叶绿素 c 含量丰富的藻类——美岭藻（黄藻门）的电致变色吸收变化。

Electrochromic absorbance changes in the chlorophyll-c-containing alga Pleurochloris meiringensis (Xanthophyceae).

机构信息

Institute for General Botany, University of Mainz, 55099, Mainz, Germany.

出版信息

Photosynth Res. 1995 Jan;43(1):49-56. doi: 10.1007/BF00029462.

Abstract

Flash-induced absorbance changes were measured in the Chl-c-containing alga Pleurochloris meiringensis (Xanthophyceae) between 430 and 570 nm. In addition to the bands originating from redox changes of cytochromes, three major positive and tow negative transient bands were observed both 0.7 and 20 ms after the exciting flash. These transient bands peaking at 520, 480 and 451 nm and 497 and 465 nm, respectively, could be assigned to an almost homogeneous shift of the absorbance bands with maxima at 506, 473 and 444 nm, respectively. The shape of the absorbance transients elicited from PS I or PS II was identical, and the two photosystems contributed nearly equally to the absorbance changes. Furthermore, the decay transients were sensitive to the preillumination of the cells. These data strongly suggest that the absorbance transients originate from an electrochromic response of carotenoid molecules. The pigment species responsible for the 506 nm absorption band, probably heteroxanthin or diatoxanthin, transferred excitation energy to both photosystems as shown by the aid of 77 K fluorescence excitation spectra.

摘要

在 430 到 570nm 之间，对含有叶绿素 c 的绿藻（黄藻门） Pleurochloris meiringensis 进行了闪光诱导的吸光度变化测量。除了源自细胞色素氧化还原变化的谱带之外，在激发闪光后 0.7 和 20ms 时，还观察到三个主要的正瞬变带和两个负瞬变带。这些分别在 520nm、480nm 和 451nm 以及 497nm 和 465nm 处达到峰值的瞬变带，可以归因于最大吸收带的几乎均匀位移，其最大吸收分别在 506nm、473nm 和 444nm 处。从 PS I 或 PS II 引发的吸光度瞬变的形状相同，两个光系统对吸光度变化的贡献几乎相等。此外，衰减瞬变对细胞的预照明敏感。这些数据强烈表明，吸光度瞬变源自类胡萝卜素分子的电致变色响应。负责 506nm 吸收带的色素物种，可能是异叶黄素或硅藻黄素，如 77K 荧光激发光谱所示，将激发能传递给两个光系统。

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叶绿素 c 含量丰富的藻类——美岭藻（黄藻门）的电致变色吸收变化。

Electrochromic absorbance changes in the chlorophyll-c-containing alga Pleurochloris meiringensis (Xanthophyceae).

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