青藏高原葱属植物的基因组大小的逐渐进化和多倍体化。
Gradual genome size evolution and polyploidy in Allium from the Qinghai-Tibetan Plateau.
机构信息
Germplasm Bank of Wild Species, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming 650201, China.
Institute of Tibetan Plateau Research at Kunming, Chinese Academy of Sciences, Kunming 650201, China.
出版信息
Ann Bot. 2023 Feb 7;131(1):109-122. doi: 10.1093/aob/mcab155.
BACKGROUND AND AIMS
Genome size is an important plant trait, with substantial interspecies variation. The mechanisms and selective pressures underlying genome size evolution are important topics in evolutionary biology. There is considerable diversity in Allium from the Qinghai-Tibetan Plateau, where genome size variation and related evolutionary mechanisms are poorly understood.
METHODS
We reconstructed the Allium phylogeny using DNA sequences from 71 species. We also estimated genome sizes of 62 species, and determined chromosome numbers in 65 species. We examined the phylogenetic signal associated with genome size variation, and tested how well the data fit different evolutionary models. Correlations between genome size variations and seed mass, altitude and 19 bioclimatic factors were determined.
KEY RESULTS
Allium genome sizes differed substantially between species and within diploids, triploids, tetraploids, hexaploids and octaploids. Size per monoploid genome (1Cx) tended to decrease with increasing ploidy levels. Allium polyploids tended to grow at a higher altitude than diploids. The phylogenetic tree was divided into three evolutionary branches. The genomes in Clade I were mostly close to the ancestral genome (18.781 pg) while those in Clades II and III tended to expand and contract, respectively. A weak phylogenetic signal was detected for Allium genome size. Furthermore, significant positive correlations were detected between genome size and seed mass, as well as between genome size and altitude. However, genome size was not correlated with 19 bioclimatic variables.
CONCLUSIONS
Allium genome size shows gradual evolution, followed by subsequent adaptive radiation. The three well-supported Allium clades are consistent with previous studies. The evolutionary patterns in different Allium clades revealed genome contraction, expansion and relative stasis. The Allium species in Clade II may follow adaptive radiation. The genome contraction in Clade III may be due to DNA loss after polyploidization. Allium genome size might be influenced by selective pressure due to the conditions on the Qinghai-Tibetan Plateau (low temperature, high UV irradiation and abundant phosphate in the soil).
背景与目的
基因组大小是植物的一个重要特征,不同物种间存在显著差异。基因组大小进化的机制和选择压力是进化生物学中的重要课题。青藏高原的葱属植物具有丰富的多样性,但其基因组大小的变化和相关进化机制尚不清楚。
方法
我们使用 71 种植物的 DNA 序列重建了葱属植物的系统发育关系。我们还估算了 62 种植物的基因组大小,并确定了 65 种植物的染色体数目。我们检验了与基因组大小变化相关的系统发育信号,并测试了数据与不同进化模型的拟合程度。确定了基因组大小变化与种子质量、海拔和 19 个生物气候因子之间的相关性。
主要结果
不同物种以及二倍体、三倍体、四倍体、六倍体和八倍体内部的葱属植物基因组大小差异显著。单倍体基因组(1Cx)的大小随倍性水平的增加而减小。与二倍体相比,多倍体葱属植物往往生长在较高的海拔。系统发育树分为三个进化分支。分支 I 的基因组大多接近祖先基因组(18.781 pg),而分支 II 和 III 的基因组则分别倾向于扩张和收缩。葱属植物基因组大小的系统发育信号较弱。此外,还检测到基因组大小与种子质量以及基因组大小与海拔之间存在显著正相关。然而,基因组大小与 19 个生物气候变量没有相关性。
结论
葱属植物基因组大小表现出逐渐进化,随后是适应性辐射。三个得到充分支持的葱属分支与之前的研究一致。不同葱属分支的进化模式揭示了基因组的收缩、扩张和相对稳定。分支 II 的葱属物种可能遵循适应性辐射。分支 III 的基因组收缩可能是多倍化后 DNA 丢失的结果。由于青藏高原的特殊环境条件(低温、高紫外线辐射和土壤中丰富的磷酸盐),葱属植物的基因组大小可能受到选择压力的影响。
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