and show that the S−S bond breaks on an ultrafast time scale. This stands in stark contrast to excitation at longer wavelengths where the initially excited S1 state evolves as the wavepacket is guided towards a conical intersection with S0 by a torsional motion involving a partially broken bond between the sulfur atoms. This process at lower excitation energy allows for efficient (re-)population of S0, rendering dithiane intact. At 200 nm, in contrast, the excitation leads to a manifold of higher excited states, Sn, that are primarily of Rydberg character. We are able to follow the gradual transition from the initially excited state to the dissociative receiver state in real time. The Rydberg states are intersected by a repulsive valence state that mediates a transition to the repulsive S2 surface. Therefore, we propose that the resulting diradical will eventually break apart on a longer timescale. The findings imply that upon going from UV−B to UV−C light the structural integrity of the disulfide moiety is compromised and proteins irradiated in this range will not be able to reform the initial tertiary structure, leading to loss of function.

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DO - 10.1002/cphc.201800610

M3 - Journal article

C2 - 30084532

SN - 1439-4235

VL - 19

SP - 2829

EP - 2834

JO - ChemPhysChem

JF - ChemPhysChem

IS - 21

ER -

Putting the Disulfide Bridge at Risk: How UV-C Radiation Leads to Ultrafast Rupture of the S-S Bond

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