水稻斑马叶突变体zebra524的表型鉴定及候选基因分析

doi:10.3864/j.issn.0578-1752.2014.15.001

Abstract

Abstract: 【Objective】 The present study was aimed at morphological characterization and candidate gene analysis of zebra leaf mutant zebra524 in rice, so as to lay the foundation for further functional analysis of this gene and its application in agricultural production. 【Method】 A zebra leaf mutant, designated as zebra524, was isolated from an ethyl methanesulfonate (EMS)-mutagenized population. Morphological characteristics and the agronomic traits of the mutant and its wildtype were contrasted systematically. Using spectrophotometer, photosynthetic pigment contents in leaves of the mutant and its wildtype were measured at seedling and booting stages, and in glumes at grain-filling stage, respectively. After the zebra524 mutant was crossed with normal green varieties, the leaf colour phenotypes of the F1 progenies and the segregation ratio of zebra leaf plants to green leaf plants in the F2 populations were investigated. A total of 575 zebra leaf mutant individuals in the F2 mapping population generated from the cross between the mutant and G46B (Indica) were used for mapping using molecular markers. In addition, putative genes in the mapped region were analyzed, and candidate genes in the mutant and its wild-type were sequenced, respectively. Subsequently, DNA sequencing of β-OsLCY gene and alignment of the deduced amino acid sequences of homologous β-OsLCY proteins were conducted. 【Result】 During seedling and tillering stages, the zebra524 mutant showed alternating transverse pale green and albino sectors on leaves. During booting stage, its albino sectors turned into pale green and hereafter, the newly grown leaves became completely pale green. The zebra524 mutant also showed pale glumes during heading and grain-filling stages, and brown nodes, pink basal internodes, orange-red embryos and basal caryopsises at maturation stage. In addition, plumules of zebra524 showed an orange-red color in the dark. Chlorophyll contents in leaves of the zebra524 mutant decreased by 82.8% and 20.9%, and carotenoid contents decreased by 64.7% and 32.6% at seedling and booting stages, respectively, compared with those of the wild type. In addition, the levels of chlorophylls and carotenoids in glumes of zebra524 mutant were reduced by 38.1% and 42.8%, respectively, at the grain-filling stage. Its plant height, number of spikelets per panicle, seed setting rate and 1000-grain weight were reduced by 12.3%, 9.5%, 13.0% and 5.4%, respectively, at maturation. All F1 plants displayed wild-type phenotype, and the number of normal seedlings versus that of mutant seedlings in the F2 populations was fitted to 3:1, indicating that the zebra524 phenotype was controlled by a single recessive nuclear gene. The mutant gene was mapped to a region of 235 kb between SSR marker RM7082 and InDel marker Y2 on the short arm of chromosome 2. Sequencing analysis of candidate genes between the mutant and its wild-type revealed a single-nucleotide G-to-T mutation was found at position 235 in the coding region of the LOC_Os02g09750 gene for lycopene β-cyclase, which resulted in an amino acid change from Gly at position 79 to Cys in the encoded product. 【Conclusion】 The zebra524 mutant gene was allelic to β-OsLCY gene which was documented previously. The zebra524 mutant phenotype may be attributed to a point mutation of β-OsLCY gene encoding lycopene β-cyclase.

Key words: rice , zebra leaf mutant , genetic analysis , carotenoid , β-OsLCY gene

LI Yan-Qun, ZHONG Ping, GAO Zhi-Yan, ZHU Bai-Yang, CHEN Dan, SUN Chang-Hui, WANG Ping-Rong, DENG Xiao-Jian. Morphological Characterization and Candidate Gene Analysis of Zebra Leaf Mutant zebra524 in Rice[J].Scientia Agricultura Sinica, 2014, 47(15): 2907-2915.

References

[1]Cazzonelli C I, Pogson B J. Source to sink: Regulation of carotenoid biosynthesis in plants. Trends in Plant Science, 2010, 15(5): 266-274.

[2]Wilson A, Ajlani G, Verbavatz J M, Vass I, Kerfeld C A, Kirilovsky D. A soluble carotenoid protein involved in phycobilisome-related energy dissipation in cyanobacteria. The Plant Cell, 2006, 18(4): 992-1007.

[3]Bartley G E, Scolnik P A. Plant carotenoids: Pigments for photoprotection, visual attraction, and human health. The Plant Cell, 1995, 7(7): 1027-1038.

[4]Li F Q, Vallabhaneni R, Wurtzel E T. PSY3, a new member of the phytoene synthase gene family conserved in the poaceae and regulator of abiotic stress-induced root carotenogenesis. Plant Physiology, 2008, 146(3): 1333-1345.

[5]Isaacson T, Ronen G, Zamir D, Hirschberg J. Cloning of tangerine from tomato reveals a carotenoid isomerase essential for the production of β-carotene and xanthophylls in plants. The Plant Cell, 2002, 14(2): 333-342.

[6]Park H, Kreunen S S, Cuttriss A J, DellaPenna D, Pogson B J. Identification of the carotenoid isomerase provides insight into carotenoid biosynthesis, prolamellar body formation, and photomorphogenesis. The Plant Cell, 2002, 14(2): 321-332.

[7]Al-Babili S, Hugueney P, Schledz M, Welsch R, Frohnmeyer H, Laule O, Beyer P. Identification of a novel gene coding for neoxanthin synthase from Solanum tuberosum. FEBS Letters, 2000, 485: 168-172.

[8]Lü M Z, Chao D Y, Shan J X, Zhu M Z, Shi M, Gao J P, Lin H X. Rice carotenoid β-ring hydroxylase CYP97A4 is involved in lutein biosynthesis. Plant and Cell Physiology, 2012, 53(6): 987-1002.

[9]Agrawal G K, Yamazaki M, Kobayashi M, Hirochika R, Miyao A, Hirochika H. Screening of the rice viviparous mutants generated by endogenous retrotransposon Tos17 insertion. Tagging of a zeaxanthin epoxidase gene and a novel OsTATC gene. Plant Physiology, 2001, 125(3): 1248-1257.

[10]Fang J, Chai C L, Qian Q, Li C L, Tang J Y, Sun L, Huang Z J, Guo X L, Sun C H, Liu M, Zhang Y, Lu Q T, Wang Y Q, Lu C M, Han B, Chen F, Cheng Z K, Chu C C. Mutations of genes in synthesis of the carotenoid precursors of ABA lead to pre-harvest sprouting and photo-oxidation in rice. The Plant Journal, 2008, 54(2): 177-189.

[11]Du H, Wang N L, Cui F, Li X H, Xiao J H, Xiong L. Characterization of the β-carotene hydroxylase gene DSM2 conferring drought and oxidative stress resistance by increasing xanthophylls and abscisic acid synthesis in rice. Plant Physiology, 2010, 154(3): 1304-1318.

[12]Lichtenthaler H K. Chlorophylls and carotenoids: Pigments of photosynthetic biomembranes. Methods in Enzymology, 1987, 148: 350-382.

[13]McCouch S R, Kochert G, Yu Z H, Wang Z Y, Khush G S, Coffman W R, Tanksley S D. Molecular mapping of rice chromosomes. Theoretical and Applied Genetics, 1988, 76(6): 815-829.

[14]Panaud O, Chen X, McCouch S R. Development of microsatellite markers and characterization of simple sequence length polymorphism (SSLP) in rice (Oryza sativa L.). Molecular and General Genetics, 1996, 252(5): 597-607.

[15]Hirschberg J. Carotenoid biosynthesis in flowering plants. Current Opinion in Plant Biology, 2001, 4(3): 210-218.

[16]Rodríguez-Villalón A, Gas E, Rodríguez-Concepción M. Phytoene synthase activity controls the biosynthesis of carotenoids and the supply of their metabolic precursors in dark-grown Arabidopsis seedlings. The Plant Journal, 2009, 60(3): 424-435.

[17]Bramley P M. Regulation of carotenoid formation during tomato fruit ripening and development. Journal of Experimental Botany, 2002, 53(377): 2107-2113.

[18]Li F Q, Vallabhaneni R, Yu J, Rochefoerd T, Wurtzel E T. The maize phytoene synthase gene family: Overlapping roles for carotenogenesis in endosperm, photomorphogenesis, and thermal stress tolerance. Plant Physiology, 2008, 147(3): 1334-1346.

[19]Welsch R, Beyer P, Hugueney P, Kleinig H, von Lintig J. Regulation and activation of phytoene synthase, a key enzyme in carotenoid biosynthesis, during photomorphogenesis. Planta, 2000, 211(6): 846-854.

[20]Nambara E, Marion-Poll A. Abscisic acid biosynthesis and catabolism. Annual Review of Plant Biology, 2005, 56: 165-185.

[21]Gomez-Roldan V, Fermas S, Brewer P B, Puech-Pagès V, Dun E A, Pillot J P, Letisse F, Matusova R, Danoun S, Portais J C, Bouwmeester H, Bécard G, Beveridge C A, Rameau C, Rochange S F. Strigolactone inhibition of shoot branching. Nature, 2008, 455: 189-194.

[22]Olson J A. Provitamin A function of carotenoids: The conversion of beta-carotene into vitamin A. The Journal of Nutrition, 1989, 119(1): 105-108.

[23]Lange B M, Ghassemian M. Genome organization in Arabidopsis thaliana: a survey for genes involved in isoprenoid and chlorophyll metabolism. Plant Molecular Biology, 2003, 51(6): 925-948.

[24]Singh M, Lewis P E, Hardeman K, Bai L, Rose J K C, Mazourek M, Chomet P, Brutnell T P. Activator mutagenesis of the pink scutellum1/viviparous7 locus of maize. The Plant Cell, 2003, 15(4): 874-884.

[25]Du H, Wu N, Chang Y, Li X H, Xiao J H, Xiong L Z. Carotenoid deficiency impairs ABA and IAA biosynthesis and differentially affects drought and cold tolerance in rice. Plant Molecular Biology, 2013, 83: 475-488.

[26]Sauter A, Davies W J, Hartung W. The long-distance abscisci acid signal in the droughted plant: The fate of the hormane on its way from root to shoot. Journal of Experimental Botany, 2001, 52(363): 1991-1997.

[27]Jiang F, Hartung W. Long-distance signalling of abscisic acid (ABA): The factors regulating the intensity of the ABA signal. Journal of Experimental Botany, 2008, 59(1): 37-43.

[28]谢刚. 水稻斑马叶基因遗传定位与表达条件分析[D].长沙: 湖南师范大学, 2011: 26-29.

Xie G. Genetic mapping and the expression conditions of the zebra-leaf gene in riee (Oryza sativa L.) [D]. Changsha: Hunan Normal University, 2011: 26-29. (in Chinese)

[29]Aluru M R, Bae H, Wu D Y, Rodermel S R. The Arabidopsis immutans mutation affects plastid differentiation and the morphogenesis of white and green sectors in variegated plants. Plant Physiology, 2001, 127(1): 67-77.

[30]Aluru M R, Zola J, Foudree A, Rodermel S R. Chloroplast photooxidation-induced transcriptome reprogramming in Arabidopsis immutans white leaf sectors. Plant Physiology, 2009, 150(2): 904-923.

[31]Li J J, Pandeya D, Nath K, Zulfugarov I S, Yoo S C, Zhang H T, Yoo J H, Cho S H, Koh H J, Kim D S, Seo H S, Kang B C, Lee C H, Paek N C. ZEBRA-NECROSIS, a thylakoid-bound protein, is critical for the photoprotection of developing chloroplasts during early leaf development. The Plant Journal, 2010, 62(4): 713-725.

[32]Xing S F, Miao J, Li S, Qin G J, Tang S, Li H N, Gu H Y, Qu L J. Disruption of the 1-deoxy-D-xylulose-5-phosphate reductoisomerase (DXR) gene results in albino, dwarf and defects in trichome initiation and stomata closure in Arabidopsis. Cell Research, 2010, 20: 688-700.

[33]Chai C L, Fang J, Liu Y, Tong H N, Gong Y Q, Wang Y Q, Liu M, Wang Y P, Qian Q, Cheng Z K, Chun C C. ZEBRA2, encoding a carotenoid isomerase, is involved in photoprotection in rice. Plant Molecular Biology, 2011, 75(3): 211-221.

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Morphological Characterization and Candidate Gene Analysis of Zebra Leaf Mutant zebra524 in Rice

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