【 摘 要 】

Background

One of the most important evolutionary processes in plants is polyploidization. The combination of two or more genomes in one organism often initially leads to changes in gene expression and extensive genomic reorganization, compared to the parental species. Hexaploid triticale (x Triticosecale) is a synthetic hybrid crop species generated by crosses between T. turgidum and Secale cereale. Because triticale is a recent synthetic polyploid it is an important model for studying genome evolution following polyploidization. Molecular studies have demonstrated that genomic sequence changes, consisting of sequence elimination or loss of expression of genes from the rye genome, are common in triticale. High-throughput DNA sequencing allows a large number of genes to be surveyed, and transcripts from the different homeologous copies of the genes that have high sequence similarity can be better distinguished than hybridization methods previously employed.

Results

The expression levels of 23,503 rye cDNA reference contigs were analyzed in 454-cDNA libraries obtained from anther, root and stem from both triticale and rye, as well as in five 454-cDNA data sets created from triticale seedling shoot, ovary, stigma, pollen and seed tissues to identify the classes of rye genes silenced or absent in the recent synthetic hexaploid triticale. Comparisons between diploid rye and hexaploid triticale detected 112 rye cDNA contigs (~0.5%) that were totally undetected by expression analysis in all triticale tissues, although their expression was relatively high in rye tissues. Non-expressed rye genes were found to be strikingly less similar to their closest BLASTN matches in the wheat genome or in the other Triticum genomes than a test set of 200 random rye genes. Genes that were not detected in the RNA-seq data were further characterized by testing for their presence in the triticale genome by PCR using genomic DNA as a template.

Conclusion

Genes with low similarity between rye sequences and their closest matches in the Triticum genome have a higher probability to be repressed or absent in the allopolyploid genome.

【 授权许可】

   
2015 Khalil et al.; licensee BioMed Central.

【 预 览 】

附件列表

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【 图 表 】

【 参考文献 】

• [1]Lysak M, Berr A, Pecinka A, Schmidt R, McBreen K, Schubert I: Mechanisms of chromosome number reduction in Arabidopsis thaliana and related Brassicaceae species. Proc Natl Acad Sci 2006, 103:5224-9.
• [2]Madlung A, Tyagi AP, Watson B, Jiang H, Kagochi T, Doerge RW, et al.: Genomic changes in synthetic Arabidopsis polyploids. Plant J 2005, 41:221-30.
• [3]Lee H-S, Chen ZJ: Protein-coding genes are epigenetically regulated in Arabidopsis polyploids. Proc Natl Acad Sci U S A 2001, 98:6753-8.
• [4]Renny-Byfield S, Kovarik A, Kelly LJ, Macas J, Novak P, Chase MW, et al.: Diploidization and genome size change in allopolyploids is associated with differential dynamics of low- and high-copy sequences. Plant J 2013, 74:829-39.
• [5]Chalupska D, Lee HY, Faris JD, Evrard A, Chalhoub B, Haselkorn R, et al.: Acc homoeoloci and the evolution of wheat genomes. Proc Natl Acad Sci U S A 2008, 105:9691.
• [6]Feldman M, Liu B, Segal G, Abbo S, Levy AA, Vega JM: Rapid elimination of low-copy DNA sequences in polyploid wheat: a possible mechanism for differentiation of homoeologous chromosomes. Genetics 1997, 147:1381-7.
• [7]Song K, Lu P, Tang K, Osborn TC: Rapid genome change in synthetic polyploids of Brassica and its implications for polyploid evaluation. Proc Natl Acad Sci 1995, 92:7719-23.
• [8]Kashkush K, Feldman M, Levy AA: Gene loss, silencing and activation in a newly synthesized wheat allotetraploid. Genetics 2002, 160:1651-9.
• [9]Brubaker CL, Paterson AH, Wendel JF: Comparative genetic mapping of allotetraploid cotton and its diploid progenitors. Genome 1999, 42:184-203.
• [10]Maestra B, Naranjo T: Structural chromosome differentiation between Triticum timopheevii and T. turgidum and T. aestivum. Theor Appl Genet 1999, 98:744-50.
• [11]Feldman M, Levy AA: Genome evolution in allopolyploid wheat: a revolutionary reprogramming followed by gradual changes. J Genet & Genomics 2009, 36:511-8.
• [12]Tate JA, Joshi P, Soltis KA, Soltis PS, Soltis DE: On the road to diploidization? Homoeolog loss in independently formed populations of the allopolyploid Tragopogon miscellus (Asteraceae). BMC Plant Biol 2009, 9:80. BioMed Central Full Text
• [13]Koh J, Soltis PS, Soltis DE: Homeolog loss and expression changes in natural populations of the recently and repeatedly formed allotetraploid Tragopogon mirus (Asteraceae). BMC Genomics 2010, 11:97. BioMed Central Full Text
• [14]Adams KL, Percifield R, Wendel JF: Organ-specific silencing of duplicated genes in a newly synthesized cotton allotetraploid. Genetics 2004, 168:2217-26.
• [15]Feldman M, Levy AA, Fahima T, Korol A: Genomic asymmetry in allopolyploid plants: wheat as a model. J Exp Bot 2012, 14:5045-59.
• [16]Eilam T, Anikster Y, Millet E, Manisterski J, Feldman M: Nuclear DNA amount and genome downsizing in natural and synthetic allopolyploids of the genera Aegilops and Triticum. Genome 2008, 51:616-27.
• [17]Eilam T, Anikster Y, Millet E, Manisterski J, Feldman M: Genome size in natural and synthetic autopolyploids and in a natural segmental allopolyploid of several Triticeae species. Genome 2009, 52(3):275-85.
• [18]Mergoum M, Singh PK, Pena RJ, Lozano del Rio AJ, Cooper KV, Salmon DF, et al.: Triticale: a ‘new’ crop with old challenges. In Cereals. 3rd edition. Edited by Carena MJ. Springer, New York; 2009:267-90.
• [19]Boyko EV, Badaev NS, Maximov NG, Zelenin AV: Regularities of genome formation and organization in cereals: I. DNA quantitative changes in the process of allopolyploidization. Genetika 1988, 24:89-97.
• [20]Bennett MD, Leitch IJ: Nuclear DNA amounts in angiosperms: targets, trends and tomorrow. Annal Bot 2011, 107:467-590.
• [21]Ma XF, Gustafson JP: Timing and rate of genome variation in triticale following alloploidization. Genome 2006, 49(8):950-8.
• [22]Comai L: Genetic and epigenetic interactions in allopolyploid plants. Plant Mol Biol 2000, 43:387-99.
• [23]Ma X-F, Fang P, Gustafson JP: Polyploidization-induced genome variation in triticale. Genome 2004, 47:839-48.
• [24]Akunova AR, Matniyazov RT, Liang HQ, Akhunov ED: Homoeolog-specific transcriptional bias in allopolyploid wheat. BMC Genomic 2010, 11:505. BioMed Central Full Text
• [25]Tran F, Penniket C, Patel RV, Provart NJ, Laroche A, Rowland O, et al.: Developmental transcriptional profiling reveals key insights into Triticeae reproductive development. Plant J 2013, 74:971-88.
• [26]Zadoks JC, Chang TT, Konzak CF: A Decimal Code for the Growth Stages of Cereals. Weed Res 1974, 14:415-21.
• [27]Khalil HB, Brunetti SC, Pham UM, Maret D, Laroche A, Gulick PJ: Characterization of the caleosin gene family in the Triticeae. BMC Genomics 2014, 15:239. BioMed Central Full Text
• [28]Blankenberg D, Gordon A, Von Kuster G, Coraor N, Taylor J, Nekrutenko A, et al.: Manipulation of FASTQ data with Galaxy. Bioinformatics 2010, 26(14):1783-5.
• [29]Goecks J, Nekrutenko A, Taylor J: Galaxy: a comprehensive approach for supporting accessible, reproducible, and transparent computational research in the life sciences. Genome Biol 2010, 11:86. BioMed Central Full Text
• [30]Li H, Durbin R: Fast and accurate short read alignment with Burrows-Wheeler Transform. Bioinformatics 2009, 25:1754-60.
• [31]International Wheat Genome Sequencing Consortium: A chromosome-based draft sequenceof the hexaploid bread wheat (Triticum aestivum) genome Science 2014, 345:1251788.
• [32]Conesa A, Götz S, García-Gómez J, Terol J, Talón M, Robles M: Blast2GO: a universal tool for annotation, visualization and analysis in functional genomics research. Bioinformatics 2005, 21:3674-6.
• [33]Doyle JJ, Doyle JL: A rapid DNA isolation procedure for small quantities of fresh leaf tissue. Phytochemistry 1987, 19:11-5.
• [34]Ridha-Farajalla R, Gulick PJ: The alpha-tubulin gene family in wheat (Triticum aestivum L.) and differential gene expression during cold acclimation. Genome 2007, 50:502-10.
• [35]Ling H-Q, Zhao S, Liu D, Wang J, Sun H, Zhang C, et al.: Draft genome of the wheat A-genome progenitor Triticum urartu. Nature 2013, 496:87-90.
• [36]Jia J, Zhao S, Kong X, Li Y, Zhao G, He W, et al.: Aegilops tauschii draft genome sequence reveals a gene repertoire for wheat adaptation. Nature 2013, 496:91-5.
• [37]Cannon SB, Mitra A, Baumgarten A, Young ND, May G: The roles of segmental and tandem gene duplication in the evolution of large gene families in Arabidopsis thaliana. BMC Plant Biol 2004, 4:10. BioMed Central Full Text
• [38]Nobuta K, Ashfield T, Kim S, Innes RW: Diversification of non-TIR class NB-LRR genes in relation to whole-genome duplication events in Arabidopsis. Mol Plant Microbe Interact 2005, 18:103-9.
• [39]Zhang X, Feng Y, Cheng H, Tian D, Yang S, Chen JQ: Relative evolutionary rates of NBS-encoding genes revealed by soybean segmental duplication. Mol Genet Genomics 2011, 285:79-90.
• [40]Ozkan H, Levy AA, Feldman M: Allopolyploidy-induced rapid genome evolution in the wheat (Aegilops–Triticum) group. Plant Cell 2001, 13:1735-47.
• [41]Ma X-F, Fang P, Gustafson JP: Allopolyploidization-accomodated Genomic Sequence Changes in Triticale. Ann Bot 2008, 101:825-32.
• [42]Shaked H, Kashkush K, Ozkan H, Feldman M, Levy AA: Sequence eliminations and cytosine methylation are rapid and reproducible responses of the genome to wide hybridization and allopolyploidy in wheat. Plant Cell 2001, 13:1749-59.
• [43]Chantret N, Salse J, Sabot F, Rahman S, Bellec A, Laubin B, et al.: Molecular basis of evolutionary events that shaped the hardness locus in diploid and polyploid wheat species (Triticum and Aegilops). Plant Cell 2005, 17:1033-45.
• [44]Li W, Li H, Gill BS: Recurrent Deletions of Puroindoline Genes at the Grain Hardness Locus in Four Independent Lineages of Polyploid Wheat. Plant Physiol 2008, 146:200-12.
• [45]Gaeta RT, Chris Pires J: Homoeologous recombination in allopolyploids: the polyploid ratchet. New Phytol 2010, 186:18-28.
• [46]Zhao XP, Si Y, Hanson RE, Crane CF, Price JH, Stelly DM, et al.: Dispersed repetitive DNA spread to new genomes since polyploid formation in cotton. Genome Res 1998, 8:479-92.
• [47]Parisod C, Salmon A, Zerjal T, Tenaillon M, Grandbastien MA, Ainouche ML: Rapid structural and epigenetic reorganization near transposable elements in hybrid and allopolyploid genomes in Spartina. New Phytol 2009, 184:1003-15.
• [48]Kirkpatrick DT, Petes TD: Repair of DNA loops involves DNA mismatch and nucleotide excision repair proteins. Nature 1997, 387:929-31.
• [49]Kearney HM, Kirkpatrick DT, Gerton JL, Petes TD: Meiotic recombination involving heterozygous large insertions in Saccharomyces cerevisiae: formation and repair of large, unpaired DNA loops. Genetics 2001, 158:1457-76.
• [50]Belyayev A, Raskina A, Korol A, Nevo E: Coevolution of A and B genomes in allotetraploid Triticum dicoccoides. Genome 2002, 43:1021-6.
• [51]Levy AA, Feldman M: The impact of polyploidy on grass genome evolution. Plant Physiol 2002, 130:1587-93.