拟南芥的侧根生长受通过富含亮氨酸重复序列受体样激酶XIP1/CEPR1和CEPR2进行的短距离和长距离信号传导控制。
Lateral root growth in Arabidopsis is controlled by short and long distance signaling through the LRR RLKs XIP1/CEPR1 and CEPR2.
作者信息
Dimitrov I, Tax F E
机构信息
a Department of Molecular and Cellular Biology , University of Arizona , Tucson , AZ , USA.
b School of Plant Sciences , University of Arizona , Tucson , AZ , USA.
出版信息
Plant Signal Behav. 2018;13(6):e1489667. doi: 10.1080/15592324.2018.1489667. Epub 2018 Jul 11.
Abstract
Plants rely on lateral roots to explore their soil environment and to maximize their uptake of essential minerals and water. Here we present evidence that the receptor kinases XIP1/CEPR1 and CEPR2 regulate both the initiation of lateral root primordia and emergence of lateral roots locally in the root, while also controlling lateral root extension in response to shoot-derived sucrose in Arabidopsis plants. In addition, mutation of both of these receptors prevents seedlings from responding to sucrose in the media, resulting in longer lateral roots. These results, combined with previous data, establish XIP1/CEPR1 and CEPR2-dependent roles in short- and long-distance pathways regulating different stages of lateral root growth.
摘要
植物依靠侧根来探索其土壤环境,并最大限度地吸收必需矿物质和水分。我们在此提供证据表明,受体激酶XIP1/CEPR1和CEPR2在根中局部调节侧根原基的起始和侧根的出现,同时还能控制拟南芥植株中侧根对来自地上部蔗糖的响应而进行的延伸。此外,这两种受体的突变会阻止幼苗对培养基中蔗糖的响应,从而导致侧根更长。这些结果与之前的数据相结合,确立了XIP1/CEPR1和CEPR2在调节侧根生长不同阶段的短距离和长距离途径中的作用。
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