叶黄素可以在CP26光捕获复合物中充当可切换的电荷转移猝灭剂。

Lutein can act as a switchable charge transfer quencher in the CP26 light-harvesting complex.

作者信息

Avenson Thomas J, Ahn Tae Kyu, Niyogi Krishna K, Ballottari Matteo, Bassi Roberto, Fleming Graham R

机构信息

Department of Chemistry, University of California, Berkeley, and Physical Biosciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720; Department of Plant and Microbial Biology, Koshland Hall, University of California, Berkeley, California 94720-3102.

Department of Chemistry, University of California, Berkeley, and Physical Biosciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720.

出版信息

J Biol Chem. 2009 Jan 30;284(5):2830-2835. doi: 10.1074/jbc.M807192200. Epub 2008 Nov 6.

DOI:10.1074/jbc.M807192200

PMID:18990705

Abstract

Energy-dependent quenching of excitons in photosystem II of plants, or qE, has been positively correlated with the transient production of carotenoid radical cation species. Zeaxanthin was shown to be the donor species in the CP29 antenna complex. We report transient absorbance analyses of CP24 and CP26 complexes that bind lutein and zeaxanthin in the L1 and L2 domains, respectively. For CP24 complexes, the transient absorbance difference profiles give a reconstructed transient absorbance spectrum with a single peak centered at approximately 980 nm, consistent with zeaxanthin radical cation formation. In contrast, CP26 gives constants for the decay components probed at 940 and 980 nm of 144 and 194 ps, a transient absorbance spectrum that has a main peak at 980 nm, and a substantial shoulder at 940 nm. This suggests the presence of two charge transfer quenching sites in CP26 involving zeaxanthin radical cation and lutein radical cation species. We also show that lutein radical cation formation in CP26 is dependent on binding of zeaxanthin to the L2 domain, implying that zeaxanthin acts as an allosteric effector of charge transfer quenching involving lutein in the L1 domain.

摘要

植物光系统II中激子的能量依赖猝灭，即qE，与类胡萝卜素自由基阳离子物种的瞬时产生呈正相关。在CP29天线复合物中，玉米黄质被证明是供体物种。我们报告了CP24和CP26复合物的瞬态吸收分析，它们分别在L1和L2结构域中结合叶黄素和玉米黄质。对于CP24复合物，瞬态吸收差异谱给出了一个重构的瞬态吸收光谱，其单峰中心位于约980nm处，这与玉米黄质自由基阳离子的形成一致。相比之下，CP26在940和980nm处探测到的衰减成分常数分别为144和194ps，瞬态吸收光谱在980nm处有一个主峰，在940nm处有一个明显的肩峰。这表明CP26中存在两个涉及玉米黄质自由基阳离子和叶黄素自由基阳离子物种的电荷转移猝灭位点。我们还表明，CP26中叶黄素自由基阳离子的形成依赖于玉米黄质与L2结构域的结合，这意味着玉米黄质作为L1结构域中涉及叶黄素的电荷转移猝灭的变构效应物。

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叶黄素可以在CP26光捕获复合物中充当可切换的电荷转移猝灭剂。

Lutein can act as a switchable charge transfer quencher in the CP26 light-harvesting complex.

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