开花植物的环境能量与进化速率
Environmental energy and evolutionary rates in flowering plants.
作者信息
Davies T Jonathan, Savolainen Vincent, Chase Mark W, Moat Justin, Barraclough Timothy G
机构信息
Department of Biological Scienes and NERC Centre for Population Biology, Imperial College, London. Ascot SL7 7PUY, UK.
出版信息
Proc Biol Sci. 2004 Oct 22;271(1553):2195-200. doi: 10.1098/rspb.2004.2849.
Abstract
The latitudinal gradient in species richness is a pervasive feature of the living world, but its underlying causes remain unclear. We evaluated the hypothesis that environmental energy drives evolutionary rates and thereby diversification in flowering plants. We estimated energy levels across angiosperm family distributions in terms of evapotranspiration, temperature and UV radiation taken from satellite and climate databases. Using the most comprehensive DNA-based phylogenetic tree for angiosperms to date, analysis of 86 sister-family comparisons shows that molecular evolutionary rates have indeed been faster in high-energy regions, but that this is not an intermediate step between energy and diversity. Energy has strong, but independent effects on both species richness and molecular evolutionary rates.
摘要
物种丰富度的纬度梯度是生物界普遍存在的一个特征,但其根本原因仍不明确。我们评估了这样一个假说:环境能量驱动着开花植物的进化速率,进而推动其多样化发展。我们根据取自卫星和气候数据库的蒸发散、温度和紫外线辐射,估算了被子植物科分布范围内的能量水平。利用迄今为止最全面的基于DNA的被子植物系统发育树,对86组姊妹科比较进行分析表明,分子进化速率在高能量区域确实更快,但这并非能量与多样性之间的中间步骤。能量对物种丰富度和分子进化速率均有强烈但独立的影响。
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