Multiple dissipation components of excess light energy in dry lichen revealed by ultrafast fluorescence study at 5 K

A time-resolved fluorescence study of living lichen thalli at 5 K was conducted to clarify the dynamics and mechanism of the effective dissipation of excess light energy taking place in lichen under extreme drought conditions. The decay-associated spectra obtained from the experiment at 5 K were cha...

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Veröffentlicht in:	Photosynthesis research 2011-10, Vol.110 (1), p.39-48
Hauptverfasser:	Miyake, Hirohisa, Komura, Masayuki, Itoh, Shigeru, Kosugi, Makiko, Kashino, Yasuhiro, Satoh, Kazuhiko, Shibata, Yutaka
Format:	Artikel
Sprache:	eng
Schlagworte:	Biochemistry Biomedical and Life Sciences Desiccation Droughts Energy dissipation Energy Transfer - radiation effects Fluorescence Japan Lichens Lichens - metabolism Lichens - radiation effects Life Sciences Light Photosynthesis Photosynthesis - radiation effects Photosystem II Protein Complex - radiation effects Plant Genetics and Genomics Plant Physiology Plant Sciences Regular Paper Spectrometry, Fluorescence - methods Stress, Physiological Temperature Time Factors
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container_title	Photosynthesis research
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creator	Miyake, Hirohisa Komura, Masayuki Itoh, Shigeru Kosugi, Makiko Kashino, Yasuhiro Satoh, Kazuhiko Shibata, Yutaka
description	A time-resolved fluorescence study of living lichen thalli at 5 K was conducted to clarify the dynamics and mechanism of the effective dissipation of excess light energy taking place in lichen under extreme drought conditions. The decay-associated spectra obtained from the experiment at 5 K were characterized by a drastically sharpened spectral band which could not be resolved by experiments at higher temperatures. The present results indicated the existence of two distinct dissipation components of excess light energy in desiccated lichen; one is characterized as rapid fluorescence decay with a time constant of 27 ps in the far-red region that was absent in wet lichen thalli, and the other is recognized as accelerated fluorescence decay in the 685–700 nm spectral region. The former energy-dissipation component with extremely high quenching efficiency is most probably ascribed to the emergence of a rapid quenching state in the peripheral-antenna system of photosystem II (PS II) on desiccation. This is an extremely effective protection mechanism of PS II under desiccation, which lichens have developed to survive in the severely desiccated environments. The latter, which is less efficient at 5 K, might have a supplementary role and take place either in the core antenna of PS II or aggregated peripheral antenna of PS II.
doi_str_mv	10.1007/s11120-011-9691-8
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The decay-associated spectra obtained from the experiment at 5 K were characterized by a drastically sharpened spectral band which could not be resolved by experiments at higher temperatures. The present results indicated the existence of two distinct dissipation components of excess light energy in desiccated lichen; one is characterized as rapid fluorescence decay with a time constant of 27 ps in the far-red region that was absent in wet lichen thalli, and the other is recognized as accelerated fluorescence decay in the 685–700 nm spectral region. The former energy-dissipation component with extremely high quenching efficiency is most probably ascribed to the emergence of a rapid quenching state in the peripheral-antenna system of photosystem II (PS II) on desiccation. This is an extremely effective protection mechanism of PS II under desiccation, which lichens have developed to survive in the severely desiccated environments. 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The decay-associated spectra obtained from the experiment at 5 K were characterized by a drastically sharpened spectral band which could not be resolved by experiments at higher temperatures. The present results indicated the existence of two distinct dissipation components of excess light energy in desiccated lichen; one is characterized as rapid fluorescence decay with a time constant of 27 ps in the far-red region that was absent in wet lichen thalli, and the other is recognized as accelerated fluorescence decay in the 685–700 nm spectral region. The former energy-dissipation component with extremely high quenching efficiency is most probably ascribed to the emergence of a rapid quenching state in the peripheral-antenna system of photosystem II (PS II) on desiccation. This is an extremely effective protection mechanism of PS II under desiccation, which lichens have developed to survive in the severely desiccated environments. The latter, which is less efficient at 5 K, might have a supplementary role and take place either in the core antenna of PS II or aggregated peripheral antenna of PS II.</abstract><cop>Dordrecht</cop><pub>Springer Netherlands</pub><pmid>21986932</pmid><doi>10.1007/s11120-011-9691-8</doi><tpages>10</tpages></addata></record>
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subjects	Biochemistry Biomedical and Life Sciences Desiccation Droughts Energy dissipation Energy Transfer - radiation effects Fluorescence Japan Lichens Lichens - metabolism Lichens - radiation effects Life Sciences Light Photosynthesis Photosynthesis - radiation effects Photosystem II Protein Complex - radiation effects Plant Genetics and Genomics Plant Physiology Plant Sciences Regular Paper Spectrometry, Fluorescence - methods Stress, Physiological Temperature Time Factors
title	Multiple dissipation components of excess light energy in dry lichen revealed by ultrafast fluorescence study at 5 K
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