不同发育时期花生胚混合全长cDNA文库的构建与分析

doi:10.3864/j.issn.0578-1752.2014.11.021

Abstract

Abstract: 【Objective】 The objective of this study is to understand the molecular mechanism of peanut embryo development and obtain important genes related to peanut embryo development. 【Method】 Using peanut variety Minhua 6 as the experimental material, embryos on 10, 20, 30, 40, 50, and 60th day after pegging were sampled. Total RNA was extracted by improved CTAB method. Double strand cDNA was synthesized based on SMART technique. The purified dscDNA was ligated to pDNR-LIB vector digested by SfiⅠ and transformed into DH5α by electroporation to construct a full-length cDNA library of peanut embryos at different developmental stages. Bioinformatics analysis was performed following small-scale EST sequencing.【Result】A successful full-length cDNA library of peanut embryos at different development stages was constructed. The titer of unamplified cDNA library was about 3.5×106cfu/mL. The average cDNA inserts were more than 1 000 bp with a recombination frequency of 95.8%. Small-scale plasmid extraction and subsequent sequencing resulted in 60 ESTs, which were used for further analysis. BLASTX analysis showed that 39 sequences (65% of total sequences) had high similarity with reported genes in Glycine max, Arachis hypogaea, Medicago truncatula, etc. on NCBI with 32 sequences having known or putative functions and functions of other 7 sequences were unclear. The other 21 (35% of total sequences) could not find similarity with known genes in NCBI, which may be novel genes for peanut. GO annotation was performed with BLAST2GO software and the results revealed that the ESTs generated in this study mainly included responsive to stresses and defenses, protein synthesis and transport, lipid synthesis and metabolism, transcription and regulation, seed germination, dormancy and embryo development related genes. Besides, some genes were involved in signal transduction and light morphogenesis process. KEGG pathway analysis showed that the ESTs generated by randomly sequencing in this study mainly involved in alpha-linolenic acid metabolism and linoleic acid metabolism.【Conclusion】A high-quality full-length cDNA library of peanut embryos was constructed successfully using SMART method and some genes related to peanut embryo development were got, such as linoleate 9S-lipoxygenase-4-like, oleosin, zinc finger protein, heat shock protein 90, late embryogenesis abundant protein group 2, lipoxygenase-10, and putative DREB transcription factor, etc.

Key words: Arachis hypogaea L. , embryo , cDNA library , SMART , EST

CHEN Hua-1, 2 , DENG Ye-1, 2 , ZHANG Chong-1, CAI Tie-Cheng-1, 2 , ZHENG Yi-Xiong-1, 2 , 3 , ZHUANG Wei-Jian-1, 2 . Construction and Analysis of a Full-Length cDNA Library of Peanut Embryos at Different Developmental Stages[J].Scientia Agricultura Sinica, 2014, 47(11): 2272-2280.

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References

[1]Zhou Y, Zhang X, Kang X, Zhao X, Zhang X, Ni M. SHORT HYPOCOTYL UNDER BLUE1 associates with MINISEED3 and HAIKU2 promoters in vivo to regulate Arabidopsis seed development. The Plant Cell, 2009, 21: 106-117.

[2]Kang X J, Li W, Zhou Y, Ni M. A WRKY transcription factor recruits the SYG1-Like potein SHB1 to activate gene expression and seed cavity enlargement. PLOS Genetics, 2013, 9(3): 1-16.

[3]Wang A, Garcia D, Zhang H, Feng K, Chaudhury A, Berger F, Peacock W J, Dennis E S, Luo M. The VQ motif protein IKU1 regulates endosperm growth and seed size in Arabidopsis. The Plant Journal, 2010, 63: 670-679.

[4]Luo M, Dennis E S, Berger F, Peacock W J, Chaudhury A. MINISEED3 (MINI3), a WRKY family gene, and HAIKU2 (IKU2), a leucinerich repeat (LRR) KINASE gene, are regulators of seed size in Arabidopsis. Proceedings of the National Academy of Science of the USA, 2005, 102: 17531-17536.

[5]Anastasiou R, Kena S, Gerstung M, Maclean D, Timmer J, Fleck C, Lenhard M. Control of plant organ size by KLUH/CYP78A5- dependent intercellular signaling. Developmental Cell, 2007, 13: 843-856.

[6]Fang W, Wang X Z, Cui R, Li J, Li Y. Maternal control of seed size by EOD3/CYP78A6 in Arabidopsis thaliana. The Plant Journal, 2012, 70: 929-939.

[7]Yang W B, Gao M J, Yin X, Liu J Y, Xu Y H, Zeng L J, Li Q, Zhang S B, Wang J M, Zhang X M, He Z H. Control of rice embryo development, shoot apital meristem maintenance and grain yield by a novel cytochrome P450. Molecular Plant, 2013, 6(6): 1945-1960.

[8]Kenneth A F. Cytochrome P450s as genes for crop improvement. Current Opinion in Plant Biology, 2001, 4:162-167.

[9]Sotelo-Silveira M, Cucinotta M, Chauvin A L, Montes R C, Colombo L, Marsch-Martínez N, Folter S. Cytochrome P450 CYP78A9 is involved in Arabidopsis Reproductive Development. Plant Physiology, 2013, 162: 779-799.

[10]Holger B, Enno R, Marita H, Minako U, Thomas L. Differential expression of WOX genes mediates apical-Basal axis formation in the Arabidopsis embryo. Developmental Cell, 2008, 14: 867-876.

[11]Mao H L, Sun S Y, Yao J L, Wang C R, Yu S B, Xu C G, Li X H, Zhang Q F. Linking differential domain functions of the GS3 protein to natural variation of grain size in rice. Proceedings of the National Academy of Science of the USA, 2010, 107(45): 19579-19584.

[12]Nayar S, Sharma R, Tyagi A K, Kapoor S. Functional delineation of rice MADS29 reveals its role in embryo and endosperm development by affecting hormone homeostasis. Journal of Experimental Botany, 2013, 64(14): 4239-4253.

[13]Sankaranarayanan S, Deb S, Widdup E, Bournonville C, Bollier N, Northey J B, McCourt P, Samuel M. ABI3 controls embryo degreening through Mendel’s I locus. Proceedings of the National Academy of Science of the USA, 2013, 110(40): 3888-3894.

[14]Jiang W B, Huang H Y, Hu Y W, Zhu S W, Wang Z Y, Lin W H. Brassinosteroid regulates seed size and shape in Arabidopsis. Plant Physiology, 2013, 162: 1965-1977.

[15]Luo M, Dennis E S, Berger F, Peacock W J, Chaudhury A. MINISEED3 (MINI3), a WRKY family gene, and HAIKU2 (IKU2), a leucinerich repeat (LRR) KINASE gene, are regulators of seed size in Arabidopsis. Proceedings of the National Academy of Science of the USA, 2005, 102: 17531-17536.

[16]Jofuku K D, Omidyar P K, Gee Z, Okamuro J K .Control of seed mass and seed yield by the floral homeotic gene APETALA2. Proceedings of the National Academy of Science of the USA, 2005,102: 3117–3122.

[17]Ohto M A, Fischer R L, Goldberg R B, Nakamura K, Harada J J. Control of seed mass by APETALA2. Proceedings of the National Academy of Science of the USA ,2005,102: 3123-3128.

[18]Ohto M A, Floyd S K, Fischer R L, Goldberg R B, Harada J J. Effects of APETALA2 on embryo, endosperm, and seed coat development determine seed size in Arabidopsis. Sexual Plant Reproduction, 2009, 22: 277-289.

[19]Schruff M C, Spielman M, Tiwari S, Adams S, Fenby N, Scott R J. The AUXIN RESPONSE FACTOR 2 gene of Arabidopsis links auxin signalling, cell division, and the size of seeds and other organs. Development, 2006,133: 251-261.

[20]Sun X, Shantharaj D, Kang X, Ni M .Transcriptional and hormonal signaling control of Arabidopsis seed development. Current Opinion in Plant Biology, 2010,13: 611-620.

[21]Chen X P, Zhu W, Azam S, Li H Y, Zhu F H, Li H F. Deep sequencing analysis of the transcriptomes of peanut aerial and subterranean young pods identifies candidate genes related to early embryo abortion. Plant Biotechnology Journal, 2013, 11:115-127.

[22]Zhu W, Zhang E H, Li H F, Chen X P, Zhu F H, Hong Y B, Liao B S, Liu S Y, Liang X Q. Comparative proteomics analysis of developing peanut aerial and subterranean pods identifies pod swelling related proteins. Journal of Proteomics, 2013, 91: 172-187.

[23]Payton P, Kottapalli K R, Rowland D, Faircloth W, Guo B Z, Burow M. Gene expression profiling in peanut using high density oligonucleotide microarrays. BMC Genomics, 2009, 10: 265-276.

[24]陈华, 姜宝杰, 邓烨, 曾建斌, 张冲, 庄伟建. 高质量花生花序全长cDNA文库的构建和鉴定. 豆科基因组学与遗传学, 2011, 2: 14-19.

Chen H, Jiang B J, Deng Y, Zeng J B, Zhang C, Zhuang W J. Construction and evaluation of a high-quality peanut inflorescence full-length cDNA library. Legume Genomics and Genetics, 2011, 2: 14-19. (in Chinese)

[25]陈华, 姜宝杰, 张冲, 曾建斌, 邓烨, 庄伟建. 利用改进的SMART法构建花生种皮全长cDNA文库. 福建农业学报, 2012, 27(11): 1151-1155.

Chen H, Jiang B J, Zhang C, Zeng J B, Deng Y, Zhuang W J. Establishment of full-length peanut testa cDNA library by using modified SMART. Fujian Journal of Agricultural Sciences, 2012, 27(11): 1151-1155. (in Chinese)

[26]陈华, 姜宝杰, 张冲, 蔡铁城, 曾建斌, 邓烨, 庄伟建. 花生果皮全长cDNA文库的构建及初步分析. 福建农林大学学报: 自然科学版, 2013, 42(1): 57-62.

Chen H, Jiang B J, Zhang C, Cai T C, Zeng J B, Deng Y, Zhuang W J. Construction and primary analysis of peanut pericarp full-length cDNA library. Journal of Fujian Agriculture and Forestry University : Natural Science Edition,2013, 42(1): 57-62. (in Chinese)

[27]姜宝杰, 陈华, 邓烨, 曾建斌, 张冲, 贺小彦, 庄伟建. 利用SMART法构建花生果针全长cDNA文库. 基因组学与应用生物学, 2011, 30: 1155-1161.

Jiang B J, Chen H, Deng Y, Zeng J B, Zhang C, He X Y, Zhuang W J. Construction of peanut gynophore full-length cDNA library with SMART method. Genomics and Applied Biology, 2011, 30: 1155-1161. (in Chinese)

[28]姜宝杰, 陈华, 张冲, 邓烨, 蔡铁城, 石新国, 庄伟建. 环境胁迫诱导的花生全长cDNA文库的构建及序列分析. 核农学报, 2013, 27(5): 545-551.

Jiang B J, Chen H, Zhang C, Deng Y, Cai T C, Shi X G, Zhuang W J. Construction of full-length cDNA library of peanut tissues treated with different stresses with SMART method. Journal of Nuclear Agricultural Sciences, 2013, 27(5): 545-551. (in Chinese)

[29]蔡宁波, 黄湘文, 庄伟建. 花生种子全长cDNA文库的构建和鉴定. 花生学报, 2007, 36(2): 1-5.

Cai N B, Huang X W, Zhuang W J. Construction and identification of a full-length cDNA library from peanut. Journal of Peanut Science, 2007, 36(2): 1-5. (in Chinese)

[30]禹山林, 迟晓元, 杨庆利, 潘丽娟, 和亚男, 陈明娜, 杨珍. 花生幼苗全长cDNA文库的构建. 花生学报, 2010, 39(2): 11-15.

Yu S L, Chi X Y, Yang Q L, Pan L J, He Y N, Chen M N, Yang Z. Construction of a full-length cDNA library from peanut seedlings. Journal of Peanut Science, 2010, 39(2): 11-15. (in Chinese)

[31]Conesa A, Gotz S, Garcia-Gomez J M, Terol J, Talon M, Robles M. Blast2GO: A universal tool for annotation, visualization and analysis in functional genomic sresearch. Bioinformatics, 2005, 21(18): 3674-3676.

[32]方花, 魏小勇. 铁皮石斛cDNA文库的构建及分析. 生命科学研究, 2005, 9(3): 263-266.

Fang H, Wei X Y. Construction and analysis of a cDNA expression library of Dendrobium candidum. Life Science Research, 2005, 9(3): 263-266. (in Chinese)

[33]高小丽, 李芳, 岳鹏, 李天红. 欧李叶片全长cDNA文库的构建和部分克隆的序列分析. 农业生物技术学报, 2010, 18(1): 156-162.

Gao X L, Li F, Yue P, Li T H. Construction and sequence analysis of partial clones of a full-length cDNA library of Chinese Dwarf Cherry leaves. Journal of Agricultural Biotechnology, 2010, 18(1): 156-162. (in Chinese)

[34]Phukon M, Namdev R, Deka D, Modi M K, Sen P. Construction of cDNA library and preliminary analysis of expressed sequence tags from tea plant [Camellia sinensis (L.) O. Kuntze]. Gene, 2012, 506: 202-206.

[35]Zhang J, Liu N, Niu R, Liu Y, Zhai H, Xu W, Wang Y. Construction of a cDNA library of the Chinese wild Vitis amurensis under cold stress and analysis of potential hardiness-related expressed sequence tags. Genetics and Molecular Research, 2013, 12(2): 1182-1193.

[36]Zhang D L, Hu C G, Ouyang Y D, Yao J L. Construction of a full-length cDNA library and analysis of expressed sequence tags from inflorescence of apomictic Sabaigrass (Eulaliopsis binata). Plant Molecular Biology Report, 2012, 30: 46-54.

[37]罗帮明. 花生种子全长cDNA文库的大规模测序和生物信息学分析[D]. 福州: 福建农林大学, 2005.

Luo B M. A large-scale sequencing and bioinformatics analysis toward a full-length cDNA library of peanut seeds[D]. Fuzhou: Fujian Agriculture and Forestry University, 2005. (in Chinese)

[38]苏磊. 花生种子全长cDNA文库序列分析及花生LEA基因家族的初步研究[D]. 济南: 山东师范大学, 2010.

Su L. Sequences analysis of peanut seeds full-length cDNA library and preliminary study of LEA family[D]. Ji’nan: Shandong Normal University, 2010. (in Chinese)

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Construction and Analysis of a Full-Length cDNA Library of Peanut Embryos at Different Developmental Stages

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