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Acta Agronomica Sinica ›› 2018, Vol. 44 ›› Issue (9): 1301-1310.doi: 10.3724/SP.J.1006.2018.01301

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Phenotypic Analysis and Gene Mapping of the Rice Narrow-leaf Mutant nal20

Hai-Xin LONG(),Hai-Yang QIU,UZAIR Muhammad,Jing-Jing FANG,Jin-Feng ZHAO,Xue-Yong LI()   

  1. National Key Facility for Crop Gene Resource and Genetic Improvement, Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing 100081, China
  • Received:2018-02-07 Accepted:2018-06-12 Online:2018-09-10 Published:2018-07-02
  • Contact: Xue-Yong LI E-mail:lhxbling@126.com;lixueyong@caas.cn
  • Supported by:
    This study was supported by the National Major Project for Developing New GM Crops (2016ZX08009-003)

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Abstract:

Leaf is the major organ for photosynthesis in plant, and its area influences the light energy utilization efficiency and grain yield. To study the molecular mechanism of rice leaf morphology, we mutagenized the japonica cultivar Chunjiang 06 through 60Co-γ radiation. A stable narrow leaf mutant named as narrow leaf20 (nal20) was obtained in the M2 population. The nal20 mutant showed narrow leaf, reduced plant height, increased tiller number, shortened internodes, and earlier heading date. Here we mainly focused on the morphology of the flag leaf, the second top leaf and the third top leaf. We found that the blade width of the mutant reduced by 50%, compared with the wild type. Meanwhile, the variation on the blade length was relatively small. Cytological observation of leaf epidermal cells indicated that the reduced leaf width was mainly due to the decreased cell number, but not the cell size. Genetic analysis indicated that the narrow leaf phenotype was controlled by a recessive gene. Using the mutant plants from the F2 mapping population derived from a cross between nal20 and Dular, the candidate mutation locus was mapped to 1.9 Mb within the centromere of chromosome 7 by using polymorphic InDel markers. The next-generation sequencing result showed that a deletion of 455 kb occurred in the predicted region. Our study lays a good foundation for the cloning and functional study of the NAL20 gene and provides gene resources and breeding materials for the improvement of rice plant architecture.

Key words: rice, leaf, narrow-leaf mutant, heading date, gene mapping

Fig. 1

Leaf width of wild type (WT) and the nal20 mutantA: flag leaf size of wild type and the nal20 mutant at heading stage (bar = 10 mm); B: leaf width comparison of flag, top second, and top third leaves between WT and nal20. P-values were analyzed using Student’s t-tests. ** significantly different at P < 0.01 (n = 20)."

Fig. 2

Leaf length of wild type (WT) and the nal20 mutantA: top leaf size of wild type and the nal20 mutant at heading stage (bar = 5 cm); B: length comparison of flag, second, and top third leaves between WT and nal20. P-values were analyzed using Student’s t-tests. * P < 0.05, ** P < 0.01 (n = 20)."

Table 1

Comparison of leaf width and heading date under different daylength conditions"

性状
Trait		 日照条件
Daylength condition		 野生型春江06
Wild-type Chunjiang 06		 nal20
Mutant nal20
剑叶宽度 长日照(北京昌平) Long-day (Changping, Beijing) 15.10±0.67 8.60±0.49**
Flag leaf width (mm) 短日照(海南三亚) Short-day (Sanya, Hainan) 15.62±0.85 8.27±0.46**
抽穗天数 长日照(北京昌平) Long-day (Changping, Beijing) 131.65±2.04 94.92±1.57**
Heading date (d) 短日照(海南三亚) Short-day (Sanya, Hainan) 89.96±1.82 92.31±1.79

Fig. 3

Leaf vein number of wild type (WT) and the nal20 mutantA, C, E: leaf vein shape of the flag leaf, top second leaf and top third leaf in the wild type (bars = 1 mm); B, D, F: leaf vein of the flag leaf, top second leaf and top third leaf in the mutant (bars = 1 mm); G: comparison of large vein number in the wild type and mutant; H: comparison of small vein number in the wild type and mutant. P-values were analyzed using Student’s t-tests. ** P < 0.01 (n = 20)."

Fig. 4

Epidermal cell width and cell number of wild type (WT) and the nal20 mutant A, B: Epidermal cell shape of flag leaf in the wild-type (A) and mutant (B) (bars = 50 μm); C, D: comparison of epidermal cell width and cell number along leaf-width axis. P-values were analyzed from Student’s t-tests. ** P < 0.01 (n = 20)."

Fig. 5

Gross morphology of wild type (WT) and the nal20 mutantA: plant type of wild type and the nal20 mutant at heading stage (bar = 5 cm). Comparison of plant height (B) and tiller number (C) between WT and nal20. P-values were analyzed using Student’s tests. ** P < 0.01 (n = 20)."

Fig. 6

Panicle morphology and internode length of wild type (WT) and the nal20 mutantA: panicle shape of wild type and the nal20 mutant at heading stage; B: comparison of grain number per panicle. The P-values were analyzed from student’s t-tests. ** P < 0.01 (n = 20); C: internodes of wild type and the nal20 mutant at heading stage; D: comparison of internode length (from the top to bottom is panicle, panicle internode, the first internode, the second internode, the third internode, the fourth internode, the fifth internode, and the sixth internode)."

Table 2

InDel markers"

分子标记
Marker		 正向引物序列
Forward primer sequence (5°-3°)		 反向引物序列
Reverse primer sequence (5°-3°)
R7-3 GGCAAGTTAAAACCGAGCAG CCATGGAAGGCTGTAACCAT
R7-4 GATAGCTTGACAACGGTGGCAC CCATACATTGTTGCACTTGTGAC
R7-6 CCCCATGAGGCCTACACTT AGCAGCATAATCAGATGAGACG
R7-7 ATCGGTGCCGCTCCTAGAT CACTCCACAGACATGCAATTT
R7-8 TTCCAGGCTGCATCTTATTC GCAGGACCCATGCTGAAAAG
C7-1 ATCTAGCGGCTAGCACACTGG ATCACCTCATGTCTCCGGACG
C7-2 ACTGTGTGCTGCCTGACATAC AGACGAATGGTCAAACATGTG
C7-3 GATGGTAGGAGGCCGGACTGG GCCTCCTTTACTACCGACCGC
C7-4 GTGGTGACAATGTGGTACAAT CCACTTATACGTGCGTAACAC
C7-5 CGCCGTTCGCATAAAGTCCTG TTGGACTTGTTTGGGCATACG
C7-6 AAGGACTTGCCGTTTGATCTC CATGATCGGTACTAGCAATTC

Fig. 7

Gene mapping of the nal20 mutantA: primary mapping result; B: fining mapping result; C: target gene region. The dashed line represents the 455 kb deletion. In panels A and B, the InDel markers and number of recombinants are marked above and below the horizontal line, respectively."

Table 3

Genes annotated in the 455 kb deletion region"

基因
Gene		 功能注释
Function annotation
LOC_Os07g15640 CRR4, putative, expressed
LOC_Os07g15650 Expressed protein
LOC_Os07g15670 Peroxiredoxin, putative, expressed
LOC_Os07g15680 Phospholipase D, putative, expressed
LOC_Os07g15720 Hypothetical protein
LOC_Os07g15770 CCT motif family protein, expressed
LOC_Os07g15820 Expressed protein
LOC_Os07g15860 Expressed protein
LOC_Os07g15870 Expressed protein
LOC_Os07g15880 Mitochondrial prohibitin complex protein 2, putative, expressed
LOC_Os07g15910 Expressed protein
LOC_Os07g15920 Expressed protein
LOC_Os07g15930 Legume lectins beta domain containing protein, expressed
LOC_Os07g15940 Legume lectins beta domain containing protein, expressed
LOC_Os07g15950 Expressed protein
LOC_Os07g15959 Expressed protein
LOC_Os07g15970 Erythronate-4-phosphate dehydrogenase domain containing protein, expressed
LOC_Os07g15980 Expressed protein
LOC_Os07g16030 Expressed protein
LOC_Os07g16040 Erythronate-4-phosphate dehydrogenase domain containing protein, expressed
LOC_Os07g16054 Hypothetical protein
LOC_Os07g16130 Acetyltransferase, GNAT family, putative, expressed
LOC_Os07g16140 FAD binding protein, putative, expressed
LOC_Os07g16150 Expressed protein
LOC_Os07g16180 Hypothetical protein
LOC_Os07g16210 Expressed protein
LOC_Os07g16224 Piwi domain containing protein, putative, expressed
LOC_Os07g16260 Expressed protein
LOC_Os07g16270 Hypothetical protein
[1] 朱雄涛, 汪真 . 水稻高光效生理育种初探. 福建稻麦科技, 2003,21(2):14-17
Zhu X T, Wang Z . Research on high photosynthetic efficiency in the physiological breeding. Fujian Sci & Technol Rice & Wheat, 2003,21(2):14-17 (in Chinese)
[2] Bowman J L, Eshed Y, Baum S F . Establishment of polarity in angiosperm lateral organs. Trends Genet, 2002,18:134-141
doi: 10.1016/S0168-9525(01)02601-4 pmid: 11858837
[3] Schraer H, Hunter S J . The development of plant leaves. Plant Physiol, 2003,131:389
doi: 10.1104/pp.015347 pmid: 12586863
[4] Murray M G, Thompson W F . Rapid isolation of high molecular weight plant DNA. Nucl Acids Res, 1980,8:4321-4325
doi: 10.1093/nar/8.19.4321 pmid: 324241
[5] David-Schwartz R, Koenig D, Sinha N R . LYRATE is a key regulator of leaflet initiation and lamina outgrowth in tomato. Plant Cell, 2009,21:3093-3104
doi: 10.1105/tpc.109.069948 pmid: 2782284
[6] 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 . Research progress of narrow leaf characters of rice. China Rice, 2010,16(3):1-4 (in Chinese)
[7] Iri A, Perera I, Ujiie K, Ishimaru K, Hirotsu N, Kashiwagi T . Partial loss-of-function of NAL1 alters canopy photosynthesis by changing the contribution of upper and lower canopy leaves in rice. Sci Rep, 2017,7(1):15958
[8] Qi J, Qian Q, Bu Q, Li S, Chen Q, Sun J, Liang W, Zhou Y, Chu C . Mutation of the rice narrow leaf1 gene, which encodes a novel protein, affects vein patterning and polar auxin transport. Plant Physiol, 2008,147:1947
[9] Woo Y M, Park H J , Su’Udi M, Yang J I, Park J J, Back K. 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 Mol Biol, 2007,65:125-136
[10] 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. Mol Genet Genomics, 2008,279:499-507
[11] Sakamoto T, Morinaka Y, Inukai Y, Kitano H, Fujioka S . Auxin signal transcription factor regulates expression of the brassinosteroid receptor gene in rice. Plant J, 2013,73:676-688
[12] Li M, Xiong G, Li R, Cui J, Tang D, Zhang B, Ding T, Zhang B C, Pauly M, Cheng Z K, Zhou Y H . Rice cellulose synthase-like D4 is essential for normal cell-wall biosynthesis and plant growth. Plant J, 2009,60:1055-1069
doi: 10.4161/psb.5.2.10369 pmid: 19765235
[13] Wu C, Fu Y, Hu G, Si H, Cheng S, Liu W . Isolation and characterization of a rice mutant with narrow and rolled leaves. Planta, 2010,232:313-324
doi: 10.1007/s00425-010-1180-3 pmid: 20443024
[14] Hu J, Zhu L, Zeng D, Gao Z, Guo L, Fang Y, Zhang G, Dong G, Yan M, Liu J . Identification and characterization of NARROW AND ROLLED LEAF 1, a novel gene regulating leaf morphology and plant architecture in rice. Plant Mol Biol, 2010,73:283-292
[15] Cho S H, Yoo S C, Zhang H, Pandeya D, Koh H J, Hwang J Y, Kim G T, Paek N C . The rice narrow leaf2 and narrow leaf3 loci encode WUSCHEL-related homeobox 3A (OsWOX3A) and function in leaf, spikelet, tiller and lateral root development. New Phytol, 2013,198:1071-1084
[16] Lin H, Niu L, Mchale N A, Ohme-Takagi M, Mysore K S, Tadege M . Evolutionarily conserved repressive activity of WOX proteins mediates leaf blade outgrowth and floral organ development in plants. Proc Natl Acad Sci USA, 2013,110:366-371
[17] Ishiwata A, Ozawa M, Nagasaki H, Kato M, Noda Y, Yamaguchi T, Nosaka M, Shimizu-Sato S, Nagasaki A, Maekawa M . Two WUSCHEL-related homeobox genes, narrow leaf2 and narrow leaf3, control leaf width in rice. Plant Cell Physiol, 2013,54:779-792
doi: 10.1093/pcp/pct032 pmid: 23420902
[18] Zheng M, Wang Y, Liu X, Sun J, Wang Y, Xu Y, Xu J L, Long W, Zhu X, Guo X . The RICE MINUTE-LIKE1 (RML1) gene, encoding a ribosomal large subunit protein L3B, regulates leaf morphology and plant architecture in rice. J Exp Bot, 2016,67:3457-3469
[19] Yang W, Guo Z, Huang C, Wang K, Jiang N, Feng H, Chen G, Liu Q, Xiong L . Genome-wide association study of rice (Oryza sativa L.) leaf traits with a high-throughput leaf scorer. J Exp Bot, 2015,66:5605-5615
[20] Yoshikawa T, Eiguchi M, Hibara K I, Ito J I, Nagato Y . Rice SLENDER LEAF 1 gene encodes cellulose synthase-like D4 and is specifically expressed in M-phase cells to regulate cell proliferation. J Exp Bot, 2013,64:2049
[21] Jiang D, Fang J, Lou L, Zhao J, Yuan S, Yin L, Sun W, Peng L, Guo B, Li X . Characterization of a null allelic mutant of the rice NAL1 gene reveals its role in regulating cell division. PLoS One, 2015,10:e0118169
[22] Michelmore R W, Paran I, Kesseli R V . Identification of markers linked to disease-resistance genes by bulked segregant analysis: A rapid method to detect markers in specific genomic regions by using segregating populations. Proc Natl Acad Sci USA, 1991,88:9828
[23] Xue W, Xing Y, Weng X, Zhao Y, Tang W, Wang L, Zhou H, Yu S, Xu C, Li X . Natural variation in Ghd7 is an important regulator of heading date and yield potential in rice. Nat Genet, 2009,40:761-767
doi: 10.1038/ng.143 pmid: 18454147
[24] 谈聪, 翁小煜, 鄢文豪, 白旭峰, 邢永忠 . 多效性基因Ghd7调控水稻剑叶面积. 遗传, 2012,34:901-906
Tan C, Weng X Y, Yan W H, Bai X F, Xing Y Z . Ghd7, a pleiotropic gene controlling flag leaf erea in rice. Hereditas(Beijing), 2012,34:901-906 (in Chinese with English abstract)
[25] Li L, Yan W, Xue W, Shao D, Xing Y . Evolution and association analysis of Ghd7 in rice. PLoS One, 2012,7:e34021
[26] Doi K, Izawa T, Fuse T, Yamanouchi U, Kubo T, Shimatani Z, Yano M, Yoshimura A . Ehd1, a B-type response regulator in rice, confers short-day promotion of flowering and controls FT-like gene expression independently of Hd1 . Genes Dev, 2004,18:926-936
[27] Hayama R, Yokoi S, Tamaki S, Yano M, Shimamoto K . Adaptation of photoperiodic control pathways produces short-day flowering in rice. Nature, 2003,422:719-722
doi: 10.1038/nature01549 pmid: 12700762
[28] 肖珂, 左海龙, 巩迎军, 张俊芝, 张永娟, 董彦君 . 控制水稻剑叶形态相关性状的数量基因位点(QTL)的定位. 上海师范大学学报(自然科学版), 2007,36(2):66-70
Xiao K, Zuo H L, Gong Y J, Zhang J Z, Zhang Y J, Dong Y J . Locating quantitative trait loci affecting flag-leaf shape traits in rice (Oryza sativa L.).J Shanghai Norm Univ(Nat Sci), 2007,36(2):66-70 (in Chinese with English abstract)
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