Roles of the transthylakoid proton gradient and xanthophyll cycle in the non-photochemical quenching of the green alga Ulva linza

文献类型: 外文期刊

第一作者: Zhang, Xiaowen

作者: Zhang, Xiaowen;Mou, Shanli;Cao, Shaona;Fan, Xiao;Xu, Dong;Ye, Naihao

作者机构:

关键词: NPQ;Delta pH;xanthophyll cycle;Ulva linza

期刊名称:ESTUARINE COASTAL AND SHELF SCIENCE ( 影响因子:2.929; 五年影响因子:3.329 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Non-photochemical quenching (NPQ) is one of the most important photoprotection mechanisms in photosynthetic organisms when they are exposed to excessive irradiation. The basic principle of NPQ which is the safe dissipation of excessive absorbed light as heat, is identical in all photoautotrophs. However, crucial differences in its regulation and structural mechanisms exist in different phototrophs. Here, we investigated NPQ in the green alga Ulva linza coupled with inhibitors to alter the amplitude of the transthylakoid proton gradient (Delta pH) and/or de-expoxidation of xanthophyll cycle (XC) under high light conditions. The data demonstrates that NPQ started with a rapid initial rise within the first minute of illumination, followed by a decline before a further rise in quenching. During the whole phase, NPQ was triggered and completely controlled by Delta pH, then strengthened and modulated by zeaxanthin. NPQ relaxation was slower in U. linza when compared to plants and other green algae, and it may be mainly caused by the slow conversion of zeaxanthin to violaxanthin. NPQ in U. linza is controlled to a greater extent by XC, which show more similarities to Arabidopsis than to Chlamydomonas and may be an adaptive mechanism for its successful colonization of coastal ecosystems. (C) 2014 Elsevier Ltd. All rights reserved.

分类号: P7

  • 相关文献

[1]Analysis of Delta pH and the xanthophyll cycle in NPQ of the Antarctic sea ice alga Chlamydomonas sp ICE-L. Mou, Shanli,Zhang, Xiaowen,Ye, Naihao,Xu, Dong,Fan, Xiao,Miao, Jinlai,An, Meiling,Cao, Shaona. 2013

[2]Occurrence of the PsbS and LhcSR products in the green alga Ulva linza and their correlation with excitation pressure. Zhang, Xiaowen,Ye, Naihao,Mou, Shanli,Xu, Dong,Fan, Xiao.

[3]Growth and nutrient uptake capacity of two co-occurring species, Ulva prolifera and Ulva linza. Liu, Feng,Luo, Min Bo,Xu, Zhao Li. 2012

[4]Activities of principal photosynthetic enzymes in green macroalga Ulva linza: functional implication of C-4 pathway in CO2 assimilation. Xu JianFang,Zheng Zhou,Miao JinLai,Zhang XiaoWen,Ye NaiHao,Mou ShanLi,Xu Dong,Dong MeiTao. 2013

[5]Expression of Three Putative Early Light-Induced Genes Under Different Stress Conditions in the Green Alga Ulva linza. Zhang, Xiaowen,Mou, Shanli,Xu, Dong,Fan, Xiao,Ye, Naihao,Li, Youxun,Cao, Shaona,Mou, Shanli.

[6]Characterization of the LhcSR Gene Under Light and Temperature Stress in the Green Alga Ulva linza. Dong, Meitao,Wang, Wenqi,Dong, Meitao,Zhang, Xiaowen,Zhuang, Zhimeng,Zou, Jian,Ye, Naihao,Xu, Dong,Mou, Shanli,Liang, Chengwei.

[7]The validity of a reference gene is highly dependent on the experimental conditions in green alga Ulva linza. Zhang, Xiaowen,Xu, Dong,Ye, Naihao,Dong, Meitao,Wang, Wenqi,Chi, Xiaoyuan,Mou, Shanli,Xu, Jianfang.

[8]Identification and expression analysis of four light harvesting-like (Lhc) genes associated with light and desiccation stress in Ulva linza. Guan, Zheng,Zhang, Xiaowen,Xu, Dong,Fan, Xiao,Wang, Yitao,Ye, Naihao,Mou, Shanli,Wang, Dongsheng,Ye, Naihao.

[9]The green tide-forming macroalga Ulva linza outcompetes the red macroalga Gracilaria lemaneiformis via allelopathy and fast nutrients uptake. Gao, Zhengquan,Meng, Chunxiao,Xu, Dong,Zhang, Xiaowen,Zou, Jian,Zhuang, Zhimeng,Ye, Naihao,Wang, Yitao,Li, Demao.

[10]Ferredoxin-quinone reductase benefits cyclic electron flow around photosystem 1 in tobacco leaves upon exposure to chilling stress under low irradiance. Li, X. -G.,Xu, P. -L.,Zhao, J. -P.,Meng, J. -J.,He, Q. -W.. 2006

[11]Xanthophyll Cycle and Inactivation of Photosystem II Reaction Centers Alleviating Reducing Pressure to Photosystem I in Morning Glory Leaves under Short-term High Irradiance. Li, Xin-Guo,Li, Jian-Yong,Zhao, Jin-Ping,Xu, Ping-Li,He, Qi-Wei.

[12]Photochemical and antioxidative responses of the glume and flag leaf to seasonal senescence in wheat. Kong, Lingan,Sun, Mingze,Xie, Yan,Wang, Fahong,Zhao, Zhendong,Sun, Mingze. 2015

[13]An integration of photosynthetic traits and mechanisms that can increase crop photosynthesis and grain production. Black, CC,Tu, ZP,Counce, PA,Yao, PF,Angelov, MN. 1995

[14]Mutations of genes in synthesis of the carotenoid precursors of ABA lead to pre-harvest sprouting and photo-oxidation in rice. Fang, Jun,Chai, Chenglin,Li, Chunlai,Tang, Jiuyou,Huang, Zejun,Guo, Xiaoli,Sun, Changhui,Liu, Min,Wang, Yiqin,Cheng, Zhukuan,Chu, Chengcai,Fang, Jun,Chai, Chenglin,Li, Chunlai,Tang, Jiuyou,Huang, Zejun,Guo, Xiaoli,Sun, Changhui,Liu, Min,Wang, Yiqin,Cheng, Zhukuan,Chu, Chengcai,Fang, Jun,Chai, Chenglin,Li, Chunlai,Tang, Jiuyou,Huang, Zejun,Guo, Xiaoli,Qian, Qian,Sun, Lei,Zhang, Yan,Lu, Qingtao,Lu, Congming,Han, Bin,Chen, Fan.

[15]DEFICIENCY OF PHYTOCHROME B ALLEVIATES CHILLING-INDUCED PHOTOINHIBITION IN RICE. Yang, Jian-Chao,Han, Guo-Liang,Sui, Na,Wang, Bao-Shan,Li, Meng,Xie, Xian-Zhi. 2013

[16]Effects of heat and high irradiance stress on energy dissipation of photosystem II in low irradiance-adapted peanut leaves. Guo, F.,Yang, S.,Zhang, J. L.,Meng, J. J.,Li, X. G.,Feng, Y.,Wan, S. B..

[17]Photoinhibition and photooxidation in leaves of indica and japonica rice under different temperatures and light intensities. Ji, BH,Jiao, DM. 2001

[18]Photochemical efficiency of PSII and membrane lipid peroxidation in leaves of indica and japonica rice (Oryza sativa) under chilling temperature and strong light stress conditions. Ji, BH,Zhu, SQ,Jiao, DM. 2002

[19]Photosynthetic Characteristics of a Super High Yield Cultivar of Winter Wheat During Late Growth Period. Meng Qing-wei,Tian Ji-chun,Zhao Shi-jie,Sui Na,Li Meng. 2010

[20]Changes in Violaxanthin Deepoxidase Activity and Unsaturation of Thylakoid Membrane Lipids in Indica and Japonica Rice Under Chilling Condition and Strong Light. Ji, BH,Cao, YY,Xie, HS,Zhu, SQ,Ma, Q,Jian, DM.

作者其他论文 更多>>

微信小程序