Excited State Decay Pathways of 2′-Deoxy-5-methylcytidine and Deoxycytidine Revisited in Solution: A Comprehensive Kinetic Study by Femtosecond Transient Absorption

Methylated cytosine is proved to have an important role as an epigenetic signal in gene regulation and is often referred to “the fifth base of DNA”. A comprehensive understanding of the electronic excited state relaxation in cytosine and its methylated derivatives is crucial for revealing UV-induced...

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Veröffentlicht in:	The journal of physical chemistry. B 2018-07, Vol.122 (28), p.7027-7037
Hauptverfasser:	Wang, Xueli, Zhou, Zhongneng, Tang, Yuankai, Chen, Jinquan, Zhong, Dongping, Xu, Jianhua
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Sprache:	eng
Schlagworte:	Acetonitriles - chemistry Cytidine - analogs & derivatives Cytidine - chemistry Deoxycytidine - chemistry DNA Damage - radiation effects Kinetics Quantum Theory Solutions - chemistry Thermodynamics Ultraviolet Rays
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container_issue	28
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container_title	The journal of physical chemistry. B
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creator	Wang, Xueli Zhou, Zhongneng Tang, Yuankai Chen, Jinquan Zhong, Dongping Xu, Jianhua
description	Methylated cytosine is proved to have an important role as an epigenetic signal in gene regulation and is often referred to “the fifth base of DNA”. A comprehensive understanding of the electronic excited state relaxation in cytosine and its methylated derivatives is crucial for revealing UV-induced photodamage to the biological genome. Because of the existence of multiple closely lying “bright” and “dark” excited states, the decay pathways in these DNA nucleosides are the most complex and the least understood so far. In this study, femtosecond transient absorption with different excitation wavelengths (240–296 nm) was used to study the relaxation of excited electronic states of 5-methylcytosine (5mC) and 2′-deoxy-5-methylcytidine (5mdCyd) in phosphate buffered aqueous solution and in acetonitrile solution. Two distinct nonradiative decay channels were directly observed. The first one is a several picosecond internal conversion channel that involves two bright ππ* states (ππ2 and ππ1) when ππ2 state is initially populated. The second channel contains the lower energy ππ1 state and a so far experimental unidentified long-lived state which exhibits a several nanosecond lifetime. The long-lived state can only be accessed by the initially excited ππ1 state. Inspired by this new discovery in 5mC and 5mdCyd, we revisited the decay of excited state of 2′-deoxycytidine (dCyd), revealing very similar decay pathways. Additionally, a well-known dark nOπ state (carbonyl lone pair) with ∼30 ps lifetime is present in both decay channels in dCyd. With our detailed experimental results, we successfully reconcile the long history debate of cytosine excited state relaxation mechanism by pointing out that the reason for the complex dynamics under traditional 266 nm excitation is mixed signals from the above-mentioned two distinct decay pathways. Our findings lead to a dramatically different and new picture of electronic energy relaxation in 5mdCyd/dCyd and could help to understand photostability as well as UV-induced photodamage of these nucleotides and related DNAs.
doi_str_mv	10.1021/acs.jpcb.8b00927
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A comprehensive understanding of the electronic excited state relaxation in cytosine and its methylated derivatives is crucial for revealing UV-induced photodamage to the biological genome. Because of the existence of multiple closely lying “bright” and “dark” excited states, the decay pathways in these DNA nucleosides are the most complex and the least understood so far. In this study, femtosecond transient absorption with different excitation wavelengths (240–296 nm) was used to study the relaxation of excited electronic states of 5-methylcytosine (5mC) and 2′-deoxy-5-methylcytidine (5mdCyd) in phosphate buffered aqueous solution and in acetonitrile solution. Two distinct nonradiative decay channels were directly observed. The first one is a several picosecond internal conversion channel that involves two bright ππ* states (ππ2 and ππ1) when ππ2 state is initially populated. The second channel contains the lower energy ππ1 state and a so far experimental unidentified long-lived state which exhibits a several nanosecond lifetime. The long-lived state can only be accessed by the initially excited ππ1 state. Inspired by this new discovery in 5mC and 5mdCyd, we revisited the decay of excited state of 2′-deoxycytidine (dCyd), revealing very similar decay pathways. Additionally, a well-known dark nOπ state (carbonyl lone pair) with ∼30 ps lifetime is present in both decay channels in dCyd. With our detailed experimental results, we successfully reconcile the long history debate of cytosine excited state relaxation mechanism by pointing out that the reason for the complex dynamics under traditional 266 nm excitation is mixed signals from the above-mentioned two distinct decay pathways. 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B</title><addtitle>J. Phys. Chem. B</addtitle><description>Methylated cytosine is proved to have an important role as an epigenetic signal in gene regulation and is often referred to “the fifth base of DNA”. A comprehensive understanding of the electronic excited state relaxation in cytosine and its methylated derivatives is crucial for revealing UV-induced photodamage to the biological genome. Because of the existence of multiple closely lying “bright” and “dark” excited states, the decay pathways in these DNA nucleosides are the most complex and the least understood so far. In this study, femtosecond transient absorption with different excitation wavelengths (240–296 nm) was used to study the relaxation of excited electronic states of 5-methylcytosine (5mC) and 2′-deoxy-5-methylcytidine (5mdCyd) in phosphate buffered aqueous solution and in acetonitrile solution. Two distinct nonradiative decay channels were directly observed. The first one is a several picosecond internal conversion channel that involves two bright ππ* states (ππ2 and ππ1) when ππ2 state is initially populated. The second channel contains the lower energy ππ1 state and a so far experimental unidentified long-lived state which exhibits a several nanosecond lifetime. The long-lived state can only be accessed by the initially excited ππ1 state. Inspired by this new discovery in 5mC and 5mdCyd, we revisited the decay of excited state of 2′-deoxycytidine (dCyd), revealing very similar decay pathways. Additionally, a well-known dark nOπ state (carbonyl lone pair) with ∼30 ps lifetime is present in both decay channels in dCyd. With our detailed experimental results, we successfully reconcile the long history debate of cytosine excited state relaxation mechanism by pointing out that the reason for the complex dynamics under traditional 266 nm excitation is mixed signals from the above-mentioned two distinct decay pathways. 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A comprehensive understanding of the electronic excited state relaxation in cytosine and its methylated derivatives is crucial for revealing UV-induced photodamage to the biological genome. Because of the existence of multiple closely lying “bright” and “dark” excited states, the decay pathways in these DNA nucleosides are the most complex and the least understood so far. In this study, femtosecond transient absorption with different excitation wavelengths (240–296 nm) was used to study the relaxation of excited electronic states of 5-methylcytosine (5mC) and 2′-deoxy-5-methylcytidine (5mdCyd) in phosphate buffered aqueous solution and in acetonitrile solution. Two distinct nonradiative decay channels were directly observed. The first one is a several picosecond internal conversion channel that involves two bright ππ* states (ππ2 and ππ1) when ππ2 state is initially populated. The second channel contains the lower energy ππ1 state and a so far experimental unidentified long-lived state which exhibits a several nanosecond lifetime. The long-lived state can only be accessed by the initially excited ππ1 state. Inspired by this new discovery in 5mC and 5mdCyd, we revisited the decay of excited state of 2′-deoxycytidine (dCyd), revealing very similar decay pathways. Additionally, a well-known dark nOπ state (carbonyl lone pair) with ∼30 ps lifetime is present in both decay channels in dCyd. With our detailed experimental results, we successfully reconcile the long history debate of cytosine excited state relaxation mechanism by pointing out that the reason for the complex dynamics under traditional 266 nm excitation is mixed signals from the above-mentioned two distinct decay pathways. 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subjects	Acetonitriles - chemistry Cytidine - analogs & derivatives Cytidine - chemistry Deoxycytidine - chemistry DNA Damage - radiation effects Kinetics Quantum Theory Solutions - chemistry Thermodynamics Ultraviolet Rays
title	Excited State Decay Pathways of 2′-Deoxy-5-methylcytidine and Deoxycytidine Revisited in Solution: A Comprehensive Kinetic Study by Femtosecond Transient Absorption
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