农科机构知识库联盟

Physiological and metabolic enzymes activity changes in transgenic rice plants with increased phosphoenolpyruvate carboxylase activity during the flowering stage

文献类型：外文期刊

第一作者： Xia, Li

作者： Xia, Li;Cao, Wang;Xia, Li

作者机构：

关键词： Phosphoenolpyruvate carboxylase (PEPC);Transgenic rice;Carbon metabolic enzyme;Nitrogen metabolic enzyme;Photosynthesis

期刊名称：ACTA PHYSIOLOGIAE PLANTARUM （影响因子：2.354；五年影响因子：2.711 ）

ISSN：

年卷期：

页码：

收录情况： SCI

摘要： To compare the differences in physiology and metabolism between phosphoenolpyruvate carboxylase (PEPC) transgenic rice and its control, untransformed wild rice, dry matter accumulation, soluble sugar, starch and protein contents and enzyme activitieswere determined in different plant parts during flowering. Results revealed that PEPC transgenic rice had higher dry weights for leaf, stem and sheath as well as panicle than the untransformed wild rice did, with the largest increase in the panicle. Soluble sugar and protein content in the grains of PEPC transgenic rice were significantly enhanced while starch content changed less. PEPC transgenic rice exhibited high levels of PEPC activity, manifesting in high net photosynthetic rates during flowering.Moreover, transgenic rice with high PEPC expression levels also had elevated levels of the enzymes such as sucrose-p-synthase and sucrose synthase, which may confer a higher capacity to assimilate CO2 into sucrose. Little increase in grain starch content was observed in transgenic plants due to the stable activities of starch synthase and Q enzyme. However, the PEPC transgenic rice plant induced the activities of nitrate reductase, glutamate oxaloacetate transaminase, glutamate pyruvate transaminase, glutamine synthetase, and asparagine synthase to high levels, as compared with the untransformed rice plant. PEPC activity was correlated with protein content in grains and the enzymes of nitrogen metabolism, suggesting that high PEPC activity in transgenic rice might be able to redirect carbon and nitrogen flow by regulating some enzymes related to carbon or nitrogen metabolisms. These results may help to understand how the C3 plants possessing a C4-like photosynthesis pathway worked by expression of PEPC.

分类号： Q94

相关文献

[1]CO2 exchange and chlorophyll fluorescence of phosphoenolpyruvate carboxylase transgenic rice pollen lines. Ling, Li-Li,Lin, Hong-Hui,Ji, Ben-Hua,Jiao, De-Mao. 2006

[2]A limited photosynthetic C-4-microcycle and its physiological function in transgenic rice plant expressing the maize PEPC gene. Ji, BH,Zhu, SQ,Jiao, DM. 2004

[3]Physiological characteristics and metabolomics of transgenic wheat containing the maize C-4 phosphoenolpyruvate carboxylase (PEPC) gene under high temperature stress. Qi, Xueli,Qi, Xueli,Xu, Weigang,Zhang, Jianzhou,Guo, Rui,Zhao, Mingzhong,Hu, Lin,Wang, Huiwei,Dong, Haibin,Li, Yan.

[4]Over-expression of phosphoenolpyruvate carboxylase cDNA from C4 millet (Seteria italica) increase rice photosynthesis and yield under upland condition but not in wetland fields. Ding, Zai-Song,Huang, Su-Hua,Zhou, Bao-Yuan,Sun, Xue-Fang,Zhao, Ming. 2013

[5]Drought tolerance and proteomics studies of transgenic wheat containing the maize C-4 phosphoenolpyruvate carboxylase (PEPC) gene. Qin, Na,Xu, Weigang,Hu, Lin,Li, Yan,Wang, Huiwei,Qi, Xueli,Fang, Yuhui,Hua, Xia.

[6]Pyramiding expression of maize genes encoding phosphoenolpyruvate carboxylase (PEPC) and pyruvate orthophosphate dikinase (PPDK) synergistically improve the photosynthetic characteristics of transgenic wheat. Zhang, HuiFang,Zhang, HuiFang,Xu, WeiGang,Wang, HuiWei,Hu, Lin,Li, Yan,Qi, XueLi,Zhang, Lei,Li, ChunXin,Hua, Xia.

[7]Production of transgenic rice new germplasm with strong resistance against two isolations of Rice stripe virus by RNA interference. Ma, Jin,Song, Yunzhi,Wu, Bin,Li, Kaidong,Zhu, Changxiang,Wen, Fujiang,Jiang, Mingsong. 2011

[8]Production of marker-free and RSV-resistant transgenic rice using a twin T-DNA system and RNAi. Jiang, Yayuan,Sun, Lin,Li, Kaidong,Song, Yunzhi,Zhu, Changxiang,Jiang, Mingsong.

[9]Dimeric artificial microRNAs mediate high resistance to RSV and RBSDV in transgenic rice plants. Sun, Lin,Lin, Chao,Du, Jinwen,Song, Yunzhi,Liu, Hongmei,Zhou, Shumei,Wen, Fujiang,Zhu, Changxiang,Jiang, Mingsong.

[10]Characteristics of CO2 exchange and chlorophyll fluorescence of transgenic rice with C-4 genes. Huang, XQ,Jiao, DM,Chi, W,Ku, MSB. 2002

[11]The characteristics of CO2 assimilation of photosynthesis and chlorophyll fluorescence in transgenic PEPC rice. Jiao, DM,Li, X,Huang, XQ,Wei, C,Kuang, TY,Maurice, KSB. 2001

[12]Establishment of a rice transgene flow model for predicting maximum distances of gene flow in Southern China. Yao, Kemin,Hu, Ning,Chen, Wanlong,Li, Renzhong,Yuan, Qianhua,Wang, Feng,Qian, Qian. 2008

[13]Expression of an elicitor-encoding gene from Magnaporthe grisea enhances resistance against blast disease in transgenic rice. Qiu, Dewen,Mao, Jianjun,Yang, Xiufen,Zeng, Hongmei. 2009

[14]Isolation of the endosperm-specific LPAAT gene promoter from coconut (Cocos nucifera L.) and its functional analysis in transgenic rice plants. Zheng, Yusheng,Wang, Zhekui,Li, Dongdong,Xu, Li,Zhou, Peng,Ye, Rongjian,Lin, Yongjun,Ye, Rongjian,Lin, Yongjun. 2010

[15]Lethal and Sub-Lethal Effects of Transgenic Rice Containing cry1Ac and CpTI Genes on the Pink Stem Borer, Sesamia inferens (Walker). Han Lan-zhi,Hou Mao-lin,Wu Kong-ming,Peng Yu-fa,Wang Feng. 2011

[16]Event-specific qualitative and quantitative detection of transgenic rice Kefeng-6 by characterization of the transgene flanking sequence. Wang, Wei-Xia,Lai, Feng-Xiang,Fu, Qiang,Zhu, Ting-Heng. 2011

[17]Transgenic fertile japonica rice plants expressing a modified crylA(b) gene resistant to yellow stem borer. Wu, C,Fan, Y,Zhang, C,Oliva, N,Datta, SK. 1997

[18]Impacts of transgenic cry1Ab rice on non-target planthoppers and their main predator Cyrtorhinus lividipennis (Hemiptera : Miridae) - A case study of the compatibility of Bt rice with biological control. Liu, Zhi-Cheng,Ye, Gong-yin,Shen, Zhi-cheng,Hu, Cui,Peng, Yu-fa,Altosaar, Illimar,Shelton, Anthony M.. 2007

[19]Functional and numerical responses of Cyrtorhinus lividipennis to eggs of Nilaparvata lugens are not affected by genetically modified herbicide-tolerant rice. Huang Qian,Long Li-ping,Ling Yan,Huang Suo-sheng,Wu Bi-qiu,Huang Feng-kuan,Cai Jian-he,Chen Yu-chong,Xiao Guo-ying. 2015

[20]Efficient Agrobacterium-mediated transformation of rice by phosphomannose isomerase/mannose selection. Ding Zai-Song,Zhao Ming,Jing Yu-Xiang,Li Liang-Bi,Kuang Ting-Nin. 2006

Physiological and metabolic enzymes activity changes in transgenic rice plants with increased phosphoenolpyruvate carboxylase activity during the flowering stage

作者其他论文 更多>>

作者其他论文更多>>