植物冷驯化相关信号机制

植物经过非致死温度的处理可以获得更强的抗冷能力叫做冷驯化,主要包括寒驯化和冻驯化 .在冷驯化过程中,质膜首先感受冷信号,调节胞质中IP3的含量,诱导胞质Ca2+浓度的升高,从而激活CBF基因的表达.至今已经克隆了大量的冷调控基因,组成了复杂的信号传导网络,其中ICE1-CBF-COR通路在植物的冷驯化过程中起到重要的作用.ICE1基因编码一个MYB类型的碱性螺旋 环-螺旋（bHLH）转录因子,在上游调节CBF和 其它转录因子的表达,提高抗冷性. HOS1蛋白通过泛素化介导的蛋白降解负调控ICE1,另外,CBF还通过转录的自我调控保持恰当的表达水平.基因的分析研究证明,RNA修饰和核质转运在植物的抗冷过程中也具有重要作用.在不依赖于CBF的途径中,转录因子HOS9和HOS10在调节抗冷有关基因的表达和提高抗冷能力方面具有至关重要的作用.     

赤桉抗寒转录因子ICE1基因的分子克隆与表达分析

ICE1属于一种类似MYC的bHLH转录因子,可特异地结合到CBF3启动子的MYC作用元件并诱导CBF/DREB1下游基因的转录表达。本文以拟南芥ICE1蛋白序列为信息探针,搜索桉树基因组和EST数据库的同源序列并进行拼接、设计引物,通过RT-PCR从赤桉克隆了桉树的第一个ICE1基因。其cDNA长1792bp,含有完整的开放阅读框,可编码523个氨基酸。BLAST分析表明,cDNA序列及其推导的氨基酸序列均与拟南芥、芥菜、小麦和甜杨ICE1存在着较高的同源性,预示所获得的cDNA可能是赤桉ICE1基因（EcaICE1）。EcaICE1基因表达分析结果显示,EcaICE1在赤桉根、茎、叶中均表达,而且表达水平不受低温胁迫处理时间的影响,这表明EcaICE1是组成型表达。此外,EcaICE1的超表达可以提高转基因烟草的耐低温能力。上述结果为进一步研究EcaICE1在赤桉耐低温胁迫过程中基因表达的调控机制打下基础。     

Fitness benefits and costs of cold acclimation in Arabidopsis thaliana

Abstract When resources are limited, there is a trade-off between growth/reproduction and stress defense in plants. Most temperate plant species, including Arabidopsis thaliana, can enhance freezing tolerance through cold acclimation at low but nonfreezing temperatures. Induction of the cold acclimation pathway should be beneficial in environments where plants frequently encounter freezing stress, but it might represent a cost in environments where freezing events are rare. In A. thaliana, induction of the cold acclimation pathway critically involves a small subfamily of genes known as the CBFs. Here we test for a cost of cold acclimation by utilizing (1) natural accessions of A. thaliana that originate from different regions of the species' native range and that have experienced different patterns of historical selection on their CBF genes and (2) transgenic CBF overexpression and T-DNA insertion (knockdown/knockout) lines. While benefits of cold acclimation in the presence of freezing stress were confirmed, no cost of cold acclimation was detected in the absence of freezing stress. These findings suggest that cold acclimation is unlikely to be selected against in warmer environments and that naturally occurring mutations disrupting CBF function in the southern part of the species range are likely to be selectively neutral. An unanticipated finding was that cold acclimation in the absence of a subsequent freezing stress resulted in increased fruit production, that is, fitness.     

ICE1 CBF信号通路在植物抵御低温胁迫和调控发育过程中的作用研究进展

低温作为重要的环境因子影响着植物的地理分布和物种多样性,并且对农业可持续发展造成了严重的威胁。ICE1(INDUCER OF CBF EXPRESSION1) CBF(C REPEAT BINDING FACTOR)信号通路不仅在植物抵御低温胁迫的过程中发挥着关键作用,也在植物调控生长发育的过程中也扮演着重要角色,对ICE1 CBF调控机理的了解有助于深入认识植物如何在逆境条件下平衡生长与生存之间的关系。该文对近年来国内外有关ICE1 CBF通路在低温信号转导中的精细调控过程的研究进展进行了综述,并重点对ICE1 CBF在调控植物发育中的作用进行了讨论。     

Integration of photoperiod and cold temperature signals into flowering genetic pathways in Arabidopsis

Appropriate timing of flowering is critical for propagation and reproductive success in plants. Therefore, flowering time is coordinately regulated by endogenous developmental programs and external signals, such as changes in photoperiod and temperature. Flowering is delayed by a transient shift to cold temperatures that frequently occurs during early spring in the temperate zones. It is known that the delayed flowering by short-term cold stress is mediated primarily by the floral repressor FLOWERING LOCUS C (FLC). However, how the FLC-mediated cold signals are integrated into flowering genetic pathways is not fully understood. We have recently reported that the INDUCER OF CBF EXPRESSION 1 (ICE1), which is a master regulator of cold responses, FLC, and the floral integrator SUPPRESSOR OF OVEREXPRESSION OF CONSTANS 1 (SOC1) constitute an elaborated feedforward-feedback loop that integrates photoperiod and cold temperature signals to regulate seasonal flowering in Arabidopsis. Cold temperatures promote the binding of ICE1 to FLC promoter to induce its expression, resulting in delayed flowering. However, under floral inductive conditions, SOC1 induces flowering by blocking the ICE1 activity. We propose that the ICE1-FLC-SOC1 signaling network fine-tunes the timing of photoperiodic flowering during changing seasons.