Scientia Agricultura Sinica ›› 2015, Vol. 48 ›› Issue (13): 2487-2496.doi: 10.3864/j.issn.0578-1752.2015.13.001

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS •     Next Articles

Genetic Analysis and Fine Mapping of a Novel Rolled Leaf Gene in Rice

LIU Chen, KONG Wei-yi, YOU Shi-min, ZHONG Xiu-juan, JIANG Ling, ZHAO Zhi-gang, WAN Jian-min   

  1. College of Agriculture, Nanjing Agricultural University/State Key Laboratory of Crop Genetics and Germplasm Enhancement, Nanjing 210095
  • Received:2015-01-05 Online:2015-07-01 Published:2015-07-01

RichHTML

13

PDF

778

Cited

3

Abstract: 【Objective】Rice leaf is not only a vital site for photosynthesis, but also an important factor for ideal plant architecture in rice. This study is useful in map-based cloning of target gene and marker-assisted transferring rolled gene in rice breeding programs. 【Method】A mutant rl16(t) (rolled leaf 16) with rolled leaves was derived from the Indica type rice 9311(wild -type WT) via the radiation of 60Co-γ. Then, it was planted for several generations to test the stability of mutant phenotype in the field. At heading stage, rl16(t) and WT were randomly selected 10 strains to measure the main agronomic traits including leaf rolling index, respectively.The same part of leaf of rl16(t) and WT was taken and fixed by FAA, then dehydrated in series ethanol and paraffin embedding. After that, the fixed leaf was incised to 10 microns slices and these slices were stained by sarranine. Finally, the bulliform cells were observed, the number of them was counted and their area was measured under the microscope. Chlorophyll content of rl16(t) and WT were tested at tilling stage. In addition, the leaf phenotype of the F1 plants and F2 population were investigated, and the mode of rolled gene inheritance was analyzed by chi-square test. To fine-map the Rl16(t), an F2 population was generated by crossing between the rl16(t) mutant and a Japonica type rice Dianjingyou. Target gene was limited by simple sequence repeat (SSR) and InDel markers. Three known domain structure genes in the mapped region were analyzed by gene quantitative expression. 【Result】Compared with wild-type, the mutant had not only typically adaxially rolled leaves, but also decreased height and panicle length, as well as the seed setting percentage. The whole plant of rl16(t) appeared leaf longitudinally rolled into the approximate tubular phenotype at seedling stage (three leaves and one new), then kept it at the rest of time. On the contrary, WT had flat leaves in the entire life. Paraffin section of flag leaf indicated that the number and area of bulliform cell of rl16(t) were lower than that of WT. The number of bulliform cell in WT was (385.1±43.6) cells/mm2, while that in the rl16(t) was(1059.5±254.4) cells/mm2. However, for the bulliform cell, there were no significant and obvious changes of rl16(t) and WT. The carotenoid content of rl16(t) was lower than that of WT, but the chlorophyll a, chlorophyll b and total chlorophyll content were significantly higher than that of WT. All of the F1 hybrid between rl16(t) and WT indicated flat leaves, meanwhile, in an F2 population, rolled and flat leaf plants segregated in a 3﹕1 ratio (97 rolled versus 326 flat leaves, chi-square = 0.86<chi-square 0.05 = 3.84). Cytological analysis indicated that the rolled leaf phenotype might be caused by the change of number and size of bulliform cells. Genetic analysis indicated that the rolled leaf characters were controlled by a recessive nuclear gene. Using SSR markers, Rl16(t) was initially mapped in the region between the RM23769 and RM23916 on the long arm of chromosome 9. Furthermore, with enlarged population and more developed InDel markers, Rl16(t) was finally delimited to a 51 kb region governed by the InDel marker DF70 and SSR marker RM23818. Three known structure coding genes (LOC_Os09g09320, LOC_Os09g09360, LOC_Os09g09370) were predicted in the limited interval. The expression of LOC_Os09g09320 and LOC_Os09g09370 in rl16(t) showed no obvious differences with that of WT, but the expression of LOC_Os09g09360 in rl16(t) was only the half of WT.As for quantitative expression analysis of the eight genes that contributed to the rolled leaf, seven of them (SLL1, ROC5, RL14, SRL1, ACL1, NRL1, NAL7)had a decline in the rl16(t) mutant, while OSZHD1 appeared a rise.【Conclusion】The rolled leaf of rl16(t) was due to reduced number and area of bulliform cells. In addition, thisgene would be a putative novel rolled leaf gene. As the result of quantitative gene expression, LOC_Os09g09360 may be the target genes.

Key words: rice (Oryza sativa L.), rolled leaf traits, genetic analysis, fine mapping

[1]    袁隆平. 杂交水稻超高产育种. 杂交水稻, 1997, 12(6): 1-6.
Yuan L P. Breeding for super high-yielding in hybrid rice. Hybrid Rice, 1997, 12(6): 1-6. (in Chinese)
[2]    朱德峰, 林贤青, 曹卫星. 不同叶片卷曲度杂交水稻的光合特性比较. 作物学报, 2001, 27(3): 329-333.
Zhu D F, Lin X Q, Cao W X. Comparison of leaf photosynthetic characteristics among rice hybrids with different leaf rolling index. Acta Agronomica Sinica, 2001, 27(3): 329-333. (in Chinese)
[3]    陈代波, 程式华, 曹立勇. 水稻窄叶性状的研究进展. 中国稻米, 2010, 16(3) : 1-4.
Chen D B, Cheng S H, Cao L Y. The research progress of rice narrow leaf traits. China Rice, 2010, 16(3): 1-4. (in Chinese)
[4]    Khush G S, Kinoshita T. Rice karyotype, marker genes, and linkage groups//Khush G S, Toenniessen G H. Rice Biotechnology. Wallingford: CAB International and IRRI, 1991: 83-108.
[5]    李仕贵, 马玉清, 何平, 黎汉云, 陈英, 周开达, 朱立煌. 一种未知的卷叶基因的识别和定位. 四川农业大学学报, 1998, 16(4): 391-393.
Li S G, Ma Y Q, He P, Li H Y, Chen Y, Zhou K D, Zhu L H. Genetic analysis and mapping the flag leaf roll in rice (Oryza sativa L.). Journal of Sichuan Agricultural University, 1998, 16(4): 391-393. (in Chinese)
[6]    严长杰, 严松, 张正球, 梁国华, 陆驹飞, 顾铭洪. 一个新的水稻卷叶突变体rl9(t)的遗传分析和基因定位. 科学通报, 2005, 50(24): 2757-2762.
Yan C J, Yan S, Zhang Z Q, Liang G H, Lu J F, Gu M H. Genetic analysis and gene fine mapping for a rice novel mutant rl9(t) with rolling leaf character. Chinese Science Bulletin, 2005, 50(24): 2757-2762. (in Chinese)
[7]    Yi J C, Zhuang C X, Wang X J, Cao Y P, Liu Y G, Mei M T. Genetic analysis and molecular mapping of a rolling leaf mutation gene in rice. Journal of Integrative Plant Biology, 2007, 49: 1746-1753.
[8]    施勇烽, 陈洁, 刘文强, 黄奇娜, 沈波, Hei Leung, 吴建利. 一个新的水稻卷叶突变体的遗传分析与基因定位. 中国科学: C辑, 2009, 39(4): 407-412.
Shi Y F, Chen J, Liu W Q, Huang Q N, Shen B, Hei Leung, Wu J L. A new rice leaf mutant of genetic analysis and gene location. Science in China Series C:Life Sciences, 2009, 39(4): 407-412. (in Chinese)
[9]    余东, 吴海滨, 杨文韬, 巩鹏涛, 李有志, 赵德刚. 水稻单侧卷叶突变体B157遗传分析及基因初步定位. 分子植物育种, 2008, 6(2): 220-226.
Yu D, Wu H B, Yang W T, Gong P T, Li Y Z, Zhao D G. Genetic analysis and mapping of the unilateral rolled leaf trait of rice mutant B157. Molecular Plant Breeding, 2008, 6(2): 220-226. (in Chinese)
[10]   Wang D K, Liu H Q, Li K L, Li S J, Tao Y Z. Genetic analysis and gene mapping of a narrow leaf mutant in rice (Oryza sativa L.). Chinese Science Bulletin, 2009, 54(5): 752-758.
[11]   罗远章, 赵芳明, 桑贤春, 凌英华, 杨正林, 何光华. 水稻新型卷叶突变体rl12(t)的遗传分析和基因定位. 作物学报, 2009, 35(11): 1967-1972.
Luo Y Z, Zhao F M, Sang X C, Ling Y H, Yang Z L, He G H. Genetic analysis and gene mapping of a novel rolled leaf mutant rl12(t) in rice. Acta Agronomica Sinica, 2009, 35(11): 1967-1972. (in Chinese)
[12]   顾兴友, 顾铭洪. 一种水稻卷叶性状的遗传分析. 遗传, 1995, 17(5): 20-23.
Gu X Y, Gu M H. A genetic analysis of rice leaf traits. Hereditas, 1995, 17(5): 20-23. (in Chinese)
[13]   Fang L K, Zhao F M, Cong Y F, Sang X C, Du Q, Wang D Z, Li Y F, Ling Y H, Yang Z L, He G H. Rolling-leaf14 is a 2OG-Fe(Ⅱ) oxygenase family protein that modulates rice leaf rolling by affecting secondary cell wall formation in leaves. Plant Biotechnology Journal, 2012, 10(5): 524-532.
[14]   张礼霞, 刘合芹, 于新, 王林友, 范宏环, 金庆生, 王建军. 水稻卷叶突变体rl15(t)的生理学分析及基因定位. 中国农业科学, 2014, 47(14): 2881-2888.
Zhang L X, Liu H Q, Yu X, Wang L Y, Fan H H, Jin Q S, Wang J J. Molecular mapping and physiological characterization of a novel mutant rl15(t) in rice. Scientia Agricultura Sinica, 2014, 47(14): 2881-2888. (in Chinese)
[15]   Yan S, Yan C J, Zeng X H, Yang Y C, Fang Y W, Tian C Y, Sun Y W, Cheng Z K, Gu M H. Rolled leaf 9, encoding a GARP protein, regulates the leaf abaxial cell fate in rice. Plant Molecular Biology, 2008, 68: 239-250.
[16]   Zhang G H, Xu Q, Zhu X D, Qian Q, Xue H W. SHALLOT-LIKE1 is a KANADI transcription factor that modulates rice leaf rolling by regulating leaf abaxial cell development. The Plant Cell, 2009, 21(3): 719-735.
[17]   Zou L P, Sun X H, Zhang Z G, Liu P, Wu J X, Tian C J, Qiu J L, Lu T G. Leaf rolling controlled by the homeodomain leucine zipper class IV gene Roc5 in rice. Plant Physiology, 2011, 156: 1589-1602.
[18]   Li L, Shi Z Y, Li L, Shen G Z, Wang X Q, An L S, Zhang J L. Overexpression of ACL1 (abaxially curled leaf 1) increased bulliform cells and induced abaxial curling of leaf blades in rice. Molecular Plant, 2010, 3: 807-817.
[19]   Xiang J J, Zhang G H, Qian Q, Xue H W. SEMI-ROLLED LEAF1 encodes a putative glycosylphosphatidylinositol-anchored protein and modulates rice leaf rolling by regulating the formation of bulliform cells. Plant Physiology, 2012, 159(4): 1488-1500.
[20]   Hu J, Zhu L, Zeng D L, Gao Z Y, Guo L B, Fang Y X, Zhang G H, Dong G J, Yan M X, Liu J, Qian Q. Identification and characterization of NARROW AND ROLLED LEAF 1, a novel gene regulating leaf morphology and plant architecture in rice. Plant Molecular Biology, 2010, 73(3): 283-292.
[21]   Fujino K, Matsuda Y, Ozawa K, Nishimura T, Koshiba T, Fraaije M W, Sekiguchi H. NARROW LEAF 7 controls leaf shape mediated by auxin in rice. Molecular Genetics and Genomics, 2008, 279: 499-507.
[22]   Woo Y M, Park H J, Su’udi M J, Yang J, Park J J, Back K, Park Y M, An G. Constitutively wilted 1, a member of the rice YUCCA gene family, is required for maintaining water homeostasis and an appropriate root to shoot ratio. Plant Molecular Biology, 2007, 65(1/2): 125-136.
[23]   Xu Y, Wang Y H, Long Q Z, Wang Y L, Wan J M. Overexpression of OsZHD1, a zinc finger homeodomain class homeobox transcription factor, induces abaxially curled and drooping leaf in rice. Planta, 2013, 239: 803-816.
[24]   高艳红, 吕川根, 王茂青, 王澎, 闫晓燕, 谢坤, 万建民. 水稻卷叶性状QTL的初步定位. 江苏农业学报, 2007, 23(1): 5-10.
Gao Y H, Lü C G, Wang M Q, Wang P, Yan X Y, Xie K, Wan J M. QTL mapping for rolled leaf gene in rice. Jiangsu Journal of Agricultural Sciences, 2007, 23(1): 5-10. (in Chinese)
[25]   Lichtenthaler H K. Chlorophylls and carotenoids: Pigments ofphotosynthetic biomembranes. Method in Enzymology, 1987, 48: 350-382.
[26]   Murray M G, Thompson W F. Rapid isolation of high-molecular weight plant DNA. Nucleic Acids Research, 1980, 8: 4321-4325.
[27]   陈晖, 何海福. 植物组织总RNA提取方法的进展研究. 甘肃农业, 2006(8): 226.
Chen H, He H F. Progress in research of plant tissue total RNA extraction method. Gansu Agricultural, 2006(8): 226. (in Chinese)
[28]   Xu L, Yang L, Huang H. Transcriptional post-transcriptional and post-translational regulations of gene expression during leaf polarity formation. Cell Research, 2007, 17: 512-519.
[29]   严松, 严长杰, 顾铭洪. 植物叶发育的分子机理. 遗传, 2008,  30(9): 1127-1135.
Yan S, Yan C J, Gu M H. Plants leaf development molecular mechanism. Hereditas, 2008, 30(9): 1127-1135. (in Chinese)
[30]   Waites R, Hudson A. Phantastica, a gene required for dorsoventrality of leaves in Antirrhinum majus. Development, 1995, 121: 2143-2154.
[31]   Emery J F, Floyd S K, Alvarez J, Eshed Y, Hawker N P, Izhaki A, Baum S F, Bowman J L. Radial patterning of Arabidopsis shoots by classⅢHD-ZIP and KANADI genes. Current Biology, 2003, 13: 1768-1774.
[32]   Siegfried K R, Eshed Y, Baum S F, Otsuga D, Drews G N, Bowman J L. Members of the YABBY gene family specify abaxial cell fate in Arabidopsis. Development, 1999, 126: 4117-4128.
[33]   Kerstetter R A, Bollman K, Taylor A, Bomblies K, Poethig R S. KANADI regulates organ polarity in Arabidopsis. Nature, 2001, 411: 706-709.
[34]   Shi Z Y, Wang J, Wan X S, Shen G Z, Wang X Q, Zhang J L. Over-expression of rice OsAGO7 gene induces upward curling of the leaf blade that enhanced erect-leaf habit. Planta, 2007, 226(1): 99-108.
[35]   Juarez M T, Kui J S, Thomas J, Heller B A, Timmermans M C P. MicroRNA-mediated repression of rolled leaf1 specifies maize leaf polarity. Nature, 2004, 428: 84-88.
[36]   Kidner C A, Martienssen R A. Spatially restricted microRNA directs leaf polarity through ARGONAUTE1. Nature, 2004, 428: 81-84.
[37]   Chitwood D H, Guo M J, Nogueira F T S, Timmermans M C P. Establishing leaf polarity:the role of small RNAs and positional signals in the shoot apex. Development, 2007, 134: 813-823.
[38]   邵元健, 潘存红, 陈宗祥, 左示敏, 张亚芳, 潘学彪. 水稻不完全隐性卷叶主基因rl(t)的精细定位. 科学通报, 2005, 50(19): 2107-2113.
Shao Y J, Pan C H, Chen Z X, Zuo S M, Zhang Y F, Pan X B. Fine mapping of a incomplete recessive major rolled leaf gene rl(t). Chinese Science Bulletin, 2005, 50(19): 2107-2113. (in Chinese)
[39]   Zhao Y D, Christensen S K, Fa Nkhauser C, Cashman J R, Cohen J D, Weige D, Chory J. A role for flavin monooxygenase-like enzymes in aux in biosynthesis. Science, 2001, 291(5502): 306-309.
[40]   Tobena Santamaria R, Bliek M, Ljung K, Sandberg G, Mol J N M, Souer E, Koes R. FLOOZY of petunia is a flavin mono oxygenase- like protein required for the specification of leaf and flower architecture. Genes and Development, 2002, 16(6): 753-763.
[41]   Fujino K, M atsuda Y, Ozawa K, Nishimura T, Koshiba T, Sekiguchi N W F H. Narrow leaf 7 controls leaf shape mediated by auxin in rice. Molecular Genomics and Genomics, 2008, 279(15): 499-507.
[1] WANG Kai,ZHANG HaiLiang,DONG YiXin,CHEN ShaoKan,GUO Gang,LIU Lin,WANG YaChun. Definition and Genetic Parameters Estimation for Health Traits by Using on-Farm Management Data in Dairy Cattle [J]. Scientia Agricultura Sinica, 2022, 55(6): 1227-1240.
[2] LONG WeiHua,PU HuiMing,GAO JianQin,HU MaoLong,ZHANG JieFu,CHEN Song. Creation of High-Oleic (HO) Canola Germplasm and the Genetic and Physiological Analysis on HO Trait [J]. Scientia Agricultura Sinica, 2021, 54(2): 261-270.
[3] KunNeng ZHOU,JiaFa XIA,Peng YUN,YuanLei WANG,TingChen MA,CaiJuan ZHANG,ZeFu LI. Transcriptome Research of Erect and Short Panicle Mutant esp in Rice [J]. Scientia Agricultura Sinica, 2020, 53(6): 1081-1094.
[4] DUAN YouHou,LU Feng. Genetic Analysis on Growth Period and Plant Height Traits of Early-maturing Dwarf Sorghum Male-Sterile Line P03A [J]. Scientia Agricultura Sinica, 2020, 53(14): 2828-2839.
[5] GONG ChengSheng, ZHAO ShengJie, LU XuQiang, HE Nan, ZHU HongJu, DOU JunLing, YUAN PingLi, LI BingBing, LIU WenGe. Chemical Compositions and Gene Mapping of Wax Powder on Watermelon Fruit Epidermis [J]. Scientia Agricultura Sinica, 2019, 52(9): 1587-1600.
[6] ZHOU JiaQin,ZHU JunZhao,YANG SiXue,ZHU ZhouJie,YAO Jie,ZHENG WenJuan,ZHU ShiHua,DING WoNa. Cloning and Functional Analysis of a Root Development Related Gene OsKSR7 in Rice (Oryza sativa L.) [J]. Scientia Agricultura Sinica, 2019, 52(5): 777-785.
[7] XU YunMei, LI YuMei, JIA YuXin, ZHANG ChunZhi, LI CanHui, HUANG SanWen, ZHU GuangTao. Fine Mapping and Candidate Genes Analysis for Regulatory Gene of Anthocyanin Synthesis in Red-Colored Tuber Flesh [J]. Scientia Agricultura Sinica, 2019, 52(15): 2678-2685.
[8] SONG Xi, PU DingFu, TIAN LuShen, YU QingQing, YANG YuHeng, Dai BingBing, ZHAO ChangBin, HUANG ChengYun, DENG WuMing. Genetic Analysis and Characterization of Hormone Response of Semi-Dwarf Mutant dw-1 in Brasscia napus L. [J]. Scientia Agricultura Sinica, 2019, 52(10): 1667-1677.
[9] XIE Jia, ZHANG XiaoBo, TAO YiRan, XIONG YuZhen, ZHOU Qian, SUN Ying, YANG ZhengLin, ZHONG BingQiang, SANG XianChun. Identification and Gene Mapping of a Shorten Panicle and Seed Mutant sps1 in Rice (Oryza sativa L.) [J]. Scientia Agricultura Sinica, 2018, 51(9): 1617-1626.
[10] SUN CanRan, ZHANG XueHai, MA ZhiHui, GUO ZhanYong, TANG JiHua, FU ZhiYuan. Fine Mapping of Grain Test Weight Gene tw1 in Maize [J]. Scientia Agricultura Sinica, 2018, 51(7): 1233-1243.
[11] ZHAO QianRu, ZHONG XingHua, ZHANG Fei, FANG WeiMin, CHEN FaDi, TENG NianJun. Heterosis and Mixed Genetic Analysis of Green-Center Trait of Spray Cut Chrysanthemum [J]. Scientia Agricultura Sinica, 2018, 51(5): 964-976.
[12] WANG BeiFang, CHEN YuYu, ZHANG YingXin, LIU QunEn, SUN Bin, XIANG XiaoJiao, CAO YongRun, CHENG ShiHua, CAO LiYong. Identification and Fine Mapping of an Early Senescent Leaf Mutant es5 in Oryza sativa L. [J]. Scientia Agricultura Sinica, 2018, 51(4): 613-625.
[13] YU YanFang, LIU Xi, TIAN YunLu, LIU ShiJia, CHEN LiangMing, ZHU JianPing, WANG YunLong, JIANG Ling, ZHANG WenWei, WANG YiHua, WAN JianMin. Phenotypic Analysis and Gene Mapping of a Floury and Shrunken Endosperm Mutant fse3 in Rice [J]. Scientia Agricultura Sinica, 2018, 51(11): 2023-2037.
[14] ZHANG XiaoBo, XIE Jia, ZHANG XiaoQiong, TIAN WeiJiang, HE PeiLong, LIU SiCen, HE GuangHua, ZHONG BingQiang, SANG XianChun. Identification and Gene Mapping of a Dwarf and Curled Flag Leaf Mutant dcfl1 in Rice (Oryza sativa L.) [J]. Scientia Agricultura Sinica, 2017, 50(9): 1551-1558.
[15] XIE HaiKun, JIAO Jian, FAN XiuCai, ZHANG Ying, JIANG JianFu, SUN HaiSheng, LIU ChongHuai. Assembling and Characteristic Analysis of the Complete Chloroplast Genome of Vitis vinifera cv. Cabernet Sauvignon from High-Throughput Sequencing Data [J]. Scientia Agricultura Sinica, 2017, 50(9): 1655-1665.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备09089781号-30
Copyright 2018 © Editorial office of Scientia Agricultura Sinica
Tel: 86-010-82106279    E-mail: zgnykx@mail.caas.net.cn
Supported by Beijing Magtech Co.Ltd