植物CBL-CIPK信号系统响应非生物胁迫的调控机制

钙调磷酸酶B蛋白(CBLs)及其互作蛋白激酶(CIPKs)组成的信号系统是非生物逆境响应的重要调控网络。CBL-CIPK系统通过磷酸化感应并解码Ca²⁺信号, 参与植物对非生物胁迫的应答调控。该文综述了CBLs和CIPKs结构、CBLs-CIPKs对不同底物磷酸化及其响应非生物胁迫调控机制的研究进展, 并展望了未来的研究方向, 以期为作物抗逆性遗传改良提供思路。     

植物钙感受器及其介导的逆境信号途径

钙信号是植物生长发育和逆境响应的重要调控因子, 是植物生理与逆境生物学研究领域中的热点之一。当植物细胞受到外界逆境刺激时, 其胞内会产生具有时空特异性的Ca2+信号变化, 这种变化首先被胞内钙感受器所感知并解码, 再由钙感受器互作蛋白将信号传递到下游, 从而激活下游早期响应基因的表达或相关离子通道的活性, 最终产生特异性逆境响应。植物细胞通过感知胞内钙信号的变化如何识别来自外界不同性质或不同强度的刺激, 是近几年植物生物学家所关注的科学问题。文章主要总结了近几年在植物钙感受器研究领域中的最新进展, 包括钙依赖蛋白激酶(CDPKs)、钙调素(CaMs)、类钙调素蛋白(CMLs)、类钙调磷酸酶B蛋白(CBLs)及其互作蛋白激酶(CIPKs)等的结构、功能及其介导的逆境信号途径, 并提供新的见解和展望。     

植物逆境胁迫相关miRNA研究进展

MicroRNAs(mi RNAs)是一类内源性小分子的非编码RNA,它通过对其靶基因mRNA的降解或抑制翻译来调控基因表达,进而参与调控植物相关生理活动。在逆境胁迫下,植物中的一些miRNA通过迅速表达并作用于某些与逆境相关的基因,以启动植物的某些抗逆信号系统,进而提高植物对不良环境的适应能力。就miRNA的产生、作用方式、研究方法及其在植物在逆境胁迫中的抗逆作用机制研究进行了综述,并对植物miRNA的研究发展趋势进行了展望。     

生长素与植物逆境胁迫关系的研究进展

生长素(IAA)是一种重要的植物激素,与植物的逆境胁迫反应关系密切。综述近年来国内外对生长素与植物逆境胁迫关系研究的一些最新进展,重点分析生长素和生长素响应基因及其相关转录因子在植物响应盐害、干旱、低温等胁迫中的反应。     

逆境胁迫下ABA与钙信号转导途径之间的相互调控机制

Ca2+信号是植物应答各种逆境胁迫响应的一个重要组分,它在植物抗病、抗虫及适应非生物胁迫反应中起着重要的作用.Caz+信号作为第二信使在激素信号转导尤其是ABA信号转导过程中发挥着重要作用.研究表明,当植物受到如干旱、低温、盐害等环境胁迫时,细胞迅速积累ABA,胞内钙离子浓度瞬间升高,然后钙离子浓度呈现忽高忽低的震荡现象.在植物细胞中发现Caz+/CDPK、Caz+/CaM和Caz+/CBL三类钙信号系统,它们与逆境胁迫信号转导密切相关.本文通过综述植物在逆境条件下,ABA与钙信号的产生、转导及产生适应性和抗性等方面,介绍了ABA与钙信号之间的相互调节机制.     

植物水分胁迫诱导蛋白的研究进展

主要介绍了植物水分胁迫诱导蛋白的表达模式、特征、分类、功能及其诱导过程中的信号转导及诱导机制。认为胁迫诱导蛋白的产生是植物对逆境胁迫的一种适应性反应,诱导蛋白从多方面保护植物避免或减少胁迫所造成的伤害。植物通过多种途径感受并转导干旱胁迫信号,诱导也多种基因表达产物,从而尽可能地增强对逆境的抗性。     

非生物逆境胁迫下植物钙信号转导的分子机制

Ca^2＋作为植物细胞中最重要的第二信使,参与植物对许多逆境信号的转导。在非生物逆境条件下,植物细胞质内的钙离子在时间、空间及浓度上会出现特异性变化,即诱发产生钙信号。钙信号再通过其下游的钙结合蛋白进行感受和转导,进而在细胞内引起一系列的生物化学反应以适应或抵制各种逆境胁迫。目前在植物细胞中发现Ca^2＋／CDPK、Ca^2＋／CaM和Ca^2＋／CBL3类钙信号系统,研究表明它们与非生物逆境胁迫信号转导密切相关。本文通过从植物在非生物逆境条件下钙信号的感受、转导到产生适应性和抗性等方面,介绍钙信号转导分子机制的一些研究进展。     

非生物逆境胁迫下植物钙信号转导的分子机制

Ca2+作为植物细胞中最重要的第二信使, 参与植物对许多逆境信号的转导。在非生物逆境条件下, 植物细胞质内的钙离子在时间、空间及浓度上会出现特异性变化, 即诱发产生钙信号。钙信号再通过其下游的钙结合蛋白进行感受和转导, 进而在细胞内引起一系列的生物化学反应以适应或抵制各种逆境胁迫。目前在植物细胞中发现Ca2+/CDPK、Ca2+/CaM和Ca2+/CBL 3类钙信号系统, 研究表明它们与非生物逆境胁迫信号转导密切相关。本文通过从植物在非生物逆境条件下钙信号的感受、转导到产生适应性和抗性等方面, 介绍钙信号转导分子机制的一些研究进展。     

植物对盐胁迫应答的转录因子及其生物学特性

逆境胁迫会激活植物的转录因子,转录因子结合到应答基因的顺式作用元件后可以启动应答基因的表达,调控并减轻逆境胁迫对植物的伤害,因而转录调控在植物对逆境胁迫的应答反应中具有重要的作用。本文对盐胁迫下参与植物应答反应的转录因子及其生物学特性进行了综述,并对这些转录因子在植物耐盐基因工程中的应用前景作出了展望。     

植物逆境miRNA研究进展

包括生物和非生物在内的多种逆境胁迫是植物正常生长和作物产量提高的重要限制性因素。植物在长期的进化过程中, 通过诱导表达某些抵御或防卫途径的关键基因来实现对胁迫的响应。研究表明, 逆境胁迫不仅会诱导植物蛋白质编码基因的表达, 也会诱导一些非蛋白质编码基因的表达, 这类非蛋白质编码基因的表达产物在植物的生长、发育和应对逆境胁迫等过程中起到重要的调控作用。miRNA(小分子RNA)就是这类非蛋白质编码基因产物中的重要类群, 研究发现, 多种逆境均会诱导miRNA的产生, 其作用是通过引导目的基因mRNA的降解和阻止翻译过程来调控靶基因, 最终通过形态或生理上的变化达到对逆境的适应。文章主要对植物逆境胁迫下miRNA的研究, 特别是逆境胁迫诱导miRNA的产生、靶基因调控以及miRNA在植物适应逆境胁迫过程中的作用进行了综述, 同时, 文章还对在逆境胁迫下植物miRNA的研究方法进行了初步的探讨。     

Structure and function of the CBL–CIPK Ca2+-decoding system in plant calcium signaling

Calcium is a crucial messenger in many growth and developmental processes in plants. The central mechanism governing how plant cells perceive and respond to environmental stimuli is calcium signal transduction, a process through which cellular calcium signals are recognized, decoded, and transmitted to elicit downstream responses. In the initial decoding of calcium signals, Ca²⁺ sensor proteins that bind Ca²⁺ and activate downstream signaling components are implicated, thereby regulating specific physiological and biochemical processes. After calcineurin B-like proteins (CBLs) sense these Ca²⁺ signatures, these proteins interact selectively with CBL-interacting protein kinases (CIPKs), thereby forming CBL/CIPK complexes, which are involved in decoding calcium signals. Therefore, specificity, diversity, and complexity are the main characteristics of the CBL-CIPK signaling system. However, additional CBLs, CIPKs, and CBL/CIPK complexes remain to be identified in plants, and the specific functions of their abiotic and biotic stress signaling will need to be further dissected. Therefore, a much-needed synthesis of recent findings is important to further the study of CBL-CIPK signaling systems. Here, we review the structure of CBLs and CIPKs, discuss the current knowledge of CBL–CIPK pathways that decode calcium signals in Arabidopsis, and link plant responses to a variety of environmental stresses with specific CBL/CIPK complexes. This will provide a foundation for future research on genetically engineered resistant plants with enhanced tolerance to various environmental stresses.     

Comprehensive structural,interaction and expression analysis of CBL and CIPK complement during abiotic stresses and development in rice

Calcium ion is involved in diverse physiological and developmental pathways. One of the important roles of calcium is a signaling messenger, which regulates signal transduction in plants. CBL (calcineurin B-like protein) is one of the calcium sensors that specifically interact with a family of serine–threonine protein kinases designated as CBL-interacting protein kinases (CIPKs). The coordination of these two gene families defines complexity of the signaling networks in several stimulus-response-coupling during various environmental stresses. In Arabidopsis, both of these gene families have been extensively studied. To understand in-depth mechanistic interplay of CBL–CIPK mediated signaling pathways, expression analysis of entire set of CBL and CIPK genes in rice genome under three abiotic stresses (salt, cold and drought) and different developmental stages (3-vegetative stages and 11-reproductive stages) were done using microarray expression data. Interestingly, expression analysis showed that rice CBLs and CIPKs are not only involved in the abiotic stress but their significant role is also speculated in the developmental processes. Chromosomal localization of rice CBL and CIPK genes reveals that only OsCBL7 and OsCBL8 shows tandem duplication among CBLs whereas CIPKs were evolved by many tandem as well as segmental duplications. Duplicated OsCIPK genes showed variable expression pattern indicating the role of gene duplication in the extension and functional diversification of CIPK gene family in rice. Arabidopsis SOS3/CBL4 related genes in rice (OsCBL4, OsCBL5, OsCBL7 and OsCBL8) were employed for interaction studies with rice and Arabidopsis CIPKs. OsCBLs and OsCIPKs are not only found structurally similar but likely to be functionally equivalent to Arabidopsis CBLs and CIPKs genes since SOS3/CBL4 related OsCBLs interact with more or less similarly to rice and Arabidopsis CIPKs and exhibited an interaction pattern comparable with Arabidopsis SOS3/CBL4.     

Identification and characterization of putative CIPK genes in maize

Calcium(Ca) plays a crucial role as a second messenger in intracellular signaling elicited by developmental and environmental cues. Calcineurin B-like proteins(CBLs) and their target proteins,CBL-interacting protein kinases(CIPKs) have emerged as a key Ca~(2+)-mediated signaling network in response to stresses in plants.Bioinformatic analysis was used to identify 43 putative ZmCIPK(Zea mays CIPK) genes in the genome of maize inbred line B73.Based on gene structures,these ZmCIPKs were divided into intron-...     

The NAF domain defines a novel protein-protein interaction module conserved in Ca2+-regulated kinases

The Arabidopsis calcineurin B-like calcium sensor proteins (AtCBLs) interact with a group of serine-threonine protein kinases (AtCIPKs) in a calcium-dependent manner. Here we identify a 24 amino acid domain (NAF domain) unique to these kinases as being required and sufficient for interaction with all known AtCBLs. Mutation of conserved residues either abolished or significantly diminished the affinity of AtCIPK1 for AtCBL2. Comprehensive two-hybrid screens with various AtCBLs identified 15 CIPKs as potential targets of CBL proteins. Database analyses revealed additional kinases from Arabidopsis and other plant species harbouring the NAF interaction module. Several of these kinases have been implicated in various signalling pathways mediating responses to stress, hormones and environmental cues. Full-length CIPKs show preferential interaction with distinct CBLs in yeast and in vitro assays. Our findings suggest differential interaction affinity as one of the mechanisms generating the temporal and spatial specificity of calcium signals within plant cells and that different combinations of CBL-CIPK proteins contribute to the complex network that connects various extracellular signals to defined cellular responses.     

Evolutionary analysis of CBL-interacting protein kinase gene family in plants

Calcineurin B-like proteins (CBLs) and CBL-interacting protein kinases (CIPKs) form the CBL-CIPK complexes, perceiving calcium signals and relaying the signals to downstream responses in plants. To further understand the CBL-CIPK signaling system, here we focused on the evolutionary analysis of CIPKs. We re-evaluated eight plant genomes and identified 146 CIPKs, providing several new CIPKs in rice and poplar. A phylogenetic tree was constructed, showing that these 146 CIPKs are grouped into intron-rich and intron-less clades. Furthermore, all the CIPKs from the non-angiosperm species were found in intron-rich clade. We identified 30 conserved protein motifs among these 146 CIPKs. Analysis of gene duplication showed that the expansion of CIPKs in both clades is partly contributed by segmental duplications, however, tandem duplicates were found only in intron-less clade. Ka/Ks ratios showed that CIPK genes have experienced purifying selective pressure. Additionally, clustering of gene expression revealed that some CIPK genes in two clades share similar expression patterns under abiotic stresses and four CIPKs in intron-less clade form a distinct cluster (i.e., different expression patterns), suggesting the complexity of CIPK gene expression under abiotic stresses. Taken together, our results provided some new insights into the evolution of CIPKs and the hint that the expansion of CIPKs in intron-less clade is adaptive to environmental stresses.     

The Arabidopsis calcium sensor calcineurin B-like 3 inhibits the 5'-methylthioadenosine nucleosidase in a calcium-dependent manner

Calcineurin B-like (CBL) proteins represent a unique family of calcium sensors in plant cells. Sensing the calcium signals elicited by a variety of abiotic stresses, CBLs transmit the information to a group of serine/threonine protein kinases (CBL-interacting protein kinases [CIPKs]), which are currently known as the sole targets of the CBL family. Here, we report that the CBL3 member of this family has a novel interaction partner in addition to the CIPK proteins. Extensive yeast two-hybrid screenings with CBL3 as bait identified an interesting Arabidopsis (Arabidopsis thaliana) cDNA clone (named AtMTAN, for 5'-methylthioadenosine nucleosidase), which encodes a polypeptide similar to EcMTAN from Escherichia coli. Deletion analyses showed that CBL3 utilizes the different structural modules to interact with its distinct target proteins, CIPKs and AtMTAN. In vitro and in vivo analyses verified that CBL3 and AtMTAN physically associate only in the presence of Ca(2+). In addition, we empirically demonstrated that the AtMTAN protein indeed possesses the MTAN activity, which can be inhibited specifically by Ca(2+)-bound CBL3. Overall, these findings suggest that the CBL family members can relay the calcium signals in more diverse ways than previously thought. We also discuss a possible mechanism by which the CBL3-mediated calcium signaling regulates the biosynthesis of ethylene and polyamines, which are involved in plant growth and development as well as various stress responses.