Variable content and distribution of arabinogalactan proteins in banana (Musa spp.) under low temperature stress

文献类型: 外文期刊

第一作者: Chen, Houbin

作者: Chen, Houbin;Wang, Yingying;Xu, Enfeng;Xie, Ling;Su, Zhaohua;Xu, Chunxiang;Takac, Tomas;Samaj, Jozef;Li, Xiaoquan

作者机构:

关键词: arabinogalactan proteins;abiotic stress;banana (Musa spp.);immuno-labeling;low temperature stress;plant cell wall;plant-environment interactions;spatial distribution

期刊名称:FRONTIERS IN PLANT SCIENCE ( 影响因子:5.753; 五年影响因子:6.612 )

ISSN: 1664-462X

年卷期: 2015 年 6 卷

页码:

收录情况: SCI

摘要: Information on the spatial distribution of arabinogalactan proteins (AGPs) in plant organs and tissues during plant reactions to low temperature (LT) is limited. In this study, the extracellular distribution of AGPs in banana leaves and roots, and their changes under LT stress were investigated in two genotypes differing in chilling tolerance, by immuno-techniques using 17 monoclonal antibodies against different AGP epitopes. Changes in total classical AGPs in banana leaves were also tested. The results showed that AGP epitopes recognized by JIM4, JIM14, JIM16, and CCRC-M32 antibodies were primarily distributed in leaf veins, while those recognized by JIM8, JIM13, JIM15, and PN16.4B4 antibodies exhibited predominant sclerenchymal localization. Epitopes recognized by LM2, LM14, and MAC207 antibodies were distributed in both epidermal and mesophyll cells. Both genotypes accumulated classical AGPs in leaves under LT treatment, and the chilling tolerant genotype contained higher classical AGPs at each temperature treatment. The abundance of JIM4 and JIM16 epitopes in the chilling-sensitive genotype decreased slightly after LT treatment, and this trend was opposite for the tolerant one. LT induced accumulation of LM2- and LM14-immunoreactive AGPs in the tolerant genotype compared to the sensitive one, especially in phloem and mesophyll cells. These epitopes thus might play important roles in banana LT tolerance. Different AGP components also showed differential distribution patterns in banana roots. In general, banana roots started to accumulate AGPs under LT treatment earlier than leaves. The levels of AGPs recognized by MAC207 and JIM13 antibodies in the control roots of the tolerant genotype were higher than in the chilling sensitive one. Furthermore, the chilling tolerant genotype showed high immuno-reactivity against JIM13 antibody. These results indicate that several AGPs are likely involved in banana tolerance to chilling injury.

分类号:

  • 相关文献

[1]Effects of inter-culture, arabinogalactan proteins, and hydrogen peroxide on the plant regeneration of wheat immature embryos. Zhang Wei,Wang Xin-min,Yin Gui-xiang,Wang Ke,Du Li-pu,Xiao Le-le,Ye Xing-guo,Fan Rong. 2015

[2]Genome-wide identification, classification and expression analysis of genes encoding putative fasciclin-like arabinogalactan proteins in Chinese cabbage (Brassica rapa L.). Li Jun,Wu Xiaoming.

[3]The putative phytocyanin genes in Chinese cabbage (Brassica rapa L.): genome-wide identification, classification and expression analysis. Li, Jun,Gao, Guizhen,Zhang, Tianyao,Wu, Xiaoming.

[4]Efficient regeneration and genetic transformation platform applicable to five Musa varieties. Liu, Juhua,Gao, Pengzhao,Zhang, Jing,Jia, Caihong,Zhang, Jianbin,Hu, Wei,Xu, Biyu,Jin, Zhiqiang,Sun, Peiguang,Wang, Jiashui,Jin, Zhiqiang,Sun, Xiuxiu. 2017

[5]A systematic comparison of embryogenic and non-embryogenic cells of banana (Musa spp. AAA): Ultrastructural, biochemical and cell wall component analyses. Shi, Lei,Pan, Xiao,Chen, Houbin,Wu, Xiaoying,Xu, Chunxiang,Lin, Guimei,Takac, Tomas,Samaj, Jozef,Samaj, Jozef. 2013

[6]Identification and evaluation of two diagnostic markers linked to Fusarium wilt resistance (race 4) in banana (Musa spp.). Hu, Yulin,Sun, Dequan,Xie, Jianghui,Wang, Wei,Staehelin, Christian,Xin, Dawei,Wang, Wei. 2012

[7]Genetic Diversity of Banana Cultivars (Musa spp.) Using SRAP Markers. Wei, Junya,Wei, Shouxing,Chen, Yeyuan. 2009

[8]Glucose alleviates cadmium toxicity by increasing cadmium fixation in root cell wall and sequestration into vacuole in Arabidopsis. Shi, Yuan-Zhi,Shi, Yuan-Zhi,Shi, Yuan-Zhi,Wan, Jiang-Xue,Zheng, Shao-Jian,Zhu, Xiao-Fang,Li, Gui-Xin. 2015

[9]Effects of crude feruloyl and acetyl esterase solutions of Neocallimastix sp YQ1 and Anaeromyces sp YQ3 isolated from Holstein steers on hydrolysis of Chinese wildrye grass hay, wheat bran, maize bran, wheat straw and corn stalks. Yang, H. J.,Yang, H. J.,Yue, Q.,Cao, Y. C.,Zhang, D. F.,Wang, J. Q.. 2009

[10]Stable Isotopic Evidence for the Widespread Presence of Oxygen Containing Chemical Linkages between alpha-Cellulose and Lignin in Poaceae (Gramineae) Grass Leaves. Zhou, Youping,Yu, Huimin,Zavadlav, Sasa,Yin, Xijie,Su, Jing,Zhou, Youping,Wang, Yan,Yang, Hubiao,Zhou, Shuixiu,Zavadlav, Sasa. 2017

[11]Distinct catalytic capacities of two aluminium-repressed Arabidopsis thaliana xyloglucan endotransglucosylase/hydrolases, XTH15 and XTH31, heterologously produced in Pichia. Shi, Yuan Zhi,Zhu, Xiao Fang,Zheng, Shao Jian,Shi, Yuan Zhi,Miller, Janice G.,Gregson, Timothy,Fry, Stephen C.,Shi, Yuan Zhi.

[12]A precise and consistent assay for major wall polymer features that distinctively determine biomass saccharification in transgenic rice by near-infrared spectroscopy. Huang, Jiangfeng,Li, Ying,Wang, Yanting,Chen, Yuanyuan,Liu, Mingyong,Wang, Youmei,Zhang, Ran,Zhou, Shiguang,Li, Jingyang,Tu, Yuanyuan,Hao, Bo,Peng, Liangcai,Xia, Tao,Huang, Jiangfeng,Li, Ying,Wang, Yanting,Chen, Yuanyuan,Liu, Mingyong,Wang, Youmei,Zhang, Ran,Zhou, Shiguang,Li, Jingyang,Tu, Yuanyuan,Hao, Bo,Peng, Liangcai,Xia, Tao,Huang, Jiangfeng,Li, Ying,Wang, Yanting,Chen, Yuanyuan,Liu, Mingyong,Wang, Youmei,Zhang, Ran,Zhou, Shiguang,Li, Jingyang,Tu, Yuanyuan,Peng, Liangcai,Liu, Mingyong,Hao, Bo,Xia, Tao,Li, Jingyang. 2017

[13]Low-Temperature-Induced Expression of Rice Ureidoglycolate Amidohydrolase is Mediated by a C-Repeat/Dehydration-Responsive Element that Specifically Interacts with Rice C-Repeat-Binding Factor 3. Li, Juan,Qin, Rui-Ying,Li, Hao,Xu, Rong-Fang,Yang, Ya-Chun,Ni, Da-Hu,Ma, Hui,Li, Li,Wei, Peng-Cheng,Yang, Jian-Bo. 2015

[14]Comparative transcriptome analysis of sweet corn seedlings under low-temperature stress. Mao, Jihua,Yu, Yongtao,Yang, Jing,Li, Gaoke,Li, Chunyan,Qi, Xitao,Wen, Tianxiang,Hu, Jianguang. 2017

[15]Effects of low temperature and drought on the physiological and growth changes in oil palm seedlings. Shao, Hong-Bo,Cao, Hong-Xing,Sun, Cheng-Xu,Lei, Xin-Tao,Shao, Hong-Bo. 2011

[16]Effect of Low Temperature Stress on the Physiological and Biochemical Indexes in Cucumber Seedling Grafted on Bur Cucumber (Sicyos angulatus L.). Zhang, Sh. P.,Gu, X. F.,Wang, Y.. 2008

[17]Gene Expression and Activities of SOD in Cucumber Seedlings Were Related with Concentrations of Mn2+, Cu2+, or Zn2+ Under Low Temperature Stress. Yu Xian-chang,Yu Xian-chang,Gao Jun-jie,Li Tao. 2009

[18]Overexpression of Arabidopsis P3B increases heat and low temperature stress tolerance in transgenic sweetpotato. Ji, Chang Yoon,Jin, Rong,Kim, Ho Soo,Lee, Chan-Ju,Kang, Le,Kim, So-Eun,Kwak, Sang-Soo,Ji, Chang Yoon,Jin, Rong,Lee, Chan-Ju,Kang, Le,Kim, So-Eun,Kwak, Sang-Soo,Jin, Rong,Xu, Zhen,Xie, Yiping,Li, Hongmin,Ma, Daifu,Lee, Hyeong-Un,Lee, Joon Seol,Kang, Chang Ho,Chi, Yong Hun,Lee, Sang Yeol,Kang, Chang Ho,Chi, Yong Hun,Lee, Sang Yeol. 2017

[19]Overexpression of tomato mitogen-activated protein kinase SlMPK3 in tobacco increases tolerance to low temperature stress. Yu, Li,Yan, Jun,Zhu, Weimin,Yang, Yanjuan.

[20]Arbuscular mycorrhizal influence on growth, photosynthetic pigments, osmotic adjustment and oxidative stress in tomato plants subjected to low temperature stress. Latef, Arafat Abdel Hamed Abdel,He Chaoxing.

作者其他论文 更多>>

微信小程序