Abstract
Two contrasting genome-specific DNA sequences were isolated from Aegilops speltoides (wild goat grass) and Hordeum chilense (wild barley), each representing more than 1 % of the genomes. These repetitive DNA fragments were identified as being genome-specific before cloning by genomic Southern hybridization (using total genomic DNA as a probe), and hence extensive screening of clones was not required. For each fragment, up to six recombinant plasmid clones were screened and about half were genome-specific. Clone pAesKB52 from Ae. speltoides was a 763 by EcoRI fragment, physically organized in simple tandem repeats and shown to localize to sub-telomerec chromosome regions of species with the Triticeae S-genome by in situ hybridization to chromosomes. The sequence data showed an internal duplication of some 280 bp, which presumably occurred before sequence amplification and dispersion, perhaps by unequal crossing-over or reciprocal translocation. In situ hybridization showed that the sequence distribution varied between closely related (S-genome) species. Clone pHcKB6 was a 339 by DraI fragment from H. chilense, also tandemly repeated but more variable; loss of the DraI site resulting in a ladder pattern in Southern blots which had little background smear. In situ hybridization showed that the tandem repeats were present as small clusters dispersed along all chromosome arms except at a few discrete regions including the centromeres and telomeres. The clone hybridized essentially specifically to the H-genome of H. chilense and hence was able to identify the origin of chromosomes in a H. chilense x Secale africanum hybrid by in situ hybridization. It has a high A + T content (66%), small internal duplications, and a 50 by degenerate inverted repeat. We speculate that it has dispersed by retrotransposition in association with other sequences carrying coding domains. The organization and evolution of such sequences are important in understanding long-range genome organization and the types of change that can occur on evolutionary and plant breeding timescales. Genome-specific sequences are also useful as markers for alien chromatin in plant breeding.
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References
Albini SM, Schwarzacher T (1992) In situ localization of two repetitive DNA sequences to surface-spread pachytene chromosomes of rye. Genome 35:551–559
Anamthawat-Jónsson K, Schwarzacher T, Leitch AR, Bennett MD, Heslop-Harrison JS (1990) Discrimination between closely related Triticeae species using genomic DNA as a probe. Theor Appl Genet 79:721–728
Anamthawat-Jónsson K (1992) Molecular cytogenetics and nuclear organization in the Triticeae. PhD Thesis, University of Cambridge, UK
Appels R, Dennis ES, Smyth DR, Peacock WJ (1981) Two repeated DNA sequences from the heterochromatic regions of rye (Secale cereale) chromosomes. Chromosoma 84:265–277
Appels R, Moran LB, Gustafson JP (1986) Rye heterochromatin. I. Studies on clusters of the major repeating sequence and the identification of a new dispersed repetitive sequence element. Can J Genet Cytol 28:645–657
Berry ST, Owen MRL, Draper J (1988) DNA probes to alien genetic material in wheat using selective DNA enrichment. In: Miller TE, Koebner RMB (eds) Proceedings 7th International Wheat Genetic Symposium. Institute of Plant Science Research, Cambridge, pp 483–488
Clarke B, Stancombe P, Money T, Foote T, Moore G (1992) Targeting deletion (homoeologous chromosome pairing locus) or addition line single copy sequences from cereal genomes. Nucleic Acids Res 20:1289–1292
Cook D, Sequeira L (1991) The use of subtractive hybridization to obtain a DNA probe specific for Pseudomonas solanacearum race 3. Mol Gen Genet 227:401–410
Devos K, Atkinson MD, Chinoy CN, Harcourt RL, Koebner RMD, Liu CJ, Masojc P, Xie DX, Gale MD (1993) Chromosome rearrangements in the rye genome relative to that of wheat. Theor Appl Genet 85:673–680
Finch RA, Bennett MD (1980) Mitotic and meiotic chromosome behaviour in new hybrids of Hordeum with Triticum and Secale. Heredity 44:201–209
Flavell RB, O'Dell M, Hutchinson J (1981) Nucleotide sequence organization in plant chromosomes and evidence for sequence translocation during evolution. Cold Spring Harbor Symp Quant Biol 45:501–508
Grandbastien M-A (1992) Retroelements in higher plants. Trends Genet 8:103–108
Grotewold E, Athma P, Peterson T (1991) A possible hot spot for Ac insertion in the maize P gene. Mol Gen Genet 230:329–331
Junghans H, Metzlaff M (1988) Genome specific, highly repetitive repeated sequences of Hordeum vulgare: cloning, sequencing and squash dot test. Theor Appl Genet 76:728–732
Le HT, Armstrong KC (1991) In situ hybridization as a rapid means to assess meiotic pairing and detection of alien DNA transfers in interphase cells of wide crosses involving wheat and rye. Mol Gen Genet 225:33–37
Leitch AR, Schwarzacher T, Wang ML, Leitch IJ, Sulan-Momirovich G, Moore G, Heslop-Harrison JS (1993) Molecular cytogenetic analysis of repeated sequences in a long term wheat suspension culture. Plant Cell Tiss Org Cult, in press
McIntyre CL, Pereira S, Moran LB, Appels R (1990) New Secale cereale (rye) DNA derivatives for the detection of rye chromosome segments in wheat. Genome 33:635–640
Metzlaff M, Troebner W, Baldauf F, Schlegel R, Cullum J (1986) Wheat-specific repetitive DNA sequences — construction and characterization of four different genomic clones. Theor Appl Genet 72:207–210
Miller TE (1987) Systematics and evolution. In: Lupton FGH (ed) Wheat breeding: its scientific basis. Chapman and Hall, London, New York, pp 1–30
Moore G, Cheung W, Schwarzacher T, Flavell R (1991) BIS 1, a major component of the cereal genome and a tool for studying genomic organization. Genomics 10:469–476
Moore G, Abbo S, Cheung W, Foote T, Gale M, Koebner R, Leitch A, Leitch I, Money T, Stancombe P, Masahiro Y, Flavell R (1993) Key features of cereal genome organization as revealed by the use of cytosine methylation-sensitive restriction endonucleases. Genomics 15:472–482
Murphy G, Ward ES, (1990) Sequencing of double-stranded DNA. In: Howe CJ, Ward ES (eds) Nucleic Acid Sequencing: A Practical Approach. IRL Press, pp 99–115
Rogowsky PM, Manning S, Liu J-Y, Langridge P (1991) The R173 family of rye-specific repetitive DNA sequences: a structural analysis. Genome 34:88–95
Sambrook J, Fritsch EF, Maniatis T (1989) Molecular cloning: A laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York
Schwarzacher T, Leitch AR, Bennett MD, Heslop-Harrison JS (1989) In situ localization of parental genomes in a wide hybrid. Ann Bot 64:315–324
Schwarzacher T, Anamthawat-Jónsson K, Harrison GE, Islam AKMR, Jia JZ, King IP, Leitch AR, Miller TE, Reader SM, Rogers WJ, Shi M, Heslop-Harrison JS (1992) Genomic in situ hybridization to identify alien chromosomes and chromosome segments in wheat. Theor Appl Genet 84:778–786
Singer MF (1982) Highly repeated sequences in mammalian genomes. Int Rev Cytol 76:67–112
Zhang H-B, Dvorak J (1990) Isolation of repeated DNA sequences from Lophopyrum elongatum for detection of Lophopyrum chromatin in wheat genomes. Genome 33:283–293
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Communicated by R. Herrmann
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Anamthawat-Jónsson, K., Heslop-Harrison, J. Isolation and characterization of genome-specific DNA sequences in Triticeae species. Molec. Gen. Genet. 240, 151–158 (1993). https://doi.org/10.1007/BF00277052
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DOI: https://doi.org/10.1007/BF00277052