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早萌芽1(EBB1)定义了一种控制木本多年生植物萌芽的保守机制。

EARLY BUD-BREAK1 (EBB1) defines a conserved mechanism for control of bud-break in woody perennials.

作者信息

Busov Victor, Carneros Elena, Yakovlev Igor

机构信息

a School of Forest Resources and Environmental Science; Michigan Technological University ; Houghton , Michigan USA.

c Biotechnology Research Center, Michigan Technological University , 1400 Townsend Drive, Houghton , MI 49931 , USA.

出版信息

Plant Signal Behav. 2016;11(2):e1073873. doi: 10.1080/15592324.2015.1073873.

DOI:10.1080/15592324.2015.1073873
PMID:26317150
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4883858/
Abstract

Bud-break is an environmentally and economically important trait in trees, shrubs and vines from temperate latitudes. Poor synchronization of bud-break timing with local climates can lead to frost injuries, susceptibility to pests and pathogens and poor crop yields in fruit trees and vines. The rapid climate changes outpace the adaptive capacities of plants to respond through natural selection. This is particularly true for trees which have long generation cycle and thus the adaptive changes are significantly delayed. Therefore, to devise appropriate breeding and conservation strategies, it is imperative to understand the molecular underpinnings that govern dormancy mechanisms. We have recently identified and characterized the poplar EARLY BUD-BREAK 1 (EBB1) gene. EBB1 is a positive regulator of bud-break and encodes a transcription factor from the AP2/ERF family. Here, using comparative and functional genomics approaches we show that EBB1 function in regulation of bud-break is likely conserved across wide range of woody perennial species with importance to forestry and agriculture.

摘要

芽萌发是温带地区树木、灌木和藤本植物在环境和经济方面的重要性状。芽萌发时间与当地气候同步性差会导致霜冻伤害、易受病虫害侵袭,以及果树和藤本植物产量低下。快速的气候变化超出了植物通过自然选择做出响应的适应能力。对于具有长世代周期因而适应变化显著延迟的树木来说尤其如此。因此,为了制定合适的育种和保护策略,必须了解控制休眠机制的分子基础。我们最近鉴定并表征了杨树早芽萌发1(EBB1)基因。EBB1是芽萌发的正向调节因子,编码一个AP2/ERF家族的转录因子。在这里,我们使用比较和功能基因组学方法表明,EBB1在调控芽萌发中的功能可能在广泛的多年生木本植物中保守,这对林业和农业具有重要意义。

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