不同生长势美洲黑杨转录组差异分析

doi:10.11707/j.1001-7488.20160306

摘要/Abstract

摘要： [目的] 研究美洲黑杨杂种F1的基因表达模式,从基因表达水平揭示杂种优势形成机制,为杨树杂种优势的深度开发利用提供有益参考。[方法] 采用Illumina HiSeq 2000高通量测序技术对不同生长势美洲黑杨杂种F1(3个生长势超过双亲、2个生长势低于亲本)及其亲本进行转录组测序和差异比较。[结果] 转录组测序共产生171154127条Reads(平均长度200 bp,约31.32 Gb),将处理后Reads与毛果杨参考基因组数据库比对,有61.89%的Reads可以与参考基因组匹配。超亲杂种F1 Vs亲本中筛选出342个基因显著差异表达(上调表达87个,下调表达255个);低亲杂种F1 Vs亲本共筛选出577个基因差异表达(上调表达146个,下调表达431个);超亲杂种F1 Vs低亲杂种F1中共筛选出486个基因显著差异表达(上调表达200个,下调表达286个)。筛选出377个对杂种优势产生具有重要作用的差异表达基因,其中,有4个差异基因在超亲F1 Vs亲本、低亲F1 Vs亲本及超亲F1 Vs低亲F1中为下调表达; 72个下调表达差异基因在超亲F1 Vs亲本及低亲F1 Vs亲本2个对比组中均显著差异表达;有129个差异基因仅在超亲F1 Vs亲本及超亲F1 Vs低亲F12个对比组中显著表达,包括19个差异基因显著上调表达,110个差异基因显著下调表达;有172个基因仅在低亲F1 Vs亲本及超亲F1 Vs低亲F1中显著差异表达。功能注释及代谢途径分析结果表明,超亲F1 Vs亲本、超亲F1 Vs低亲及低亲F1 Vs亲本3个对比组中分别有167个、233个及280个差异显著基因能被功能注释,分别涉及46个、45个及51个生物学功能,在分子功能、生物学过程、细胞组分3种GO分类中,其中差异基因主要富集在"催化活性"、"胺的代谢过程"及"氧化还原酶活性"等功能中,参与碳水化合物代谢、氨基酸代谢、能量代谢途径及外来物质的降解和代谢途径。[结论] 杂种优势的形成,可能是由于相关基因的显著差异表达,调控光合作用、物质代谢吸收等与生长紧密联系的代谢活动,进而促进生长优势的产生。

关键词: 美洲黑杨, 转录组, 差异表达, 杂种优势

Abstract: [Objective] The study was intended to study the gene expression profile of F1 hybrids of Populus deltoides to reveal the mechanism of hybrid vigor at the gene expression level. [Method] We sequenced the transcriptomes of three super-parent hybrids F1 (H1, H2, H3), two low-parent hybrids (L1, L2), and their parents (Q1, Q2) using high throughput sequencing. [Result] We obtained a total of 171 154 127 reads, with an average length of 200 bp and a total of 31.32 Gb size. After filtering, we aligned the clean reads to the reference genome of Populus trichocarpa and 61.89% of the clean reads could be aligned to the reference genome. The comparison between super-parent hybrids F1 and parents(H Vs Q) revealed that 342 genes were differently expressed (87 up-regulated and 255 down-regulated). We termed the different expressed gene as DEG thereafter. Meanwhile, 577 DEGs (146 up-regulated and 431 down-regulated) were identified by comparing low-parent hybrids F1 with parents(L Vs Q), and 486 DEGs (200 up-regulated and 286 down-regulated) were identified by comparison of low-parent hybrids F1 and super-parent hybrid F1(H Vs L). 377 genes that were highly related to the hybrid vigor were identified, of which 4 genes down-regulated expressed in H Vs Q, L Vs Q and H Vs L, 72 genes down-regulated expressed both in H Vs Q and L Vs Q, 129 genes differentially expressed (19 up-regulated and 110 down-regulated) both in H Vs Q and H Vs L, 170 genes differentially expressed both in L Vs Q and H Vs L. The functional analysis and pathway analysis demonstrated that there were 167, 233 and 288 DGEs could be categorized into 46, 45 and 51 functional groups, respectively. In the three main categories (cellular component, molecular function, and biological process) of the GO classification, the DEGs were mainly enriched in "catalytic activity", "amine metabolic process" and "oxidoreductase activity" etc. These activities were reported to be involved in the carbohydrate metabolism, amino acid metabolism, energy metabolism and degradation pathways and foreign substances metabolic pathways.[Conclusion] Heterosis, probably due to significant different expressions of related genes, regulates metabolic activities closely linked to growth, e.g. photosynthesis, metabolism and absorption, and thus contributes to the formation of growth advantage.

Key words: Populus deltoides, thanscriptome, differential gene expression, hybrid vigor

中图分类号:

S718.46

丁昌俊, 张伟溪, 高暝, 黄秦军, 褚延广, 苏晓华. 不同生长势美洲黑杨转录组差异分析[J]. 林业科学, 2016, 52(3): 47-58.

Ding Changjun, Zhang Weixi, Gao Ming, Huang Qinjun, Chu Yanguang, Su Xiaohua. Analysis of Transcriptome Differences among Populus deltoides with Different Growth Potentials[J]. Scientia Silvae Sinicae, 2016, 52(3): 47-58.

参考文献

程昕昕,耿广汉,刘正. 2007.过氧化物酶杂合性与玉米F1产量性状相关性分析.中国农学通报, 23(2):271-274.
(Cheng X X, Geng G H, Liu Z. 2007. Relationship of peroxidase diversity with Fl yield in maize. Chinese Agricultural Science Bulletin, 23(2):271-274.[in Chinese])
高暝,丁昌俊,苏晓华,等. 2014.美洲黑杨及其杂种F1无性系光合特性的研究.林业科学研究, 27(6):721-728.
(Gao M, Ding C J, Su X H, et al. 2014. Comparison of photosynthetic characteristics of Populus deltoides and their hybrid clones. Forest Research, 27(6):721-728.[in Chinese])
高暝,黄秦军,丁昌俊,等. 2013.美洲黑杨及其杂种F1不同生长势无性系叶片δ¹³C和氮素利用效率.林业科学, 49(8):51-57.
(Gao M, Huang Q J, Ding C J, et al. 2013. Foliar δ¹³C and nitrogen use efficient of Populus deltoides and the different growth vigor F1 hybrid clones. Scientia Silvae Sinicae, 49(8):51-57.[in Chinese])
姜涛,王丕武,张君. 2013.玉米mRNA差异显示与杂种优势关系的研究.玉米科学, 21(5):41-45.
(Jiang T, Wang P W, Zhang J. 2013. Relationship between mRNA differential gene expression and heterosis in maize. Journal of Maize Sciences, 21(5):41-45.[in Chinese])
祁云霞,刘永斌,荣威恒. 2011.转录组研究新技术:RNA-Seq及其应用.遗传, 33(11):1191-1202.
(Qi Y X, Liu Y B, Rong W H. 2011. RNA-Seq and its applications:A new technology for transcriptomics. Hereditas(Beijing), 33(11):1191-1202.[in Chinese])
王晓阳,李火根. 2011.鹅掌楸苗期生长杂种优势的SSR分析.林业科学, 47(4):57-62.
(Wang X Y, Li H G. 2011. Possible mechanism analysis for heterosis of hybrid Liriodendron based on seedling growth and SSR markers. Scientia Silvae Sinicae, 47(4):57-62.[in Chinese])
郑康乐,庄杰云,樊叶杨,等. 1999.杂交水稻产量性状的上位性效应及杂合性与杂种优势的相关性.云南大学学报:自然科学版, (S3):47-48.
(Zheng K L, Zhuang J Y, Fan Y Y, et al. 1999. Correlation of epistatic effects and heterozygosity of yield traits with heterosis in hybrid rice. Journal of Yunnan University:Natural Sciences Edition, (S3):47-48.[in Chinese])
Birchler J A, Auger D L, Riddle N C. 2003. In search of the molecular basis of heterosis. The Plant Cell, 15(10):2236-2239.
Birchler J A, Yao H, Chudalayandi S, et al. 2010. Heterosis. Plant Cell, 22(7):2105-2112.
Bruce A B. 1910. The Mendelian theory of heredity and the augmentation of vigor. Science, 32(827):627-628.
Chen Z J. 2010. Molecular mechanisms of polyploidy and hybrid vigor. Trends in Plant Science, 15(2):57-71.
Gao M, Huang Q J, Chu Y G, et al. 2014. Analysis of the leaf methylomes of parents and their hybrids provides new insight into hybrid vigor in Populus deltoides. BMC Genetics, 15(Suppl 1):S8.
Hebenstreit D, Fang M, Gu M, et al. 2011. RNA sequencing reveals two major classes of gene expression levels in metazoan cells. Molecular Systems Biology, 7:497.
Li A, Fang M, Song W, et al. 2012. Gene expression profiles of two intraspecific Larix lines and their reciprocal hybrids. Molecular Biology Reports, 39(4):3773-3784.
Li A, Liu D, Wu J, et al. 2014. mRNA and small RNA transcriptomes reveal insights into dynamic homoeolog regulation of allopolyploid heterosis in nascent hexaploid wheat. Plant Cell, 26(5):1878-1900.
Mortazavi A, Williams B A, Mccue K, et al. 2008. Mapping and quantifying mammalian transcriptomes by RNA-Seq. Nature Methods, 5(7):621-628.
Shull G H. 1914. Duplicate genes for capsule-form in Bursa bursa-pastoris. Molecular and General Genetics, 12(1):97-149.
Song G, Guo Z, Liu Z, et al. 2013. Global RNA sequencing reveals that genotype-dependent allele-specific expression contributes to differential expression in rice F1 hybrids. BMC Plant Biology, 13(1):221.
Swanson-Wagner R A, Decook R, Jia Y, et al. 2009. Paternal dominance of trans-eQTL influences gene expression patterns in maize hybrids. Science, 326(5956):1118-1120.
Swanson-Wagner R A, Jia Y, Decook R, et al. 2006. All possible modes of gene action are observed in a global comparison of gene expression in a maize F1 hybrid and its inbred parents. Proceedings of the National Academy of Sciences, 103(18):6805-6810.
Zhuang Y, Adams K L. 2007. Extensive allelic variation in gene expression in Populus F1 hybrids. Genetics, 177(4):1987-1996.
Takatsuji H. 1998. Zinc-finger transcription factors in plants. Cellular and Molecular Life Sciences, 54(6):582-596.

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