Genome size variation in diploid and tetraploid wild wheats
- PMID: 22476073
- PMCID: PMC2992354
- DOI: 10.1093/aobpla/plq015
Genome size variation in diploid and tetraploid wild wheats
Abstract
Background and aims: Intra- and interspecific variations of C-values and the relationship between habitat factors and genome size were studied in natural populations of diploid and tetraploid wild wheats.
Methodology: The 1C nuclear DNA content of 376 individual plants representing 41 populations of diploid and tetraploid wild wheats was determined by flow cytometry (FCM) and correlated with geographical and bioclimate variables.
Principal results: Based on analysis of variance, significant differences between diploid and tetraploid Triticum species were found. Differences among populations of T. boeoticum and T. dicoccoides were also statistically significant and argue for isolation between populations, except for T. araraticum. However, the variation among individuals of the same population was not statistically significant. Maximum genome size differences among populations for T. boeoticum (0.143 pg; 2.32 %), T. dicoccoides (0.314 pg; 2.49 %) and T. araraticum (0.116 pg; 0.98 %) argue for genome constancy in these species. There was no significant correlation between intra-population variance and geographical and bioclimate variables for T. boeoticum and T. dicoccoides. In contrast to the limited genome size variation at the intraspecific level, the interspecific variation was large: ∼0.5 pg/1C (8 %) at the diploid level (T. boeoticum vs. T. urartu) and ∼1 pg/1C (9.7 %) at the tetraploid level (T. dicoccoides vs. T. araraticum).
Conclusions: Low intraspecific genome size variation occurs in diploid and tetraploid wild wheats, and this limited variation is not correlated with geographical and climate variables. However, interspecific variation is significant at the diploid and tetraploid level. It can be concluded that the genome size of wild self-fertilizing Triticum species is generally stable, despite the presence of many potentially active retroelements. In natural habitats, it is very difficult to distinguish wild wheats from each other. However, all four species can be distinguished easily, quickly and unambiguously by using the FCM technique.
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References
-
- Arumuganathan K, Earle ED. Estimation of nuclear DNA content of plants by flow cytometry. Plant Molecular Biology Reporter. 1991;9:229–233. doi:10.1007/BF02672073. - DOI
-
- Badaeva ED, Boguslavsky RL, Badaev NS, Zelenin AV. Intraspecific chromosomal polymorphism of Triticum araraticum (Poaceae) detected by C-banding technique. Plant Systematics and Evolution. 1990;169:13–24. doi:10.1007/BF00935980. - DOI
-
- Badaeva ED, Jiang J, Gill BS. Detection of intergenomic translocations with centromeric and noncentromeric breakpoints in Triticum araraticum: mechanism of origin and adaptive significance. Genome. 1995;38:976–981. doi:10.1139/g95-128. - DOI - PubMed
-
- Bennett MD. Variation in genomic form in plants and its ecological implications. New Phytologist. 1987;106:177–200. doi:10.1111/j.1469-8137.1987.tb04689.x. - DOI
-
- Bennett MD, Leitch IJ. Nuclear DNA amounts in angiosperms. Annals of Botany. 1995;76:113–176. doi:10.1006/anbo.1995.1085. - DOI
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