NaCl和Na2CO3对不同棉花基因组的DNA甲基化影响

doi:10.3864/j.issn.0578-1752.2014.16.002

Abstract

Abstract: 【Objective】 The objective of the study is to research the change of genomic DNA methylation under different types of salt and to compare the variation of DNA methylation between leaves and roots, which can help us make it clear about the relation between DNA methylation and the salt tolerance in cotton.【Method】In the study, salt-tolerant variety Zhong9806 and salt-sensitive variety ZhongS9612 were used as experimental materials, which were treated with NaCl and Na2CO3 at concentration of 0.4%, respectively. DNA extracted from control materials and the treatment materials were used for double digestions, ligation reactions, pre-amplification reactions and selective amplification reactions, then MSAP technology (Methylation sensitive amplified polymorphism) was used to explore the change of DNA methylation between the control and treatment materials in cotton seedlings. The differentially methylated DNA fragments were isolated from the polyacrylamide gel, sequenced and BLAST analysis in NCBI library. Real time-PCR technology was used to test the expression quantity of polymorphic fragments in cotton seedlings.【Result】The results of salt stress indicated that the effects of different salt stresses on the growth of cotton seedlings were different. Neutral salt NaCl at 0.4% concentration had a relatively small effect on cotton seedling，and the morphological characters of different tissues changed a little, but 0.4% alkaline salt Na2CO3 had a bigger harm, resulted in the cotyledon soft, and the basal part of stem and roots of cotton seedlings black. MSAP analysis showed that after NaCl treatment, the genomic DNA methylation level of leaves of Zhong9806 and ZhongS9612 were 23.5% and 27.7%, in which full methylated ratio was 20.3% and 22.9%, respectively. The methylation level of roots of Zhong9806 and ZhongS9612 was 24.7% and 27.1%, in which full methylated ratio was 19.6% and 21.6%, respectively. After Na2CO3 treatment, the methylation level of leaves of Zhong9806 and ZhongS9612 were 28.9% and 28.1%, in which full methylated ratio was 24.3% and 24.5%, respectively. The methylation level of roots of Zhong9806 and ZhongS9612 was 25.7% and 27.6%, in which full methylated ratio was 21.5% and 24.0%, respectively. Genomic DNA methylation levels were different between leaves and roots. With the salt type changed from neutral salt to alkaline salt, the genomic DNA methylation levels went up rapidly and reached the maximum in the Na2CO3 treatment. From the result of DNA methylation status analysis, we could learn that the methylated band ratio (% polymorphic bands) in leaves of Zhong9806 was 40.00% and 50.00%, respectively, and demethylated band ratio (% polymorphic bands) was 54.12% and 46.67%, respectively. The methylated band ratio (% polymorphic bands) in roots of Zhong9806 was 35.53% and 43.59%, respectively, and demethylated band ratio (% polymorphic bands) was 56.58% and 51.28%, respectively. But the methylated band ratio (% polymorphic bands) and the demethylated band ratio (% polymorphic bands) in leaves and roots of ZhongS9612 changed a little after stress. In total, 6 fragments were obtained from the gel, which were amplified and analyzed with BLAST method. The result indicated that the 6 sequences were homologous to 6 different genes, widely distributed in coding region and non-coding region, involving different metabolic reactions. The analysis of qRT-PCR showed that these genes were differentially expressed between control and treatment.【Conclusion】The response of cotton varieties with different salt-tolerances to the stress of different salt is different. The DNA methylation level of Zhong 9806, a salt-tolerant variety, declined under salt stress, which could induce the expression of genes related to salt-tolerance, but Zhong S9612, a salt-sensitive variety, lack relevant genes to make the damage increase, reaching the most after the Na2CO3 treatment. A big difference exists in the DNA methylation level between the control and treatment，and the pattern of DNA methylation has tissue specificity. From the analysis of polymorphic fragments, homogenous genes involve many metabolic pathways, through the synergistic effect of three pathways to deal with the stress.

Key words: cotton , DNA methylation , MSAP , salt , qRT-PCR

LU Xu-Ke, WANG De-Long, YIN Zu-Jun, WANG Jun-Juan, FAN Wei-Li, WANG Shuai, ZHAO Xiao-Jie, ZHANG Tian-Bao, YE Wu-Wei. Genomic DNA Methylation Polymorphism Analysis of Cotton Under NaCl and Na2CO3 Stress[J].Scientia Agricultura Sinica, 2014, 47(16): 3132-3142.

0
/ / Recommend

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

URL: https://www.chinaagrisci.com/EN/10.3864/j.issn.0578-1752.2014.16.002

https://www.chinaagrisci.com/EN/Y2014/V47/I16/3132

References

[1]Watanable K, Tanaka T, Hottta Y, Kuramochi H, Takeuchi Y. Improving salt tolerance of cotton seedings with 5-aminolevulinic acid. Plant Growth Regulation, 2000, 32: 99-103.

[2]Xiong L M, Karen S S, Zhu J K. Cell signaling during cold, drought, and salt stress. The Plant Cell, 2002, 14(Suppl.): 165-183.

[3]Gonzalgo M L, Jones P A. Mutagenic and epigenetic effects of DNA methylation. Mutation Research, 1997, 386: 107-118.

[4]Vaillant I, Paszkowski J. Role of histone and DNA methylation in gene regulation. Current Opinion in Plant Biology, 2007, 10(5): 528-533.

[5]Martienssen R A, Colot V. DNA methylation and epigenetic inheritance in plants and filamentous fungi. Science, 2001, 93(5532): 1070-1074.

[6]Richards E J. DNA methylation and plant development. Trends in Genetics, 1997, 13: 319-323.

[7]Vanyushin B F, Ashapkin V V. DNA methylation in higher plants: Past, present and future. Biochimica et Biophysica Acta, 2011, 1809: 360-368.

[8]Zilberman D, Gehring M, Tran R K, Ballinger T, Henikoff S. Genome-wide analysis of Arabidopsis thaliana DNA methylation uncovers an inter-dependence between methylation and transcription. Nature Genetics, 2007, 39: 61-69.

[9]Ronemus M J, Galbiati M, Ticknor C, Chen J, Dellaporta S L. Demethylation-induced developmental pleiotropy in Arabidopsis. Science, 1996, 273: 657.

[10]Choi C S, Sano H. Abiotic-stress induces demethylation and transcriptional activation of a gene encoding a glycerophosphodiesterase- like protein in tobacco plants. Molecular Genetics and Genomics, 2007, 5(277): 589-600.

[11]Jaligot E, Beule T, Rival A. Methylation-sensitive RFLPs: Characterization of two oil palm markers showing somaclonal variation-associated polymorphism. Theoretical and Applied Genetics, 2002, 104: 1263-1269.

[12]McClelland M, Nelson M, Raschke E. Effect of site-specific modification on restriction endonuclease and DNA modification methyltransferases. Nucleic Acids Research, 1994, 17: 3640-3659.

[13]Cervera M T, Ruiz-Garcia L, Martinez-Zapater J M. Analysis of DNA methylation in Arabidopsis thaliana based on methylation-sensitive AFLP markers. Molecular Genetics and Genomics, 2002, 268: 543-552.

[14]Ashikawa I. Surveying CpG methylation at 5'-CCGG in the genomes of rice cultivars. Plant Molecular Biology, 2001, 45: 31-39.

[15]李雪林, 林忠旭, 聂以春, 郭小平, 张献龙. 盐胁迫下棉花基因组DNA表观遗传变化的MSAP分析. 作物学报, 2009, 35(4): 588-596.

Li X L, Lin Z X, Nie Y C, Guo X P, Zhang X L. Methylation-sensitive amplification polymorphism of epigenetic changes in cotton under salt stress. Acta Agronomica Sinica, 2009, 35(4): 588-596. (in Chinese)

[16]潘雅娇, 傅彬英, 王迪, 朱苓华, 黎志康. 水稻干旱胁迫诱导DNA甲基化时空变化特征分析. 中国农业科学, 2009, 42(9): 3009-3018.

Pan Y J, Fu B Y, Wang D, Zhu L H, Li Z K. Spatial and temporal profiling of DNA methylation induced by drought stress in rice. Scientia Agricultura Sinica, 2009, 42(9): 3009-3018. (in Chinese)

[17]崔宇鹏, 樊保香, 王德龙, 王俊娟, 王帅, 叶武威. 盐胁迫下棉花叶片差异蛋白表达的分析. 分子植物育种, 2012, 10(1): 48-54.

Cui Y P, Fan B X, Wang D L, Wang J J, Wang S, Ye W W. Analysis of differential proteins of cotton leaves under salt stress. Molecular Plant Breeding, 2012, 10(1): 48-54. (in Chinese)

[18]Porebski S, Grant-Bailey L, Baum B R. Modification of a CTAB extraction protocol for plants containing high polysaccharide and polyphenol components. Plant Molecular Biology Reporter, 1997, 15(1): 8-15.

[19]Zhao Y L, Yu S X, Ye W W, Wang H M, Wang J J, Fang B X. Study on DNA cytosine methylation of cotton (Gossypium hirsutum L.) genome and its implication for salt tolerance. Agricultural Science in China, 2010, 9(6): 783-791.

[20]Mcclelland M, Nelson M, Raschke E. Effect of site-specific modification on restriction endonucleases and DNA modification methyltransferases. Nucleic Acids Research, 1994, 22(17): 3640-3459.

[21]Vanyushin B F, Ashapkin V V. DNA Methylation in Plants. New York: Nova Science Press, 2009.

[22]李春贺. 盐胁迫条件下不同耐盐棉花miRNA差异差异表达分析[D]. 泰安: 山东农业大学, 2009.

Li C H. Differential expression of miRNA in different salt- tolerant cotton varieties under salt stress [D]. Taian: Shandong Agricultural University, 2009. (in Chinese)

[23]Cervera M T, Ruiz-Garcia L, Martinez-Zapater J M. Analysis of DNA methylation in Arabidopsis thaliana based on methylation-sensitive AFLP markers. Molecular Genetics and Genomics, 2002, 268: 543-552.

[24]Kovarik A, Koukalov B, Bezdk M, Opatrn Z. Hyper-methylation of tobacco heterochromatic loci in response to osmotic stress. Theoretical and Applied Genetics, 1997, 95: 301-306.

[25]Tan M P. Analysis of DNA methylation of maize inresponse to osmotic and salt stress based on methylation-sensitive amplified polymorphism. Plant Physiology and Biochemistry, 2010, 48: 21-26.

[26]葛才林, 杨小勇, 刘向农, 孙锦荷, 罗时石, 王泽港. 重金属对水稻和小麦DNA甲基化水平的影响. 植物生理与分子生物学学报, 2002, 28(5): 363-368.

Ge C L, Yang X Y, Liu X N, Sun J H, Luo S S, Wang Z G. Effect of heavy metal on levels of methylation in DNA of rice and wheat. Journal of Plant Physiology and Molecular Biology, 2002, 28(5): 363-368. (in Chinese)

[27]Labra M, Ghiani A, Citterio S, Sgorbati S, Sala F, Vannini C, Ruffini-Castiglione M, Bracale M. Analysis of cytosine methylaion pattern in response to water deficit in pea root tips. Plant Biology, 2002, 4(6): 694-699.

[28]宋贵方, 樊伟丽, 王俊娟, 王德龙, 王帅, 周凯, 叶武威. 陆地棉干旱胁迫响应基因GhGR的克隆及特征分析. 中国农业科学, 2012, 45(8): 1644-1652.

Song G F, Fan W L, Wang J J, Wang D L, Wang S, Zhou K, Ye W W. Cloning and characterization of drought-stress responsive gene GhGR in Gossypium hirsutum L.. Scientia Agricultura Sinica, 2012, 45(8): 1644-1652. (in Chinese)

[29]Friedrichsen D M, Joazeiro C A P, Li J M, Hunter T, Chory J. Brassinosteroid-insensitive-1 is a ubiquitously expressed leucine-rich repeat receptor serine/threonine kinase. Plant Physiology, 2000, 123(4): 1247-1256.

[30]Cheng D H, Côté J, Shaaban S, Bedford M T. The arginine methyltransferase CARM1 regulates the coupling of transcription and mrna processing. Molecular Cell, 2007, 25(12): 71-83.

[31]Lian C L, Zhou Z H, Hogetsu T. A simple method for amplified fragments developing micro- satellite markers using of inter-simple sequence repeat (ISSR). Journal of Plant Research, 2001, 114: 381-385.

Related Articles 15

[1]	WANG CaiXiang,YUAN WenMin,LIU JuanJuan,XIE XiaoYu,MA Qi,JU JiSheng,CHEN Da,WANG Ning,FENG KeYun,SU JunJi. Comprehensive Evaluation and Breeding Evolution of Early Maturing Upland Cotton Varieties in the Northwest Inland of China [J]. Scientia Agricultura Sinica, 2023, 56(1): 1-16.
[2]	WANG JunJuan,LU XuKe,WANG YanQin,WANG Shuai,YIN ZuJun,FU XiaoQiong,WANG DeLong,CHEN XiuGui,GUO LiXue,CHEN Chao,ZHAO LanJie,HAN YingChun,SUN LiangQing,HAN MingGe,ZHANG YueXin,FAN YaPeng,YE WuWei. Characteristics and Cold Tolerance of Upland Cotton Genetic Standard Line TM-1 [J]. Scientia Agricultura Sinica, 2022, 55(8): 1503-1517.
[3]	WANG SiTong,CHEN Yan,LUO YuJia,YANG YuanYuan,JIANG ZhiYang,JIANG XinYi,ZHONG Fan,CHEN Hao,XU HongXing,WU Yan,DUAN HongXia,TANG Bin. Effect of Three Novel Compounds on Trehalose and Chitin Metabolism and Development of Spodoptera frugiperda [J]. Scientia Agricultura Sinica, 2022, 55(8): 1568-1578.
[4]	YIN YanYu,XING YuTong,WU TianFan,WANG LiYan,ZHAO ZiXu,HU TianRan,CHEN Yuan,CHEN Yuan,CHEN DeHua,ZHANG Xiang. Cry1Ac Protein Content Responses to Alternating High Temperature Regime and Drought and Its Physiological Mechanism in Bt Cotton [J]. Scientia Agricultura Sinica, 2022, 55(23): 4614-4625.
[5]	XIE XiaoYu, WANG KaiHong, QIN XiaoXiao, WANG CaiXiang, SHI ChunHui, NING XinZhu, YANG YongLin, QIN JiangHong, LI ChaoZhou, MA Qi, SU JunJi. Restricted Two-Stage Multi-Locus Genome-Wide Association Analysis and Candidate Gene Prediction of Boll Opening Rate in Upland Cotton [J]. Scientia Agricultura Sinica, 2022, 55(2): 248-264.
[6]	SHI XiaoLong,GUO Pei,REN JingYao,ZHANG He,DONG QiQi,ZHAO XinHua,ZHOU YuFei,ZHANG Zheng,WAN ShuBo,YU HaiQiu. A Salt Stress Tolerance Effect Study in Peanut Based on Peanut//Sorghum Intercropping System [J]. Scientia Agricultura Sinica, 2022, 55(15): 2927-2937.
[7]	HU YaLi,NIE JingZhi,WU Xia,PAN Jiao,CAO Shan,YUE Jiao,LUO DengJie,WANG CaiJin,LI ZengQiang,ZHANG Hui,WU QiJing,CHEN Peng. Effect of Salicylic Acid Priming on Salt Tolerance of Kenaf Seedlings [J]. Scientia Agricultura Sinica, 2022, 55(14): 2696-2708.
[8]	ZHU ChunYan,SONG JiaWei,BAI TianLiang,WANG Na,MA ShuaiGuo,PU ZhengFei,DONG Yan,LÜ JianDong,LI Jie,TIAN RongRong,LUO ChengKe,ZHANG YinXia,MA TianLi,LI PeiFu,TIAN Lei. Effects of NaCl Stress on the Chlorophyll Fluorescence Characteristics of Seedlings of Japonica Rice Germplasm with Different Salt Tolerances [J]. Scientia Agricultura Sinica, 2022, 55(13): 2509-2525.
[9]	WANG Juan, MA XiaoMei, ZHOU XiaoFeng, WANG Xin, TIAN Qin, LI ChengQi, DONG ChengGuang. Genome-Wide Association Study of Yield Component Traits in Upland Cotton (Gossypium hirsutum L.) [J]. Scientia Agricultura Sinica, 2022, 55(12): 2265-2277.
[10]	BIAN LanXing,LIANG LiKun,YAN Kun,SU HongYan,LI LiXia,DONG XiaoYan,MEI HuiMin. Effects of Trichoderma on Root and Leaf Ionic Homeostasis and Photosystem II in Chinese Wolfberry Under Salt Stress [J]. Scientia Agricultura Sinica, 2022, 55(12): 2413-2424.
[11]	WANG Ning,FENG KeYun,NAN HongYu,ZHANG TongHui. Effects of Combined Application of Organic Fertilizer and Chemical Fertilizer on Root Characteristics and Yield of Cotton Under Different Water Conditions [J]. Scientia Agricultura Sinica, 2022, 55(11): 2187-2201.
[12]	LIU Chuang,GAO Zhen,YAO YuXin,DU YuanPeng. Functional Identification of Grape Potassium Ion Transporter VviHKT1;7 Under Salt Stress [J]. Scientia Agricultura Sinica, 2021, 54(9): 1952-1963.
[13]	QIN HongDe, FENG ChangHui, ZHANG YouChang, BIE Shu, ZHANG JiaoHai, XIA SongBo, WANG XiaoGang, WANG QiongShan, LAN JiaYang, CHEN QuanQiu, JIAO ChunHai. F₁ Performance Prediction of Upland Cotton Based on Partial NCII Design [J]. Scientia Agricultura Sinica, 2021, 54(8): 1590-1598.
[14]	TongYu HOU,TingLi HAO,HaiJiang WANG,Ze ZHANG,Xin LÜ. Advances in Cotton Growth and Development Modelling and Its Applications in China [J]. Scientia Agricultura Sinica, 2021, 54(6): 1112-1126.
[15]	ZHANG GuiYun,ZHU JingWen,SUN MingFa,YAN GuoHong,LIU Kai,WAN BaiJie,DAI JinYing,ZHU GuoYong. Analysis of Differential Metabolites in Grains of Rice Cultivar Changbai 10 Under Salt Stress [J]. Scientia Agricultura Sinica, 2021, 54(4): 675-683.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

Genomic DNA Methylation Polymorphism Analysis of Cotton Under NaCl and Na2CO3 Stress

RichHTML

PDF

Cited

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Comments

Recommended 0