Department of Botany and Zoology, Masaryk University, Kotlářská 2, 61137 Brno, Czech Republic.
BMC Plant Biol. 2010 Nov 30;10:265. doi: 10.1186/1471-2229-10-265.
Transposable elements (TEs) are considered to be an important source of genome size variation and genetic and phenotypic plasticity in eukaryotes. Most of our knowledge about TEs comes from large genomic projects and studies focused on model organisms. However, TE dynamics among related taxa from natural populations and the role of TEs at the species or supra-species level, where genome size and karyotype evolution are modulated in concert with polyploidy and chromosomal rearrangements, remain poorly understood. We focused on the holokinetic genus Eleocharis (Cyperaceae), which displays large variation in genome size and the occurrence of polyploidy and agmatoploidy/symploidy. We analyzed and quantified the long terminal repeat (LTR) retrotransposons Ty1-copia and Ty3-gypsy in relation to changes in both genome size and karyotype in Eleocharis. We also examined how this relationship is reflected in the phylogeny of Eleocharis.
Using flow cytometry, we measured the genome sizes of members of the genus Eleocharis (Cyperaceae). We found positive correlation between the independent phylogenetic contrasts of genome size and chromosome number in Eleocharis. We analyzed PCR-amplified sequences of various reverse transcriptases of the LTR retrotransposons Ty1-copia and Ty3-gypsy (762 sequences in total). Using real-time PCR and dot blot approaches, we quantified the densities of Ty1-copia and Ty3-gypsy within the genomes of the analyzed species. We detected an increasing density of Ty1-copia elements in evolutionarily younger Eleocharis species and found a positive correlation between Ty1-copia densities and C/n-values (an alternative measure of monoploid genome size) in the genus phylogeny. In addition, our analysis of Ty1-copia sequences identified a novel retrotransposon family named Helos1, which is responsible for the increasing density of Ty1-copia. The transition:transversion ratio of Helos1 sequences suggests that Helos1 recently transposed in later-diverging Eleocharis species.
Using several different approaches, we were able to distinguish between the roles of LTR retrotransposons, polyploidy and agmatoploidy/symploidy in shaping Eleocharis genomes and karyotypes. Our results confirm the occurrence of both polyploidy and agmatoploidy/symploidy in Eleocharis. Additionally, we introduce a new player in the process of genome evolution in holokinetic plants: LTR retrotransposons.
转座元件(TEs)被认为是真核生物基因组大小变异、遗传和表型可塑性的重要来源。我们对 TEs 的大部分了解来自于大型基因组项目和针对模式生物的研究。然而,在自然种群中,相关分类群之间的 TE 动态以及在物种或超物种水平上 TE 的作用,其中基因组大小和核型进化与多倍体和染色体重排一起调节,仍然知之甚少。我们专注于整体活跃的属 Eleocharis(莎草科),该属在基因组大小以及多倍体和同倍体/拟倍体的发生方面表现出很大的变化。我们分析并量化了长末端重复(LTR)逆转录转座子 Ty1-copia 和 Ty3-gypsy 与 Eleocharis 中基因组大小和核型变化的关系。我们还研究了这种关系在 Eleocharis 系统发育中的反映。
使用流式细胞术,我们测量了 Eleocharis 属(莎草科)成员的基因组大小。我们发现 Eleocharis 中基因组大小和染色体数目的独立系统发育对比之间存在正相关。我们分析了 LTR 逆转录转座子 Ty1-copia 和 Ty3-gypsy 的各种逆转录酶的 PCR 扩增序列(总共 762 个序列)。使用实时 PCR 和斑点印迹方法,我们量化了分析物种基因组中 Ty1-copia 和 Ty3-gypsy 的密度。我们在进化上较年轻的 Eleocharis 物种中检测到 Ty1-copia 元件密度增加,并在属系统发育中发现 Ty1-copia 密度与 C/n 值(单倍体基因组大小的替代衡量标准)之间存在正相关。此外,我们对 Ty1-copia 序列的分析鉴定了一种名为 Helos1 的新型逆转录转座子家族,它负责 Ty1-copia 密度的增加。Helos1 序列的转换/颠换比表明,Helos1 最近在分化较晚的 Eleocharis 物种中转座。
使用几种不同的方法,我们能够区分 LTR 逆转录转座子、多倍体和同倍体/拟倍体在塑造 Eleocharis 基因组和核型方面的作用。我们的结果证实了 Eleocharis 中多倍体和同倍体/拟倍体的发生。此外,我们在整体活跃植物的基因组进化过程中引入了一个新的参与者:LTR 逆转录转座子。
