欢迎访问作物学报,今天是
作物学报

作物学报 ›› 2017, Vol. 43 ›› Issue (01): 31-41.doi: 10.3724/SP.J.1006.2017.00031

• 作物遗传育种·种质资源·分子遗传学 • 上一篇    下一篇

甘蔗独脚金内酯生物合成关键基因ScD27的克隆与表达分析

吴转娣**,刘新龙,刘家勇,昝逢刚,李旭娟,刘洪博,林秀琴,陈学宽,苏火生,赵培方,吴才文*   

  1. 云南省农业科学院甘蔗研究所 / 云南省甘蔗遗传改良重点实验室,云南开远661699
  • 收稿日期:2016-01-11 修回日期:2016-09-18 出版日期:2017-01-12 网络出版日期:2016-09-28
  • 通讯作者: 吴才文, E-mail: gksky_wcw@163.com
  • 基金资助:

    本研究由国家自然科学基金项目(31360359),国家现代农业产业技术体系建设专项(CARS-20-1-1),云南省中青年学术技术带头人后备人才(2014HB038),云南省应用基础研究计划项目(2016FB071),重大科技专项-生物(2015ZA001)和科技创新人才计划(2014HC015)资助。

Cloning and Expression Analysis of Key Gene ScD27 in Strigolactones Biosynthesis Pathway

WU Zhuan-Di**,LIU Xin-Long**,LIU Jia-Yong,ZAN Feng-Gang,LI Xu-Juan,LIU Hong-Bo,LIN Xiu-Qin, CHEN Xue-Kuan, SU Huo-Sheng,ZHAO Pei-fang,WU Cai-Wen*   

  1. Sugarcane Research Institute, Yunnan Academy of Agricultural Sciences / Yunnan Key Laboratory of Sugarcane Genetic Improvement, Kaiyuan 661699, China
  • Received:2016-01-11 Revised:2016-09-18 Published:2017-01-12 Published online:2016-09-28
  • Contact: 吴才文, E-mail: gksky_wcw@163.com
  • Supported by:

    This study was supported by the National Natural Science Foundation of China (31360359), the National Modern Agricultural Industry Technology System Construction Project (CARS-20-1-1), the Young and Middle-aged Academic Technology Leaders Reserve Talented Person in Yunnan Province (2014HB038), the Applied Basic Research Projects in Yunnan Province (2016FB071), the Major Science and Technology Projects – Biology (2015ZA001), and the Science and Technology Innovation Talents Project (2014HC015).

RichHTML

PDF

793

摘要:

独脚金内酯(Strigolactones SLs)是一类新型植物激素,D27基因是独脚金内酯生物合成途径中最上游的调控基因,且该基因调控SLs的合成是一个可逆的过程。本研究根据水稻、玉米、高粱和二穗短柄草4种禾本科作物的D27基因核苷酸序列保守区域设计引物,以甘蔗品种ROC22的cDNA为模板,利用RT-PCR和RACE技术,从甘蔗中克隆出D27基因的cDNA全长序列,命名为ScD27,GenBank登录号为KP987221.1。该基因序列全长1379 bp,包含一个867 bp的完整开放阅读框(ORF),编码288个氨基酸残基。ScD27编码的蛋白质分子量为71.58 kD,理论等电点为5.04,是一种非分泌性蛋白主要分布于叶绿体上,该蛋白的保守区可能具有2个锌指蛋白结构域(ZnF_TAZ和ZnF_A20),且不存在信号肽;该基因编码的氨基酸序列具有较高的保守性,与高粱、谷子、大麦和短穗二柄草等禾本科植物的D27氨基酸序列相似性在70%以上;ScD27基因在甘蔗各组织部位均有表达,其中茎尖和腋芽中表达量较高,叶、茎和根中的表达较低。此外,ScD27基因在甘蔗茎尖中的表达受PEG、盐胁迫、磷缺乏和营养缺乏的诱导,推测ScD27基因是甘蔗独脚金内酯生物合成途径中响应非生物胁迫的关键基因。

关键词: 甘蔗, ScD27, 同源克隆, 生物信息学, q-PCR

Abstract:

Strigolactones (SLs) is a novel class of plant hormones. D27 regulating reversible metabolic process is located in up-stream of strigolactones biosynthesis pathway. In this study, primers were designed based on the conserved domains from four species inluding Oryza sativa, Zea mays, Sorghum bicolor, and Brachypodium distachyon. Using cDNA from sugarcane cultivar ROC22 as the template, the full-length cDNA sequence of D27 gene from sugarcane was cloned by RT-PCR and RACE method. This gene isnamed as ScD27, with the GenBank accession number of KP987221.1. Its length is 1379bp, and it contains an 867bp open reading frame (ORF), encoding 288 amino acid residues. ScD27 is not a secretory protein and has a molecular weight of 71.58kD, with a theoretical isoelectric point of 5.04. ScD27 is mainly located in chloroplast and the conserved domains of this protein involve two zinc finger protein structures (ZnF_TAZ and ZnF_A20). Amino acid sequences encoded by ScD27 shared more than 70% similarity with the reported amino acid sequences encoded by D27 of Sorghum bicolor, Setaria italica Beauv., Hordeum vulgare subsp. vulgareand Brachypodium distachyon. ScD27 gene was differentially expressed in different parts of sugarcane plant, with higher level of transcript in stem tip and axillary bud but much lower level in leaf, stem and root. Furthermore, the expression of ScD27 could be induced by the stresses of PEG, salt and the deficiencies of phosphorus and nutrition. These results demonstrated that ScD27 might be a key gene participating in the response to abiotic stresses during sugarcane SLs biosynthesis pathway.

Key words: Sugarcane, ScD27, Homology cloning, Bioinformatics, q-PCR

[1] 许智宏, 李家洋. 中国植物激素研究: 过去、现在和未来. 植物学通报, 2006, 23: 433–442
Xu Z H, Li J Y. Plant hormones research in china: past, present and future. Chin Bull Bot, 2006, 23: 433–442 (in Chinese with English abstract)
[2] 王威豪, 王一丁, 莫云川, 叶燕萍, 李杨瑞. 水分胁迫下喷施乙烯利对甘蔗分蘖及农艺性状的影响. 广西农业科学, 2007, (2): 148–151
Wang W H, Wang Y D, Mo Y C, Ye Y P, Li Y Y. Studies on effects of etheph on physiological, biochemical and agronomical characters in sugarcane during tillering stage under water stress. Guangxi Agric Sci, 2007, (2): 148–151 (in Chinese with English abstract)
[3] Vasantha S, Shekinah D E, Gupta C, Rakkiyappan P. Tiller production, regulation and senescence in sugarcane (Saccharum species hybrid) genotypes. Sugar Tech, 2012, 14: 156–160
[4] Gomez-Roldan V, Fermas S, Brewer P B, Puech-Pages V, Dun E A, Pillot J P, Letisse F, Matusova R, Danoun S, Portais J C, Bouwmeester H, Becard G, Beveridge C A, Rameau C, Rochange S F. Strigolactone inhibition of shoot branching. Nature, 2008, 455: 189–194
[5] Klee H. Plant biology: Hormones branch out. Nature, 2008, 455: 176–177
[6] Umehara M, Hanada A, Yoshida S, Akiyama K, Arite T, Takeda-Kamiya N, Magome H, Kamiya Y, Shirasu K, Yoneyama K, Kyozuka J, Yamaguchi S. Inhibition of shoot branching by new terpenoid plant hormones. Nature, 2008, 455: 195–200
[7] Koltai H. Strigolactones are regulators of root development. New Phytol, 2011, 190: 545–549
[8] Al-Babili S, Bouwmeester H J. Strigolactones, a novel carotenoid-derived plant hormone. Annu Rev Plant Biol, 2015, 66: 161–186
[9] Rasmussen A, Hosseini S A, Hajirezaei M R, Druege U, Geelen D. Adventitious rooting declines with the vegetative to reproductive switch and involves a changed auxin homeostasis. J Exp Bot, 2015, 66: 1437–1452
[10] Andreo-Jimenez B, Ruyter-Spira C, Bouwmeester H J, Lopez-Raez J A. Ecological relevance of strigolactones in nutrient uptake and other abiotic stresses, and in plant-microbe interactions below-ground. Plant Soil. 2015, 394: 1–19
[11] Alder A, Jamil M, Marzorati M, Bruno M, Vermathen M, Bigler P, Ghisla S, Bouwmeester H, Beyer P, Al-Babili S. The path from beta-carotene to carlactone, a strigolactone-like plant hormone. Science, 2012, 335: 1348–1351
[12] Booker J, Sieberer T, Wright W, Williamson L, Willett B, Stirnberg P, Turnbull C, Srinivasan M, Goddard P, Leyser O. MAX1 encodes a cytochrome P450 family member that acts downstream of MAX3/4 to produce a carotenoid-derived branch-inhibiting hormone. Dev Cell, 2005, 8: 443–449
[13] Simons J L, Napoli C A, Janssen B J, Plummer K M, Snowden K C. Analysis of the DECREASED APICAL DOMINANCE genes of petunia in the control of axillary branching. Plant Physiol, 2007, 143: 697–706
[14] Drummond R S, Martinez-Sanchez N M, Janssen B J, Templeton K R, Simons J L, Quinn B D, Karunairetnam S, Snowden K C. Petunia hybrida CAROTENOID CLEAVAGE DIOXYGENASE 7 is involved in the production of negative and positive branching signals in petunia. Plant Physiol, 2009, 151: 1867–1877
[15] Drummond R S, Sheehan H, Simons J L, Martinez-Sanchez N M, Turner R M, Putterill J, Snowden K C. The expression of petunia strigolactone pathway genes is altered as part of the endogenous developmental program. Front Plant Sci, 2011, 2: 115
[16] Sorefan K, Booker J, Haurogne K, Goussot M, Bainbridge K, Foo E, Chatfield S, Ward S, Beveridge C, Rameau C, Leyser O. MAX4 and RMS1 are orthologous dioxygenase-like genes that regulate shoot branching in Arabidopsis and pea. Genes Dev, 2003, 17: 1469–1474
[17] 王涛. 水稻独脚金内酯相关基因的图位克隆与功能分析. 中国农业科学院博士学位论文, 北京, 2012
Wang T. Map-Based Cloning and Functional Analysis of the Strigolactones-Related Genes in Rice (Orzya sativa L.). PhD Dissertation of Chinese Academy of Agriculture Science, Beijing, China, 2012
[18] Waters M T, Brewer P B, Bussell J D, Smith S M, Beveridge C A. The Arabidopsis ortholog of rice DWARF27 acts upstream of MAX1 in the control of  plant development by strigolactones. Plant Physiol, 2012, 159: 1073–1085
[19] Zhang Y, van Dijk A D, Scaffidi A, Flematti G R, Hofmann M, Charnikhova T, Verstappen F, Hepworth J, van der Krol S, Leyser O, Smith S M, Zwanenburg B, Al-Babili S, Ruyter-Spira C, Bouwmeester H J. Rice cytochrome P450 MAX1 homologs catalyze distinct steps in strigolactone biosynthesis. Nat Chem Biol, 2014, 10: 1028–1033
[20] Lin H, Wang R, Qian Q, Yan M, Meng X, Fu Z, Yan C, Jiang B, Su Z, Li J, Wang Y. DWARF27, an iron-containing protein required for the biosynthesis of strigolactones, regulates rice tiller bud outgrowth. Plant Cell, 2009, 21: 1512–1525
[21] Rubio-Moraga A, Ahrazem O, Perez-Clemente R M, Gomez-Cadenas A, Yoneyama K, Lopez-Raez J A, Molina R V, Gomez-Gomez L. Apical dominance in saffron and the involvement of the branching enzymes CCD7 and CCD8 in the control of bud sprouting. BMC Plant Biol, 2014, 14: 171
[22] 陈芳育, 江良荣, 郑景生, 黄荣裕, 王侯聪. 用蛋白质组遗传方法分析水稻多蘖矮秆突变体的共分离蛋白. 中国遗传学会大会,厦门大学, 2011
Chen F Y, Jiang L R, Zheng J S, Huang R Y, Wang H C. Fine mapping and proteomics analysis of a high-tillering dwarf mutant in rice. Congress of Chinese genetic Society Xiamen University, 2010
[23] Arite T, Iwata H, Ohshima K, Maekawa M, Nakajima M, Kojima M, Sakakibara H, Kyozuka J. DWARF10, an RMS1/MAX4/DAD1 ortholog, controls lateral bud outgrowth in rice. Plant J, 2007, 51: 1019–1029
[24] Harrison P J, Newgas S A, Descombes F, Shepherd S A, Thompson A J, Bugg T D. Biochemical characterization and selective inhibition of beta-carotene cis-trans isomerase D27 and carotenoid cleavage dioxygenase CCD8 on the strigolactone biosynthetic pathway. FEBS J, 2015, 282: 3986–4000
[25] Wen C, Zhao Q, Nie J, Liu G, Shen L, Cheng C, Xi L, Ma N, Zhao L. Physiological controls of chrysanthemum DgD27 gene expression in regulation of shoot branching. Plant Cell Rep, 2016
[26] Abe S, Sado A, Tanaka K, Kisugi T, Asami K, Ota S, Kim H I, Yoneyama K, Xie X, Ohnishi T, Seto Y, Yamaguchi S, Akiyama K, Yoneyama K, Nomura T. Carlactone is converted to carlactonoic acid by MAX1 in Arabidopsis and its methyl ester can directly interact with AtD14 in vitro. Proc Natl Acad Sci USA, 2014, 111: 18084–18089
[27] Zou J, Zhang S, Zhang W, Li G, Chen Z, Zhai W, Zhao X, Pan X, Xie Q, Zhu L. The rice HIGH-TILLERING DWARF1 encoding an ortholog of Arabidopsis MAX3 is required for negative regulation of the outgrowth of axillary buds. Plant J, 2006, 48: 687–698
[28] 王闵霞, 白玉路, 王平, 向跃武, 蔡平钟, 张志雄. 水稻Dwarf 14(D14)基因的生物信息学分析. 西南农业学报. 2014, 27: 1347–1352
Wang M X, Bai Y L Wang P, Xiang Y W, Cai P Z, Zhang Z X. Bioinformatics analysis of D14(Dwarf 14) in rice. Southwest China J Agric Sci, 2014, 27: 1347–1352 (in Chinese with English abstract)
[29] Zhao J, Wang T, Wang M, Liu Y, Yuan S, Gao Y, Yin L, Sun W, Peng L, Zhang W, Wan J, Li X. DWARF3 participates in an SCF complex and associates with DWARF14 to suppress rice shoot branching. Plant Cell Physiol, 2014, 55: 1096–1109
[30] Zhao L H, Zhou X E, Yi W, Wu Z, Liu Y, Kang Y, Hou L, de Waal P W, Li S, Jiang Y, Scaffidi A, Flematti G R, Smith S M, Lam V Q, Griffin P R, Wang Y, Li J, Melcher K, Xu H E. Destabilization of strigolactone receptor DWARF14 by binding of ligand and E3-ligase signaling effector DWARF3. Cell Res, 2015, 25: 1219–1236
[31] Soundappan I, Bennett T, Morffy N, Liang Y, Stanga J P, Abbas A, Leyser O, Nelson D C. SMAX1-LIKE/D53 Family Members Enable Distinct MAX2-Dependent Responses to Strigolactones and Karrikins in Arabidopsis. Plant Cell, 2015, 27: 3143–3159
[32] Arite T, Umehara M, Ishikawa S, Hanada A, Maekawa M, Yamaguchi S, Kyozuka J. d14, a strigolactone-insensitive mutant of rice, shows an accelerated outgrowth of tillers. Plant Cell Physiol, 2009, 50: 1416–1424
[33] Ishikawa S, Maekawa M, Arite T, Onishi K, Takamure I, Kyozuka J. Suppression of tiller bud activity in tillering dwarf mutants of rice. Plant Cell Physiol, 2005, 46: 79–86
[34] Zhou F, Lin Q, Zhu L, Ren Y, Zhou K, Shabek N, Wu F, Mao H, Dong W, Gan L, Ma W, Gao H, Chen J, Yang C, Wang D, Tan J, Zhang X, Guo X, Wang J, Jiang L, Liu X, Chen W, Chu J, Yan C, Ueno K, Ito S, Asami T, Cheng Z, Wang J, Lei C, Zhai H, Wu C, Wang H, Zheng N, Wan J. D14-SCFD3-dependent degradation of D53 regulates strigolactone signalling. Nature, 2013, 504: 406–410
[35] Jiang L, Liu X, Xiong G, Liu H, Chen F, Wang L, Meng X, Liu G, Yu H, Yuan Y, Yi W, Zhao L, Ma H, He Y, Wu Z, Melcher K, Qian Q, Xu H E, Wang Y, Li J. DWARF 53 acts as a repressor of strigolactone signalling in rice. Nature, 2013, 504: 401–405
[36] Brewer P B, Dun E A, Ferguson B J, Rameau C, Beveridge C A. Strigolactone acts downstream of auxin to regulate bud outgrowth in pea and Arabidopsis. Plant Physiol, 2009, 150: 482–493
[37] 贾昆鹏. 植物激素独脚金内酯和茉莉酸信号与光信号互作的分子机制研究. 上海: 上海交通大学, 2014
Jia K P. The molecular mechanism of cross talking between light and phytohormones strigolactone and jasmonate signaling. Shanghai: Shanghai Jiao Tong University, 2014 (in Chinese with English abstract)
[38] Kumar M, Pandya-Kumar N, Dam A, Haor H, Mayzlish-Gati E, Belausov E, Wininger S, Abu-Abied M, Mcerlean C S, Bromhead L J, Prandi C, Kapulnik Y, Koltai H. Arabidopsis response to low-phosphate conditions includes active changes in actin filaments and PIN2 polarization and is dependent on strigolactone signalling. J Exp Bot, 2015, 66: 1499–1510
[39] Yoneyama K, Xie X, Kusumoto D, Sekimoto H, Sugimoto Y, Takeuchi Y, Yoneyama K. Nitrogen deficiency as well as phosphorus deficiency in sorghum promotes the production and exudation of 5-deoxystrigol, the host recognition signal for arbuscular mycorrhizal fungi and root parasites. Planta, 2007, 227: 125–132
[40] Lopez-Raez J A, Charnikhova T, Gomez-Roldan V, Matusova R, Kohlen W, De Vos R, Verstappen F, Puech-Pages V, Becard G, Mulder P, Bouwmeester H. Tomato strigolactones are derived from carotenoids and their biosynthesis is promoted by phosphate starvation. New Phytol, 2008, 178: 863–874
[41] Bu Q, Lv T, Shen H, Luong P, Wang J, Wang Z, Huang Z, Xiao L, Engineer C, Kim T H, Schroeder J I, Huq E. Regulation of drought tolerance by the F-box protein MAX2 in Arabidopsis. Plant Physiol, 2014, 164: 424–439
[42] Ha C V, Leyva-Gonzalez M A, Osakabe Y, Tran U T, Nishiyama R, Watanabe Y, Tanaka M, Seki M, Yamaguchi S, Dong N V, Yamaguchi-Shinozaki K, Shinozaki K, Herrera-Estrella L, Tran L S. Positive regulatory role of strigolactone in plant responses to drought and salt stress. Proc Natl Acad Sci USA, 2014, 111: 851–856
[43] Yamaguchi S, Kyozuka J. Branching hormone is busy both underground and overground. Plant Cell Physiol, 2010, 51: 1091–1094
[44] Sun H, Tao J, Liu S, Huang S, Chen S, Xie X, Yoneyama K, Zhang Y, Xu G. Strigolactones are involved in phosphate- and nitrate-deficiency-induced root development and auxin transport in rice. J Exp Bot, 2014, 65: 6735–6746
[45] 李晓君. 甘蔗逆境相关锌指蛋白基因ShSAP1的功能研究. 海南大学博士学位论文, 海南海口, 2012
Li X J. Functional Analysis of Stress Associated Zinc Finger Protein Gene ShSAP1 from Sugarcane. PhD Dissertation of Hainan University, Haikou, China, 2012 (in Chinese with English abstract)
[46] 阙友雄, 许莉萍, 徐景升, 张积森, 张木清, 陈如凯. 甘蔗基因表达定量PCR分析中内参基因的选择. 热带作物学报, 2009, 30(3): 274–278
Que Y X, Xu L P, Xu J S, Zhang J S, Zhang M Q, Chen Y K. Selection of control genes in Real-time qPCR analysis of gene expression in sugarcane. Chin J Trop Crops, 2009, 30(3): 274–278 (in Chinese with English abstract)
[47] 谢晓娜, 杨丽涛, 王盛, 张小秋, 李杨瑞. 甘蔗NADP异柠檬酸脱氢酶基因(SoNADP-IDH)的克隆与表达分析. 中国农业科学, 2015, 48: 185–196
Xie X N, Yang L T, Wang S, Zhang X Q, Li Y Y. Cloning and expression analysis of sugarcane NADP+-dependent isocitrate dehydrogenase (SoNADP-IDH) gene. Sci Agric Sin, 2015, 48: 185–196 (in Chinese with English abstract)
[48] Vij S, Tyagi A K. Genome-wide analysis of the stress associated protein (SAP) gene family containing A20/AN1 zinc-finger(s) in rice and their phylogenetic relationship with Arabidopsis. Mol Genet Genom, 2006, 276: 565–575
[49] Waldie T, Mcculloch H, Leyser O. Strigolactones and the control of plant development: lessons from shoot branching. Plant J, 2014, 79: 607–622
[50] 李晓君, 武媛丽, 孔冉, 杨本鹏, 张树珍. 植物A20/AN1型锌指蛋白基因功能研究进展. 生物技术通报, 2013, 29(12): 6–14
Li X J, Wu Y L, Kong R, Yang B P, Zhang S Z. Functional Research of A20/AN1 type zinc finger protein gene in plants. Biotechnol Bull, 2013, 29(12): 6–14 (in Chinese with English abstract)
[51] Mayzlish-Gati E, De-Cuyper C, Goormachtig S, Beeckman T, Vuylsteke M, Brewer P B, Beveridge C A, Yermiyahu U, Kaplan Y, Enzer Y, Wininger S, Resnick N, Cohen M, Kapulnik Y, Koltai H. Strigolactones are involved in root response to low phosphate conditions in Arabidopsis. Plant Physiol, 2012, 160: 1329–1341
[52] Yoneyama K, Yoneyama K, Takeuchi Y, Sekimoto H. Phosphorus deficiency in red clover promotes exudation of orobanchol, the signal for mycorrhizal symbionts and germination stimulant for root parasites. Planta, 2007, 225: 1031–1038
[1] 肖健, 陈思宇, 孙妍, 杨尚东, 谭宏伟. 不同施肥水平下甘蔗植株根系内生细菌群落结构特征[J]. 作物学报, 2022, 48(5): 1222-1234.
[2] 周慧文, 丘立杭, 黄杏, 李强, 陈荣发, 范业赓, 罗含敏, 闫海锋, 翁梦苓, 周忠凤, 吴建明. 甘蔗赤霉素氧化酶基因ScGA20ox1的克隆及功能分析[J]. 作物学报, 2022, 48(4): 1017-1026.
[3] 孔垂豹, 庞孜钦, 张才芳, 刘强, 胡朝华, 肖以杰, 袁照年. 不同施肥水平下丛枝菌根真菌对甘蔗生长及养分相关基因共表达网络的影响[J]. 作物学报, 2022, 48(4): 860-872.
[4] 巫燕飞, 胡琴, 周棋, 杜雪竹, 盛锋. 水稻延伸因子复合体家族基因鉴定及非生物胁迫诱导表达模式分析[J]. 作物学报, 2022, 48(3): 644-655.
[5] 杨宗桃, 刘淑娴, 程光远, 张海, 周营栓, 商贺阳, 黄国强, 徐景升. 甘蔗类泛素蛋白UBL5应答SCMV侵染及其与SCMV-6K2的互作[J]. 作物学报, 2022, 48(2): 332-341.
[6] 余慧芳, 张卫娜, 康益晨, 范艳玲, 杨昕宇, 石铭福, 张茹艳, 张俊莲, 秦舒浩. 马铃薯CrRLK1Ls基因家族的鉴定及响应晚疫病菌信号的表达分析[J]. 作物学报, 2022, 48(1): 249-258.
[7] 荐红举, 尚丽娜, 金中辉, 丁艺, 李燕, 王季春, 胡柏耿, Vadim Khassanov, 吕典秋. 马铃薯PIF家族成员鉴定及其对高温胁迫的响应分析[J]. 作物学报, 2022, 48(1): 86-98.
[8] 张海, 程光远, 杨宗桃, 刘淑娴, 商贺阳, 黄国强, 徐景升. 甘蔗PsbR亚基应答SCMV侵染及其与SCMV-6K2的互作[J]. 作物学报, 2021, 47(8): 1522-1530.
[9] 傅华英, 张婷, 彭文静, 段瑶瑶, 许哲昕, 林艺华, 高三基. 甘蔗新品种(系)苗期白条病人工接种抗性鉴定与评价[J]. 作物学报, 2021, 47(8): 1531-1539.
[10] 苏亚春, 李聪娜, 苏炜华, 尤垂淮, 岑光莉, 张畅, 任永娟, 阙友雄. 甘蔗割手密种类甜蛋白家族鉴定及栽培种同源基因功能分析[J]. 作物学报, 2021, 47(7): 1275-1296.
[11] 黄宁, 惠乾龙, 方振名, 李姗姗, 凌辉, 阙友雄, 袁照年. 甘蔗β-胡萝卜素异构酶基因家族的鉴定、定位和表达分析[J]. 作物学报, 2021, 47(5): 882-893.
[12] 王恒波, 陈姝琦, 郭晋隆, 阙友雄. 甘蔗抗黄锈病G1标记的分子检测及候选抗病基因WAK的分析[J]. 作物学报, 2021, 47(4): 577-586.
[13] 张荣跃, 王晓燕, 杨昆, 单红丽, 仓晓燕, 李婕, 王长秘, 尹炯, 罗志明, 李文凤, 黄应昆. 甘蔗新品种及主栽品种对褐锈病抗性与Bru1基因分子检测[J]. 作物学报, 2021, 47(2): 376-382.
[14] 李鹏, 刘彻, 宋皓, 姚盼盼, 苏沛霖, 魏跃伟, 杨永霞, 李青常. 烟草非特异性脂质转移蛋白基因家族的鉴定与分析[J]. 作物学报, 2021, 47(11): 2184-2198.
[15] 仓晓燕, 夏红明, 李文凤, 王晓燕, 单红丽, 王长秘, 李婕, 张荣跃, 黄应昆. 甘蔗优良品种(系)对黑穗病的抗性评价[J]. 作物学报, 2021, 47(11): 2290-2296.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备15008789号-2