Phenotypic Characterization, Genetic Analysis and Gene-mapping for a Brittle Mutant in Rice 被引量：7

Phenotypic Characterization, Genetic Analysis and Gene-mapping for a Brittle Mutant in Rice

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摘要 Plant mechanical strength is an important agronomic trait of rice. An ethyl methane sulfonate （EMS）-induced rice mutant, fragile plant 2 （fp2）, showed morphological changes and reduced mechanical strength. Genetic analysis indicated that the brittle of fp2 was controlled by a recessive gene. The fp2 gene was mapped on chromosome 10. Anatomical analyses showed that the fp2 mutation caused the reduction of cell length and cell wall thickness, increasing of cell width, and the alteration of cell wall structure as well as the vessel elements. The consequence was a global alteration in plant morphology. Chemical analyses indicated that the contents of cellulose and lignin decreased, and hemicelluloses and silicon increased in fp2. These results were different from the other mutants reported in rice. Thus, fp2 might affect the deposition and patterning of microflbrils, the biosynthesis and deposition of cell wall components, which influences the formation of primary and secondary cell walls, the thickness of cell walls, cell elongation and expansion, plant morphology and plant strength in rice. Plant mechanical strength is an important agronomic trait of rice. An ethyl methane sulfonate （EMS）-induced rice mutant, fragile plant 2 （fp2）, showed morphological changes and reduced mechanical strength. Genetic analysis indicated that the brittle of fp2 was controlled by a recessive gene. The fp2 gene was mapped on chromosome 10. Anatomical analyses showed that the fp2 mutation caused the reduction of cell length and cell wall thickness, increasing of cell width, and the alteration of cell wall structure as well as the vessel elements. The consequence was a global alteration in plant morphology. Chemical analyses indicated that the contents of cellulose and lignin decreased, and hemicelluloses and silicon increased in fp2. These results were different from the other mutants reported in rice. Thus, fp2 might affect the deposition and patterning of microflbrils, the biosynthesis and deposition of cell wall components, which influences the formation of primary and secondary cell walls, the thickness of cell walls, cell elongation and expansion, plant morphology and plant strength in rice.

作者 Jian-Di Xu

机构地区 Rice Research Institute Shandong Rice Research Institute Key Laboratory of Crop Gene Resources and Improvement Rice and Sorghum Research Institute

出处《Journal of Integrative Plant Biology》 SCIE CAS CSCD 2008年第3期319-328,共10页 植物学报（英文版）

基金 the Program for Changjiang Scholars and Innovative ResearchTeam in University (IRT0453).

关键词 cell wall fragile plant （fp）2 gene mapping PHENOTYPE RICE cell wall fragile plant （fp）2 gene mapping phenotype rice

分类号 S511 [农业科学—作物学]

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参考文献2

1QIAN Qian,LI Yunhai,ZENG Dali,TENG Sheng,WANG Zhengke,LI Xueyong,DONG Zhigang,DAI Ning,SUN Lei,LI Jiayang.Isolation and genetic charac-terization of a fragile plant mutant in rice (Oryza sativa L.)[J].Chinese Science Bulletin,2001,46(24):2082-2085. 被引量：13
2沈恒胜,陈君琛,曾大力,涂杰峰,汤葆莎,滕胜.低纤维基因突变水稻稻草细胞壁组分动态发育分析[J].中国农业科学,2004,37(7):943-947. 被引量：6

二级参考文献34

1Hossain M T, Mori R, Soga K, Wakabayashi K, Kamisaka S,Fujii S Yamamoto R, Hoson T. Growth promotion and increase in cell wall extensibility by silicon in rice and some other Poaceae seedings. Journal of Plant Researcch, 2002,115:23-27.
2Van Soest P J, Robertson J B. Analysis of forages and fibrous food. A laboratory Manual for Animal Science 613.Cornell University, Ithaca, New York:1985: 74-75,80-82.
3Van Soest P J, Robertson J B, Lewis B A. Method for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Sciences, 1991, 74:3583-3597.
4Mengel K, Kirkby E A. Principles of Plant Nutrition (4th),Chap. 19 Further elements of importance. IPI Bern,Switzerland, 1987: 577-582.
5Fleming I. A primer on organosilicon chemistry. In: Ciba Foundation Symposium 121, Silicon Biochemistry. John Wiley & Sons, 1986: 112-119.
6Knight C T G, Kinrade S D. A primer on the aqueous chemistry of silicon. In: Datnoff L E, Snyder G H,Korndorfer G H. Silicon in Agriculture. Elsevier Science B V. 2001: 57-84.
7X. Chen,S. Temnykh,Y. Xu,Y. G. Cho,S. R. McCouch.Development of a microsatellite framework map providing genome-wide coverage in rice (Oryza sativa L.)[J]. TAG Theoretical and Applied Genetics . 1997 (4)
8H. Akagi,Y. Yokozeki,A. Inagaki,T. Fujimura.Microsatellite DNA markers for rice chromosomes[J]. Theoretical and Applied Genetics . 1996 (7)
9O. Panaud,X. Chen,S. R. McCouch.Development of microsatellite markers and characterization of simple sequence length polymorphism (SSLP) in rice (Oryza sativa L.)[J]. MGG Molecular & General Genetics . 1996 (5)
10K. Arumuganathan,E. D. Earle.Nuclear DNA content of some important plant species[J]. Plant Molecular Biology Reporter . 1991 (3)

共引文献17

1沈恒胜,陈君琛,黄进华,汤葆莎.水稻叶表皮硅体显微结构及其分布[J].福建农林大学学报（自然科学版）,2005,34(2):137-140. 被引量：11
2储黄伟,刘海生,李晖,王红梅,韦嘉励,李娜,丁淑燕,黄海,马红,黄潮锋,罗达,袁政,刘文轩,张大兵.水稻叶状颖壳突变体Oslh的遗传分析和OsLH基因的定位[J].植物生理与分子生物学学报,2005,31(6):594-598. 被引量：14
3胡标林,孔祥礼,包劲松,谢建坤.植物细胞壁性状的基因定位与克隆研究进展[J].江西农业学报,2006,18(2):17-21. 被引量：5
4张帆,万雪琴,潘光堂.玉米分子遗传图谱的构建[J].玉米科学,2006,14(3):6-9. 被引量：15
5韦存虚,谢佩松,周卫东,陈义芳,严长杰.水稻脆性突变体叶的解剖结构和化学特性[J].作物学报,2008,34(8):1417-1423. 被引量：9
6刘占宇,黄敬峰,王福民,王渊.估算水稻叶面积指数的调节型归一化植被指数[J].中国农业科学,2008,41(10):3350-3356. 被引量：38
7饶玉春,李跃,董国军,曾大力,钱前.水稻抗倒伏研究进展[J].中国稻米,2009,15(6):15-19. 被引量：26
8黄薇,姚清华,陈丽华,宋永康,黄敏敏,李玥仁.广谱抗真菌转基因水稻植株化学成分与结构动态变化[J].生物安全学报,2011,20(3):249-254.
9杨春艳,江玲,沈贝贝,冯志明,王新华,万建民.水稻品种‘南粳35’辐射诱变突变体的鉴定[J].南京农业大学学报,2012,35(3):1-6. 被引量：3
10FU Xue-qian,FENG Jing,YU Bin,GAO You-jun,ZHENG Yong-lian,YUE Bing.Morphological,Biochemical and Genetic Analysis of a Brittle Stalk Mutant of Maize Inserted by Mutator[J].Journal of Integrative Agriculture,2013,12(1):12-18. 被引量：2

同被引文献51

1王明庥,黄敏仁,阮锡根,吕士行,徐锡增,许农,邬荣领.黑杨派新无性系木材性状的遗传改良[J].南京林业大学学报（自然科学版）,1989,13(3):9-16. 被引量：31
2沈革志,王新其,王江,宛新杉,李琳,张景六.水稻脆杆突变体bcm581-1茎杆形态结构观察、理化测定和遗传分析[J].实验生物学报,2002,35(4):307-312. 被引量：8
3洪解放,张敏华,刘成,邹少兰,吴经才.代谢木糖生产乙醇的基因工程菌研究进展[J].食品与发酵工业,2005,31(1):114-118. 被引量：16
4汪海峰,朱军莉,刘建新,吴跃明,钱前,腾胜.饲喂脆茎全株水稻对生长肥育猪生长性能、养分消化和胴体品质的影响[J].畜牧兽医学报,2005,36(11):1139-1144. 被引量：25
5胡标林,孔祥礼,包劲松,谢建坤.植物细胞壁性状的基因定位与克隆研究进展[J].江西农业学报,2006,18(2):17-21. 被引量：5
6Lei Wang,Yun-Yuan Xu,Qi-Bin Ma,Dan Li,Zhi-Hong Xu,Kang Chong.Heterotrimeric G protein α subunit is involved in rice brassinosteroid response[J].Cell Research,2006,16(12):916-922. 被引量：29
7李文丽,吴先军.一个水稻脆性突变体的遗传分析与基因定位[J].核农学报,2006,20(6):500-502. 被引量：17
8陈介南.木质纤维生物转化乙醇技术[J].生物质化学工程,2006,40(B12):69-77. 被引量：7
9吴超,朱丽,林凤.水稻脆茎突变体的研究进展[J].安徽农业科学,2007,35(17):5085-5086. 被引量：10
10吴超,林凤.转基因脆茎水稻的收获指数研究[J].安徽农业科学,2007,35(19):5682-5683. 被引量：3

引证文献7

1王川丽,王令强,牟同敏.水稻脆性突变体nbc(t)的主要特性和脆性基因的初步定位[J].华中农业大学学报,2012,31(2):159-164. 被引量：5
2RAO YuChun,YANG YaoLong,XIN DeDong,LI XiaoJing,ZHAI KaiEn,MA BoJun,PAN JianWei,QIAN Qian,ZENG DaLi.Characterization and cloning of a brittle culm mutant (bc88) in rice (Oryza sativa L.)[J].Chinese Science Bulletin,2013,58(24):3000-3006. 被引量：11
3彭应财,刘文真,傅亚萍,王鹤潼,胡国成,陈温福,徐正进.水稻显性脆秆突变体Bc18的鉴定和基因定位[J].中国水稻科学,2016,30(2):127-135. 被引量：1
4舒亚洲,曾冬冬,秦冉,金晓丽,郑希,石春海.水稻脆秆突变体bc16的鉴定和基因精细定位[J].中国水稻科学,2016,30(4):345-355. 被引量：5
5QIN Ran,Delara AKHTER,YANG Chengcong,Ujjal Kumar NATH,Jamal ESHAG,JIN Xiaoli,SHI Chunhai.SRG1,Encoding a Kinesin-4 Protein,Is an Important Factor for Determining Grain Shape in Rice[J].Rice science,2018,25(6):297-307. 被引量：1
6姜鸿瑞,叶亚峰,何丹,任艳,杨阳,谢建,程维民,陶亮之,周利斌,吴跃进,刘斌美.一个新的水稻脆秆突变体bc17的鉴定及基因定位[J].作物学报,2021,47(1):71-79. 被引量：2
7李少锋.林木木材形成机制及材性改良研究进展[J].温带林业研究,2019,0(2):40-47. 被引量：5

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2黄峰,王永泽,周胜德,赵锦芳,赵筱,王金华.水稻脆性秸秆发酵产纤维乙醇的研究[J].可再生能源,2014,32(2):211-215. 被引量：7
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1刘玉龙,于永贵.3W-1500型喷雾机[J].现代化农业,1989(6):14-15.
2喻足衡,陈年镛,陈伯勇,李岩峰.杂交水稻直播栽培技术总结[J].闽东农业科技,2005(2):1-2.
3张鸿书,张希山,代连义,王志杰,舒晓峰.乌苏一号无芒雀麦新品种的特征特性研究[J].草原与草坪,2005,25(5):42-45. 被引量：4
4李勇,彭少兵,黄见良,熊栋梁,刘茜.叶肉导度的组成、大小及其对环境因素的响应[J].植物生理学报,2013,49(11):1143-1154. 被引量：19
5韩乃勇,巴哈古丽,夏依扎提,丁逸.甘草打沟直播栽培技术[J].农业科技通讯,2006(3):32-32.
6苏伟敏,靳雅惠,杨妮,王建.植物形态学及SSR标记在药用植物遗传分析中的应用[J].河北农业科学,2016,20(2):48-50. 被引量：4
7李银水,余常兵,廖星,胡小加,谢立华,张树杰,车志,廖祥生.施肥对油菜菌核病发生的影响[J].中国油料作物学报,2013,35(3):290-294. 被引量：17
8Iqbal Harbi,Salwa Jaber A1-Awadi,Ali Imad Mohammad Moner.Molecular Characterization of Olive Cultivars in Iraq Using SSR Markers and Compare with Phenotypic Characterization[J].Journal of Life Sciences,2012,6(12):1343-1350.
9张海波,曾冬冬,金晓丽,郑希,石春海.水稻少蘖直立穗突变体的形态特征和基因定位[J].中国水稻科学,2015,29(4):350-356. 被引量：2
10汪奎,张改生,袁正杰,孙瑞,位明明,史丽丽,牛娜.杂交小麦西杂5号及其亲本mtDNAs的RAPD分析[J].麦类作物学报,2008,28(4):560-563. 被引量：2

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