Transcriptome analysis of rice root heterosis by RNA-Seq

详细信息    查看全文

• 作者：Rongrong Zhai (1)
  Yue Feng (1)
  Huimin Wang (2)
  Xiaodeng Zhan (1)
  Xihong Shen (1)
  Weiming Wu (1)
  Yingxin Zhang (1)
  Daibo Chen (1)
  Gaoxing Dai (3)
  Zhanlie Yang (4)
  Liyong Cao (1)
  Shihua Cheng (1)
  
• 关键词：Heterosis ; Root ; Transcriptome ; RNA ; Seq ; Hybrid rice
• 刊名：BMC Genomics
• 出版年：2013
• 出版时间：December 2013
• 年：2013
• 卷：14
• 期：1
• 全文大小：615KB
• 参考文献：1. Cheng SH, Zhuang JY, Fan YY, Du JH, Cao LY: Progress in research and development on hybrid rice: a super-domesticate in China. / Ann Bot 2007, 100:959鈥?66. CrossRef
  2. Davenport CB: Degeneration, albinism and inbreeding. / Science 1908, 28:454. CrossRef
  3. Bruce AB: The mendelian theory of heredity and the augmentation of vigor. / Science 1910, 32:627鈥?28. CrossRef
  4. East EM: Inbreeding in corn. / Rep Connecticut Agric Exp Stn 1907 1908, 419鈥?28.
  5. Shull GH: The composition of a field of maize. / Am Breed Assoc Rep 1908, 4:296鈥?01.
  6. Hochholdinger F, Hoecker N: Towards the molecular basis of heterosis. / Trends Plant Sci 2007, 12:427鈥?32. CrossRef
  7. Wang J, Tian L, Lee HS, Wei NE, Jiang H, Watson B, Madlung A, Osborn TC, Doerge R, Comai L, / et al.: Genomewide nonadditive gene regulation in Arabidopsis allotetraploids. / Genetics 2006, 172:507鈥?17. CrossRef
  8. Fujimoto R, Taylor JM, Shirasawa S, Peacock WJ, Dennis ES: Heterosis of Arabidopsis hybrids between C24 and Col is assiciated with increased photosynthesis capacity. / Proc Natl Acad Sci 2012, 109:7109鈥?114. CrossRef
  9. Thiemann A, Fu J, Schrag TA, Melchinger AE, Frisch M, Scholten S: Correlation between parental transcriptome and field data for the characterization of heterosis in Zea mays L. / Theor Appl Genet 2010, 120:401鈥?13. CrossRef
  10. Ge X, Chen W, Song S, Wang W, Hu S, Yu J: Transcriptomic profiling of mature embryo from an elite super-hybrid rice LYP9 and its parental lines. / BMC Plant Biol 2008, 8:114. CrossRef
  11. Song GS, Zhai HL, Peng YG, Zhang L, Wei G, Chen XY, Xiao YG, Wang L, Chen YJ, Wu B, / et al.: Comparative transcriptional profiling and preliminary study on heterosis mechanism of super-hybrid rice. / Mol Plant 2010, 3:1012鈥?025. CrossRef
  12. Wei G, Tao Y, Liu G, Chen C, Luo R, Xia H, Gan Q, Zeng H, Lu Z, Han Y, / et al.: A transcriptomic analysis of superhybrid rice LYP9 and its parents. / Proc Natl Acad Sci 2009, 106:7695鈥?701. CrossRef
  13. Tirosh I: A yeast hybrid provides insight into the evolutiona of gene expression regulation. / Science 2009, 324:659鈥?62. CrossRef
  14. Zhang X, Borevitz JO: Global analysis of allele-specific expression in Arabidopsis thaliana. / Genetics 2009, 182:943鈥?54. CrossRef
  15. Kyndt T, Denil S, Haegeman A, Trooskens G, De Meyer T, Van Criekinge W, Gheysen G: Transcriptome analysis of rice mature root tissue and root tips in early development by massive parallel sequencing. / J Exp Bot 2012, 63:2141鈥?157. CrossRef
  16. Wang Z, Gerstein M, Snyder M: RNA-Seq: a revolutionary tool for transcriptomics. / Nat Rev Genet 2009, 10:57鈥?3. CrossRef
  17. Oono Y, Kawahara Y, Kanamori H, Mizuno H, Yamagata H, Yamamoto M, Hosokawa S, Ikawa H, Akahane I, Zhu Z, / et al.: mRNA-Seq reveals a comprehensive transcriptome profile of rice under phosphate stress. / Rice 2011, 4:50鈥?5. CrossRef
  18. He G, Zhu X, Elling AA, Chen L, Wang X, Guo L, Liang M, He H, Zhang H, Chen F, / et al.: Global epigenetic and transcriptional trends among two rice subspecies and their reciprocal hybrids. / Plant Cell 2010, 22:17鈥?3. CrossRef
  19. Lu T, Lu G, Fan D, Zhu C, Li W, Zhao Q, Feng Q, Zhao Y, Guo Y, Huang X, / et al.: Function annotation of the rice transcriptome at single-nucleotide resolution by RNA-seq. / Genome Res 2010, 20:1238鈥?249. CrossRef
  20. Zhang G, Guo G, Hu X, Zhang Y, Li Q, Li R, Zhuang R, Lu Z, He Z, Fang X, / et al.: Deep RNA sequencing at single base-pair resolution reveals high complexity of the rice transcriptome. / Genome Res 2010, 20:646鈥?54. CrossRef
  21. Mizuno H, Kawahara Y, Sakai H, Kanamori H, Wakimoto H, Yamagata H, Oono Y, Wu J, Ikawa H, Itoh T, Matsumoto T: Massive parallel sequencing of mRNA in identification of unannotated salinity stress-inducible transcripts in rice (Oryza sativa L.). / BMC Genomics 2010, 11:683. CrossRef
  22. Hoecker N, Keller B, Piepho HP, Hochholdinger F: Manifestation of heterosis during early maize (Zea mays L.) root development. / Theor Appl Genet 2005, 112:421鈥?29. CrossRef
  23. Meyer RC: Heterosis of biomass production in Arabidopsis. Establishment during early development. / Plant Physiol 2004, 134:1813鈥?823. CrossRef
  24. Bao JY, Lee S, Chen C, Zhang XQ, Zhang Y, Liu SQ, Clark T, Wang J, Cao ML, Yang HM: Serial analysis of gene expression study of a hybrid rice strain (LYP9) and its parental cultivars. / Plant Physiol 2005, 138:1216鈥?231. CrossRef
  25. Wang Z, Ni Z, Wu H, Nie X, Sun Q: Heterosis in root development and differential gene expression between hybrids and their parental inbreds in wheat (Triticum aestivum L.). / Theor Appl Genet 2006, 113:1283鈥?294. CrossRef
  26. Yao Y, Ni Z, Zhang Y, Chen Y, Ding Y, Han Z, Liu Z, Sun Q: Identification of differentially expressed genes in leaf and root between wheat hybrid and its parental inbreds using PCR-based cDNA subtraction. / Plant Mol Biol 2005, 58:367鈥?84. CrossRef
  27. Paschold A, Marcon C, Hoecker N, Hochholdinger F: Molecular dissection of heterosis manifestation during early maize root development. / Theor Appl Genet 2009, 120:383鈥?88. CrossRef
  28. Cheng SH, Cao LY, Zhuang JY, Chen SG, Zhan XD, Fan YY, Zhu DF, Min SK: Super hybrid rice breeding in China:achievements and prospects. / J Integr Plant Biol 2007, 49:805鈥?10. CrossRef
  29. Pickett AA: Hybrid wheat: results and problems. / Adv Plant Breed, Suppl J Plant Breed 1993, 15:1鈥?59.
  30. Ye J, Fang L, Zheng H, Zhang Y, Chen J, Zhang Z, Wang J, Li S, Li R, Bolund L, / et al.: WEGO: a web tool for plotting GO annotations. / Nucleic Acids Res 2006, 34:293鈥?97. CrossRef
  31. Zhang HY, He H, Chen LB, Li L, Liang MZ, Wang XF, Liu XG, He GM, Chen RS, Ma LG, / et al.: A genome-wide transcription analysis reveals a close correlation of promoter INDEL polymorphism and heterotic gene expression in rice hybrids. / Mol Plant 2008, 1:720鈥?31. CrossRef
  32. Wang D, Pan Y, Zhao X, Zhu L, Fu B, Li Z: Genome-wide temporal-spatial gene expression profiling of drought responsiveness in rice. / BMC Genomics 2011, 12:149. CrossRef
  33. Jackson MB: / New Root Formation in Plants and Cuttings. Martinus Nijhoff Press, Netherland; 1986. CrossRef
  34. Sharp RE, Silk WK, Hsiao TC: Growth of the maize primary root at low water potentials: I. Spatial distribution of expansive growth. / Plant Physiol 1988, 87:50鈥?7. CrossRef
  35. Rodriguez HG, Roberts JKM, Jordan WR, Drew MC: Growth, water relations, and accumulation of organic and inorganic solutes in roots of maize seedlings during salt stress. / Plant Physiol 1997, 113:881鈥?93.
  36. Ogawa A, Yamauchi A: Root osmotic adjustment under osmotic stress in maize seedlings. 2. Mode of accumulation of several solutes for osmotic adjustment in the root. / Plant Prod Sci 2006, 9:39鈥?6. CrossRef
  37. Jiang K, Zhang S, Lee S, Tsai G, Kim K, Huang H, Chilcott C, Zhu T, Feldman LJ: Transcription profile analyses identify genes and pathways central to root cap functions in maize. / Plant Mol Biol 2006, 60:343鈥?63. CrossRef
  38. Ogawa A, Ando F, Toyofuku K, Kawashima C: Sucrose metabolism for the development of seminal root in maize seedlings. / Plant Prod Sci 2009, 12:9鈥?6. CrossRef
  39. Cho JI, Kim HB, Kim CY, Hahn TR, Jeon JS: Identification and characterization of the duplicate rice sucrose synthase genes OsSUS5 and OsSUS7 which are associated with the plasma membrane. / Mol Cells 2011, 31:553鈥?61. CrossRef
  40. Hirose T, Scofield GN, Terao T: An expression analysis profile for the entire sucrose synthase gene family in rice. / Plant Sci 2008, 174:534鈥?43. CrossRef
  41. Zhang Y, Xiao W, Luo L, Pang J, Rong W, He C: Downregulation of OsPK1, a cytosolic pyruvate kinase, by T-DNA insertion causes dwarfism and panicle enclosure in rice. / Planta 2011, 235:25鈥?8. CrossRef
  42. Konishi H, Yamane H, Maeshima M, Komatsu S: Characterization of fructose-bisphosphate aldolase regulated by gibberellin in roots of rice seedling. / Plant Mol Biol 2004, 56:839鈥?48. CrossRef
  43. O鈥機arra P, Mulcahy P: Lactate dehydrogenase in plants: distribution and function. / Phytochemistry 1996, 42:581鈥?87. CrossRef
  44. Menegus F, Cattaruzza L, Chersi A, Fronza G: Differences in the anaerobic lactate-succinate production and in the changes of cell sap pH for plants with high and low resistance to anoxia. / Plant Physiol 1989, 90:29鈥?2. CrossRef
  45. Hoffman NE, Bent AF, Hanson AD: Induction of lactate dehydrogenase isozymes by oxygen deficit in barley root tissue. / Plant Physiol 1986, 82:658鈥?63. CrossRef
  46. Dolferus R, Ellis M, De Bruxelles G, Trevaskis B, Hoeren F, Dennis E, Peacock W: Strategies of gene action in Arabidopsis during hypoxia. / Ann Bot 1997, 79:21鈥?1. CrossRef
  47. Laszlo A, St. Lawrence P: Parallel induction and synthesis of PDC and ADH in anoxic maize roots. / Mol Gen Genet 1983, 192:110鈥?17. CrossRef
  48. Farrokhi N, Burton RA, Brownfield L, Hrmova M, Wilson SM, Bacic A, Fincher GB: Plant cell wall biosynthesis: genetic, biochemical and functional genomics approaches to the identification of key genes. / Plant Biotechnol J 2006, 4:145鈥?67. CrossRef
  49. Somerville C, Bauer S, Brininstool G, Facette M, Hamann T, Milne J, Osborne E, Paredez A, Persson S, Raab T: Toward a systems approach to understanding plant cell walls. / Science 2004, 306:2206鈥?211. CrossRef
  50. Kim CM, Park SH, Je BI, Park SJ, Piao HL, Eun MY, Dolan L, Han C: OsCSLD1, a cellulose synthase-like D1 gene, is required for root hair morphogenesis in rice. / Plant Physiol 2007, 143:1220鈥?230. CrossRef
  51. Wang X, Cnops G, Vanderhaeghen R, De Block S, Van Montagu M, Van Lijsebettens M: AtCSLD3, a cellulose synthase-like gene important for root hair growth in Arabidopsis. / Plant Physiol 2001, 126:575鈥?86. CrossRef
  52. Zhang JW, Xu L, Wu YR, Chen XA, Liu Y, Zhu SH, Ding WN, Wu P, Yi KK: OsGLU3, a putative membrane-bound endo-1,4-beta-glucanase, is required for root cell elongation and division in rice (Oryza sativa L.). / Mol Plant 2012, 5:176鈥?86. CrossRef
  53. Guo D, Liang J, Li L: Abscisic acid (ABA) inhibition of lateral root formation involves endogenous ABA biosynthesis in Arachis hypogaea L. / Plant Growth Regul 2009, 58:173鈥?79. CrossRef
  54. De Smet I, Signora L, Beeckman T, Inz茅 D, Foyer CH, Zhang H: An abscisic acid-sensitive checkpoint in lateral root development of Arabidopsis. / Plant J 2003, 33:543鈥?55. CrossRef
  55. Cohen D, Bogeat-Triboulot MB, Tisserant E, Balzergue S, Martin-Magniette ML, Lelandais G, Ningre N, Renou JP, Tamby JP, Thiec DL, / et al.: Comparative transcriptomics of drought responses in Populus: a meta-analysis of genome-wide expression profiling in mature leaves and root apices across two genotypes. / BMC Genomics 2010, 11:630. CrossRef
  56. Santiago J, Dupeux F, Round A, Antoni R, Park SY, Jamin M, Cutler SR, Rodriguez PL, M谩rquez JA: The abscisic acid receptor PYR1 in complex with abscisic acid. / Nature 2009, 462:665鈥?68. CrossRef
  57. Santiago J, Rodrigues A, Saez A, Rubio S, Antoni R, Dupeux F, Park SY, M谩rquez JA, Cutler SR, Rodriguez PL: Modulation of drought resistance by the abscisic acid receptor PYL5 through inhibition of clade A PP2Cs. / Plant J 2009, 60:575鈥?88. CrossRef
  58. Li X, Mo X, Shou H, Wu P: Cytokinin-mediated cell cycling arrest of pericycle founder cells in lateral root initiation of Arabidopsis. / Plant Cell Physiol 2006, 47:1112鈥?123. CrossRef
  59. Lee DJ, Kim S, Ha YM, Kim J: Phosphorylation of Arabidopsis response regulator 7 (ARR7) at the putative phospho-accepting site is required for ARR7 to act as a negative regulator of cytokinin signaling. / Planta 2007, 227:577鈥?87. CrossRef
  60. Rabin R, Stewart V: Dual response regulators (NarL and NarP) interact with dual sensors (NarX and NarQ) to control nitrate-and nitrite-regulated gene expression in Escherichia coli K-12. / J Bacteriol 1993, 175:3259鈥?268.
  61. Li J, Swanson RV, Simon MI, Weis RM: The response regulators CheB and CheY exhibit competitive binding to the kinase CheA. / Biochemistry 1995, 34:14626鈥?4636. CrossRef
  62. Sourjik V, Schmitt R: Phosphotransfer between CheA, CheY1, and CheY2 in the chemotaxis signal transduction chain of Rhizobium meliloti. / Biochemistry 1998, 37:2327鈥?335. CrossRef
  63. To JPC, Deruere J, Maxwell BB, Morris VF, Hutchison CE, Ferreira FJ, Schaller GE, Kieber JJ: Cytokinin regulates type-A Arabidopsis response regulator activity and protein stability via two-component phosphorelay. / Plant Cell 2007, 19:3901鈥?914. CrossRef
  64. Mason MG: Multiple type-B response regulators mediate cytokinin signal transduction in Arabidopsis. / Plant Cell 2005, 17:3007鈥?018. CrossRef
  65. Tsai YC, Weir NR, Hill K, Zhang W, Kim HJ, Shiu SH, Schaller GE, Kieber JJ: Characterization of genes involved in cytokinin signaling and metabolism from rice. / Plant Physiol 2012, 158:1666鈥?684. CrossRef
  66. Chen YL: / QTL for Traits Related with Potassium Deficiency Resistance in Rice. Chinese academy of sciences master dissertation, Beijing, China; 2012.
  67. Liang YS: / Genetic Research on Root of Populations Derived from Super Rice (Oryza sativa L.) Xieyou 9308. Chinese academy of sciences doctoral dissertation, Beijing, China; 2011.
  68. Feng Y, Cao LY, Wu WM, Shen XH, Zhan XD, Zhai RR, Wang RC, Chen DB, Cheng SH: Mapping QTLs for nitrogen-deficiency tolerance at seedling stage in rice (Oryza sativa L.). / Plant Breeding 2010, 129:652鈥?56. CrossRef
  69. Feng Y: / Genetic Analysis and QTL Mapping on the Response of A Super Rice XY9308 RIL Population to Nitrogen Levels. Shenyang agricultural university doctoral dissertation, Shenyang, China; 2010.
  70. Wang RC: / QTLMapping of Phosphorus Deficiency Tolerance in Rice (Oryza sativa L.) at Two Development Stages. Chinese academy of sciences master dissertation, Beijing, China; 2009.
  71. Shen XH: / RIL Construction and QTL Mapping for Some Traits of Super Hybrid Rice (Oryza sativa L.) XY9308. Chinese academy of sciences doctoral dissertation, Beijing, China; 2008.
  72. Springer NM, Stupar RM: Allelic variation and heterosis in maize: How do two halves make more than a whole? / Genome Res 2007, 17:264鈥?75. CrossRef
  73. Li B, Dewey CN: RSEM: accurate transcript quantification from RNA-Seq data with or without a reference genome. / BMC Bioinformatics 2011, 12:323. CrossRef
  74. Robinson MD, McCarthy DJ, Smyth GK: edgeR: a Bioconductor package for differential expression analysis of digital gene expression data. / Bioinformatics 2010, 26:139鈥?40. CrossRef
  75. Mortazavi A, Williams BA, McCue K, Schaeffer L, Wold B: Mapping and quantifying mammalian transcriptomes by RNA-Seq. / Nat Methods 2008, 5:621鈥?28. CrossRef
  76. Griffing B: Use of a controlled-nutrient experiment to test heterosis hypotheses. / Genetics 1990, 126:753鈥?67.
  77. Kearsey MJ, Pooni HS: / The Genetical Analysis of Quantitative Traits. Chapman & Hall Press, London; 1996.
  78. Lynch M, Walsh B: / Genetics Analysis of Quantitative Traits. Sinauer Associates Press, Sunderland; 1998.
  79. Vuylsteke M, Van Eeuwijk F, Van Hummelen P, Kuiper M, Zabeau M: Genetic analysis of variation in gene expression in Arabidopsis thaliana. / Genetics 2005, 171:1267鈥?275. CrossRef
  80. Eisen MB, Spellman PT, Brown PO, Botstein D: Cluster analysis and display of genome-wide expression patterns. / Proc Natl Acad Sci 1998, 95:14863鈥?4868. CrossRef
  
• 作者单位：Rongrong Zhai (1)
  Yue Feng (1)
  Huimin Wang (2)
  Xiaodeng Zhan (1)
  Xihong Shen (1)
  Weiming Wu (1)
  Yingxin Zhang (1)
  Daibo Chen (1)
  Gaoxing Dai (3)
  Zhanlie Yang (4)
  Liyong Cao (1)
  Shihua Cheng (1)
  
  1. State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou, 310006, China
  2. College of Agronomy, Shenyang Agricultural University, Shenyang, 110161, China
  3. Rice Research Institute, Guangxi Academy of Agricultural Sciences, Nanning, 530007, China
  4. Rice Research Institute, Guizhou Academy of Agricultural Sciences, Guiyang, 550006, China
  

文摘

Background Heterosis is a phenomenon in which hybrids exhibit superior performance relative to parental phenotypes. In addition to the heterosis of above-ground agronomic traits on which most existing studies have focused, root heterosis is also an indispensable component of heterosis in the entire plant and of major importance to plant breeding. Consequently, systematic investigations of root heterosis, particularly in reproductive-stage rice, are needed. The recent advent of RNA sequencing technology (RNA-Seq) provides an opportunity to conduct in-depth transcript profiling for heterosis studies. Results Using the Illumina HiSeq 2000 platform, the root transcriptomes of the super-hybrid rice variety Xieyou 9308 and its parents were analyzed at tillering and heading stages. Approximately 391 million high-quality paired-end reads (100-bp in size) were generated and aligned against the Nipponbare reference genome. We found that 38,872 of 42,081 (92.4%) annotated transcripts were represented by at least one sequence read. A total of 829 and 4186 transcripts that were differentially expressed between the hybrid and its parents (DGHP) were identified at tillering and heading stages, respectively. Out of the DGHP, 66.59% were down-regulated at the tillering stage and 64.41% were up-regulated at the heading stage. At the heading stage, the DGHP were significantly enriched in pathways related to processes such as carbohydrate metabolism and plant hormone signal transduction, with most of the key genes that are involved in the two pathways being up-regulated in the hybrid. Several significant DGHP that could be mapped to quantitative trait loci (QTLs) for yield and root traits are also involved in carbohydrate metabolism and plant hormone signal transduction pathways. Conclusions An extensive transcriptome dataset was obtained by RNA-Seq, giving a comprehensive overview of the root transcriptomes at tillering and heading stages in a heterotic rice cross and providing a useful resource for the rice research community. Using comparative transcriptome analysis, we detected DGHP and identified a group of potential candidate transcripts. The changes in the expression of the candidate transcripts may lay a foundation for future studies on molecular mechanisms underlying root heterosis.