Difference between revisions of "Os06g0133000"

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Annotated Information

Function

Please input function information here. Carbohydrate analysis indicated that the content of amylose in GM077 seeds was significantly reduced, while that of amylopectin significantly rose as compared to the wild type BP034. The content of glucose, sucrose, total starch, cell-wall polysaccharides and oil were only slightly affected in the mutant as compared to the wild type. Suppression subtractive hybridization (SSH) experiments generated 116 unigenes in the mutant on the wild-type background. Among the 116 unigenes, three, AGP, ISA1 and SUSIBA2-like, were found to be directly involved in amylopectin synthesis, indicating their possible roles in redirecting carbon flux from amylose to amylopectin. A bioinformatics analysis of the putative SUSIBA2-like binding elements in the promoter regions of the upregulated genes indicated that the SUSIBA2-like transcription factor may be instrumental in promoting the carbon reallocation from amylose to amylopectin.

Expression

Please input expression information here. Analyses of carbohydrate and oil fractions and gene expression profiling on a global scale in the rice waxy mutant GM077 revealed several candidate genes implicated in the carbon reallocation response to an amylose deficiency, including genes encoding AGPase and SUSIBA2-like. We believe that AGP and SUSIBA2 are two promising targets for classical breeding and/or transgenic plant improvement to control the carbon flux between starch and other components in cereal seeds

Evolution

Please input evolution information here.

Waxy mutants of cereals have a high content of amylopectin and have been well characterized. However, the allocation of carbon to other components, such as beta-glucan and oils, and the regulation of the altered carbon distribution to amylopectin in a waxy mutant are poorly understood. In this study, we used a rice mutant, GM077, with a low content of amylose to gain molecular insight into how a deficiency of amylose affects carbon allocation to other end products and to amylopectin. We used carbohydrate analysis, subtractive cDNA libraries, and qPCR to identify candidate genes potentially responsible for the changes in carbon allocation in GM077 seeds

Labs working on this gene

Please input related labs here.

1.State Key Laboratory of Rice Biology, China National Rice Research Institute, 31006 Hangzhou, China

2.Department of Plant Biology & Forest Genetics, Uppsala BioCenter, Swedish University of Agricultural Sciences and Linnean Center for Plant Biology, P.O. Box 7080, SE 75007, Uppsala, Sweden

3.State Key Laboratory of Plant Genomics and National Center for Plant Gene Research, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China.

4.Institute of Food Crops,Jiangsu Academy of Agricultural Sciences/Jiangsu High Quality Rice R&D Center/Nanjing Branch of Chinese National Center for Rice Improvement, Nanjing 210014,China.

5.College of Agronomy and Biotechnology, Yunnan Agricultural University, Kunming 650201, China.

6.Key Laboratory of Biotechnology Research of Yunnan Province , Yunnan Academy of Agricultural Sciences, Kunming 650223 , China.

7.College of Life Science, Yunnan University , Kunming 650091 , China.

8.Chengdu Institute of Biology , Chinese Academy of Sciences, Chengdu 610041,China.

9.Rice Research Institute, Sichuan Agricultural University, Wenjiang 611130, China.

10.Key Laboratory of Southwest Crop Genetic Resource and Improvement, Ministry of Education, Sichuan Agricultural University, Ya’an 625014, China.

11.Rice Research Institute , Sichuan Agricultural University , Wenjiang 611130 , China.

12.Key Laboratory of Southwest Crop Genetic Resource and Improvement , Ministry of Education, Sichuan Agricultural University , Yacan 625014 , China.

13.Key Laboratory of Crop Genetics and Physiology of Jiangsu Province, Agricultural College, Yangzhou University, Yangzhou 225009, China

References

Please input cited references here. 1. Ming-Zhou Zhang;Jie-Hong Fang;Xia Yan;Jun Liu;Jin-Song Bao;Gunnel Fransson;Roger Andersson;Christer Jansson;Per Åman;Chuanxin Sun

 Molecular insights into how a deficiency of amylose affects carbon allocation -- carbohydrate and oil analyses and gene expression profiling in the seeds of a rice waxy mutant
 BMC Plant Biology, 2012, 12: 230 

2. Yan Su;Yuchun Rao;Shikai Hu;Yaolong Yang;Zhenyu Gao;Guanghen Zhang;Jian Liu;Jiang Hu;Meixian Yan;Guojun Dong;Li Zhu;Longbiao Guo;Qian Qian;Dali Zeng

 Map-based cloning proves qGC-6, a major QTL for gel consistency of japonica/indica cross, responds by Waxy in rice (Oryza sativa L.)
 Theoretical and Applied Genetics, 2011, 123(5): 859-867 

3. 姚姝;陈涛;张亚东;朱镇;赵凌;赵庆勇;周丽慧;王才林

 分子标记辅助选择聚合水稻暗胚乳突变基因Wx-mq和抗条纹叶枯病基因Stv-bi
 中国水稻科学, 2010, 24(4): 341-347 

4. Zhixi Tian;Qian Qian;Qiaoquan Liu;Meixian Yan;Xinfang Liu;Changjie Yan;Guifu Liu;Zhenyu Gao;Shuzhu Tang;Dali Zeng;Yonghong Wang;Jianming Yu;Minghong Gu;Jiayang Li

 Allelic diversities in rice starch biosynthesis lead to a diverse array of rice eating and cooking qualities
 Proceedings of the National Academy of Sciences, 2009, 106(51): 21760-21765 

5. P. Jayamani;S. Negrão;C. Brites;M.M. Oliveira

 Potential of Waxy gene microsatellite and single-nucleotide polymorphisms to develop japonica varieties with desired amylose levels in rice (Oryza sativa L.)
 Journal of Cereal Science, 2007, 46(2): 178-186 

6. 张娅丽; 许明辉; 曾亚文; 姚春馨; 陈善娜

 云南地方稻种Wx基因第一内含子供体+1位碱基变异与直链淀粉含量的关系
 中国水稻科学, 2007, 21(1): 20-24 

7. 刘玉花; 栾丽; 龙文波; 王兴; 孔繁伦; 何涛; 涂升斌

 同源四倍体和二倍体水稻Wx基因与淀粉品质的遗传关系
 中国水稻科学, 2007, 21(2): 143-149 

8. WAN Ying-xiu;DENG Qi-ming;WANG Shi-quan;LIU Ming-wei;ZHOU Hua-qiang;LI Ping

 Genetic Polymorphism of Wx Gene and Its Correlation with Main Grain Quality Characteristics in Rice
 Rice Science, 2007, 14(2): 85-93 

9. 陈刚; 王忠; 刘巧泉; 熊飞; 顾蕴洁; 顾国俊

 转反义Wx基因水稻颖果的发育及物质积累
 中国水稻科学, 2006, 20(3): 277-282 

10. 万映秀;邓其明;王世全;刘明伟;周华强;李平

 水稻Wx基因的遗传多态性及其与主要米质指标的相关性分析
 中国水稻科学, 2006, 20(6): 603-609 

11. CHEN Gang; WANG Zhong; LIU Qiao-quan; XIONG Fei; GU Yun-jie; GU Guo-jun

 Development and Substance Accumulation of Caryopsis in Transgenic Rice with Antisense Wx Gene
 Rice Science, 2006, 13(2): 106-112 

12. ZENG Rui-zhen; ZHANG Ze-min; HE Feng-hua; XI Zhang-ying; Akshay TALUKDAR; SHI Jun-qiong; QIN Li-jun; HUANG Chao-feng; ZHANG Gui-quan

 Identification of Multiple Alleles at the Wx Locus and Development of Single Segment Substitution Lines for the Alleles in Rice
 Rice Science, 2006, 13(1): 9-14 

13. 曾瑞珍; 张泽民; 何风华; 席章营; Akshay TALUKDAR; 施军琼; 秦利军; 黄朝锋; 张桂权

 水稻Wx复等位基因的鉴定及单片段代换系的建立
 中国水稻科学, 2005, 19(6): 495-500 

14. MAO Xing-xue; LIU Yan-zhuo; XIAO Xin; CHEN Jian-wei; LUO Wen-yong; LI Xiao-fang

 A One-Step PCR Method for Detecting the First Base of Splice Donor of Wx Intron 1 in Rice
 Rice Science, 2004, 11(5-6): 342-344 

15. Yamanaka-S;Nakamura-I;Watanabe-K-N;Sato-Y-I

 Identification of SNPs in the waxy gene among glutinous rice cultivars and their evolutionary significance during the domestication process of rice
 Theoretical and Applied Genetics, 2004, 108(7): 1200-1204 

16. Zhongyi Li;Fei Sun;Shoumin Xu;Xiusheng Chu;Y. Mukai;M. Yamamoto;Shahjahan Ali;Lynette Rampling;Behjat Kosar-Hashemi;Sadequr Rahman;Matthew K. Morell

 The structural organisation of the gene encoding class II starch synthase of wheat and barley and the evolution of the genes encoding starch synthases in plants
 Functional & Integrative Genomics, 2003, 3(1-2): 76-85 

17. Y. Sato;T. Nishio

 Mutation detection in rice waxy mutants by PCR-RF-SSCP
 Theoretical and Applied Genetics, 2003, 107: 560-567 

18. Hiroyuki Sato; Yasuhiro Suzuki; Makoto Sakai and Tokio Imbe

 Molecular Characterization of Wx-mq, a Novel Mutant Gene for Low-amylose Content in Endosperm of Rice (Oryza sativa L.)
 Breeding Science, 2002, 52(2): 131-135 

19. 于恒秀; 刘巧泉; 陈秀花; 陆美芳; 王兴稳; 王宗阳; 顾铭洪

 根癌农杆菌介导的水稻转化系统的优化及转反义Wx基因植株的获得
 中国水稻科学, 2002, 16(4): 304-310 

20. Ichiho Mikami;Munetoshi Aikawa;Hiro-Yuki Hirano and Yoshio Sano

 Altered tissue-specific expression at the Wx gene of the opaque mutants in rice
 Euphytica, 1999, 105(2): 91-97 

21. Hiro-Yuki Hirano;Mitsugu Eiguchi;Yoshio Sano

 A single base change altered the regulation of the Waxy gene at the posttranscriptional level during the domestication of rice
 Molecular Biology and Evolution, 1998, 15(8): 978-987 

22. Masayuki Isshiki;Kazuko Morino;Midori Nakajima;Ron J. Okagaki;Susan R. Wessler;Takeshi Izawa;Ko Shimamoto

 A naturally occurring functional allele of the rice waxy locus has a GT to TT mutation at the 5' splice site of the first intron
 The Plant Journal, 1998, 15(1): 133-138 

23. N. M. Ayres;A. M. McClung;P. D. Larkin;H. F. J. Bligh;C. A. Jones;W. D. Park

 Microsatellites and a single-nucleotide polymorphism differentiate apparentamylose classes in an extended pedigree of US rice germ plasm
 Theoretical and Applied Genetics, 1997, 94(6-7): 773-781 

24. Zong-Yang Wang;Fei-Qin Zheng;Ge-Zhi Shen;Ji-Ping Gao;D. Peter Snustad;Min-Gang Li;Jing-Liu Zhang;Meng-Min Hong

 The amylose content in rice endosperm is related to the post-transcriptional regulation of the waxy gene
 The Plant Journal, 1995, 7(4): 613-622 

25. 何祖华; 华金渭; 申宗坦

 水稻wx基因对籽粒糖类积累和萌发种子淀粉酶活力的影响
 中国水稻科学, 1994, 8(1): 21-26 

26. 郑柔; 奚永安; 林贻滋

 利用水稻糯与非糯(近)等基因系探讨WX基因对成熟胚培养力的影响
 中国水稻科学, 1993, 7(1): 7-10 

27. Zong-yang Wang; Zhi-liang Wu; Yan-yan Xing; Fei-gin Zheng; Xiao-Ii Guo; Wei-guo Zhang and Meng-min Hong

 Nucleotide sequence of rice waxy gene
 Nucleic Acids Research, 1990, 18(19): 5898- 

28. Yoshio Sano;Mitsuko Katsumata;Kazutoshi Okuno

 Genetic studies of speciation in cultivated rice. 5. Inter- and intraspecific differentiation in the waxy gene expression of rice
 Euphytica, 1986, 35(1): 1-9 

29. Y. Sano;M. Maekawa;H. Kikuchl

 Temperature effects on the Wx protein level and amylose content in the endosperm of rice
 Journal of Heredity, 1985, 76(3): 221-222 

30. Yoshio Sano

 Differential regulation of waxy gene expression in rice endosperm
 Theoretical and Applied Genetics, 1984, 68(5): 467-473

Structured Information

 ORGANISM  Oryza sativa Japonica Group
           Eukaryota; Viridiplantae; Streptophyta; Embryophyta; Tracheophyta;
           Spermatophyta; Magnoliophyta; Liliopsida; Poales; Poaceae; BEP
           clade; Ehrhartoideae; Oryzeae; Oryza.