番茄果实代谢的分道化。
Canalization of Tomato Fruit Metabolism.
机构信息
Max Planck Institute of Molecular Plant Physiology, 14476 Potsdam-Golm, Germany.
Consiglio per la Ricerca in Agricoltura e l'analisi dell'Economia Agraria, 00134 Rome, Italy.
出版信息
Plant Cell. 2017 Nov;29(11):2753-2765. doi: 10.1105/tpc.17.00367. Epub 2017 Nov 1.
Abstract
To explore the genetic robustness (canalization) of metabolism, we examined the levels of fruit metabolites in multiple harvests of a tomato introgression line (IL) population. The IL partitions the whole genome of the wild species in the background of the cultivated tomato (). We identified several metabolite quantitative trait loci that reduce variability for both primary and secondary metabolites, which we named canalization metabolite quantitative trait loci (cmQTL). We validated nine cmQTL using an independent population of backcross inbred lines, derived from the same parents, which allows increased resolution in mapping the QTL previously identified in the ILs. These cmQTL showed little overlap with QTL for the metabolite levels themselves. Moreover, the intervals they mapped to harbored few metabolism-associated genes, suggesting that the canalization of metabolism is largely controlled by regulatory genes.
摘要
为了探索代谢的遗传鲁棒性(分 canalization),我们检测了番茄导入系(IL)群体在多次收获中的果实代谢物水平。该 IL 将野生种的整个基因组分配到栽培番茄的背景中()。我们鉴定了几个减少初级和次级代谢物变异性的代谢物数量性状位点(cmQTL),我们将其命名为 canalization 代谢物数量性状位点(cmQTL)。我们使用来自相同亲本的回交自交系(BILs)的独立群体验证了 9 个 cmQTL,这允许在先前在 ILs 中鉴定的 QTL 上进行更高分辨率的映射。这些 cmQTL 与代谢物水平本身的 QTL 很少重叠。此外,它们映射到的区间几乎没有与代谢相关的基因,这表明代谢的 canalization 主要由调节基因控制。
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