植物机械响应中的钙通信北大核心CSCD

以胞质钙离子浓度变化(钙信号)为核心的钙通信系统在植物机械响应中发挥着不可替代的作用。本文综述了机械刺激诱导的植物细胞钙信号及其生理作用、植物机械敏感钙通道,以及TCH基因编码的钙调蛋白和钙调蛋白类似蛋白等的研究进展,总结了该领域尚待解决的问题,并对未来的研究方向进行了展望。     

植物感受盐胁迫及相关钙信号的研究进展

盐胁迫对植物的生长和发育造成严重影响,其危害包括渗透胁迫、离子毒害等,严重损害了农业生产和粮食安全。在盐胁迫下,植物相关感受器接受刺激,使得Ca²⁺通过细胞膜以及细胞内钙库膜上打开的Ca²⁺通道进入细胞质基质,导致细胞质内Ca²⁺浓度升高,产生钙信号。钙离子作为重要的第二信使,在植物细胞内和细胞间传递信号,信号往下游传递,在不同生长和发育阶段引起植物一系列的生理响应来应对盐胁迫影响。钙信号主要通过钙调蛋白（CaM）、钙调素样蛋白（CML）、钙依赖性蛋白激酶（CDPK）、钙调磷酸酶B样蛋白（CBL）和CBL互作蛋白激酶（CIPK）感知并将特异的钙信号信息传递到下游;从而激活植物盐胁迫生理响应。本文主要综述植物如何感知盐胁迫刺激,以及钙信号产生与传导机制,并对该研究领域需解决的问题进行了展望。     

环境胁迫下植物MAPK多叠级联响应

植物MAP(mitogen-activated protein)激酶涉及植物的生长发育、对内源和外界环境刺激的反应.MAP激酶能将胞外感受器引起的刺激传递到胞内引起细胞的反应.拟南芥(Arabidopsis thaliana)作为模式植物,其全部的MAP激酶已经列出并进行了分类.根据已分类的拟南芥MAP激酶家族,已经分离出大量的MAP激酶基因,并将它们进行分类,发现它们大多能被包括病原、创伤、温度、干旱、盐、渗透、紫外线辐射、臭氧和活性氧等胁迫刺激激活.通过研究在不同环境胁迫下的功能和信号路径,发现植物MAP激酶信号传递系统是复杂且相互交错的.需要开发一些新的工具和策略去阐明MAPK信号传递路径,以及如何利用MAPK系统去改善农作物对生物和非生物胁迫的抗性.     

植物中的MAPK及其在信号传导中的作用

促分裂原活化蛋白激酶(MAPKs)是一类存在于真核生物中的丝氨酸/苏氨酸蛋白激酶。同动物和酵母中MAPKs类似,植物中的MAPK级联途径也是由MAPKs、MAPKKs、MAPKKKs三种类型的激酶组成。植物细胞内受体接受外界刺激信号,然后依次磷酸化激活MAPKKKs、MAPKKs和MAPKs,并影响相关基因表达。目前已经从植物中分离到一些MAPKs、MAPKKs和MAPKKKs,它们参与了植物激素、生物胁迫及非生物胁迫等过程的信号传导。介绍了植物响应外界环境胁迫过程中,不同机制和因子对MAPKs级联途径的调控。     

植物MPK信号通路与信号分子H2O2和NO之间的相互关系

促分裂原活化蛋白激酶(MPK)级联途径是真核细胞中普遍存在且保守的信号传导通路,广泛参与植物生长发育和植物抵抗生物和非生物胁迫的防御反应。过氧化氢(H2O2)和一氧化氮(NO)作为重要的信使分子也广泛参与植物生长发育和防御反应的信号传导。近年来,研究也表明MPK信号通路与信号分子H2O2和NO之间存在着多种复杂的关系。一方面,在一些刺激的信号传递过程中,MPK信号通路参与了信号分子H2O2和NO的产生、清除或其信号的向下传递等过程;另一方面,在有些刺激的信号传递过程中,它们位于不同的信号传递途经中,行使不同的功能。本文就目前植物MPK信号通路与H2O2和NO之间相互关系的研究现状进行了综述和分析,并指出了该研究领域存在的问题。     

植物荫蔽胁迫的激素信号响应

植物的生长发育与光信号密切相关, 外界光强、光质的变化会改变植物的生长发育状态。在自然或人工生态系统中, 植株个体的光环境往往会被其周围植物所影响, 导致荫蔽胁迫, 其主要表现为光合有效辐射以及红光与远红光比值(R:FR)降低。荫蔽胁迫对植物生长发育的多个时期均有影响, 如抑制种子萌发、促进幼苗下胚轴伸长及促进植物花期提前等, 这对农业生产不利, 会导致作物产量以及品质的降低。植物激素是调控植物生长发育的关键内源因子。大量研究表明, 生长素(IAA)、赤霉素(GA)及油菜素甾醇(BR)等植物激素均参与介导植物的荫蔽胁迫响应。当植物处于荫蔽胁迫时, 光信号的改变会影响植物激素的合成及信号转导。不同植物激素对荫蔽胁迫的响应各不相同, 但其信号通路之间却存在互作关系, 从而形成复杂的网络状调控路径。该文总结了几种主要植物激素(生长素、赤霉素、油菜素甾醇及乙烯)响应荫蔽胁迫的机理, 重点论述了荫蔽胁迫对植物激素合成及信号通路的影响, 以及植物激素调控荫蔽胁迫下植物生长的分子机理, 并对未来潜在的研究热点进行了分析。     

过氧化氢酶在植物胁迫响应中的功能研究进展

作为信号分子的过氧化氢是植物复杂信号传导中的一个重要组成部分,它介导了多种植物胁迫反应并对其平衡的维持和调控起到了非常重要的作用。越来越多的研究证实了胁迫反应中过氧化氢酶与过氧化氢含量的变化有一定的关系,同时又和其它信号因子存在着交互作用。本文综述了近年来过氧化氢酶在植物遭受病害、水分、盐渍、光等胁迫反应中的调控作用,以及在这些反应中过氧化氢酶、过氧化氢、蛋白激酶、转录因子与其它信号分子所构成的可能信号网络和过氧化氢的限速步骤方面的研究进展。     

NO是植物应激反应的信号分子

根据NO的性质和可能的产生途径,略述了生物胁迫(病原菌侵害)和干旱胁迫、盐胁迫、极端温度、机械损伤、臭氧和紫外辐射等各种非生物胁迫信号与NO信号分子的偶联及其信号的级联途径,概括了NO可能介导的生物过程,讨论了NO通过其下游信号过程对与细胞的生理影响以及该下游信号过程所涉及到的cGMP、cADPR的产生和NO与其它信号分子(ROS、SA、ABA等)的协同作用,表明胁迫诱导的NO爆发是激发、启动和装备植物细胞的重要信号级联环节,这个环节能使植物细胞处于应激状态,并迅速作出反应,形成一系列适应机制。     

黄瓜卷须缠绕过程中小G蛋白活性变化

攀爬植物的卷须是对机械刺激极为敏感的器官。拟南芥(Arabidopsisthaliana)小G蛋白能够响应机械刺激调控自身发育,但小G蛋白信号是否在卷须感受机械刺激发生缠绕过程中发挥作用目前尚不清楚。该研究以黄瓜(Cucumissativus)为实验材料,对其卷须受机械刺激缠绕过程中小G蛋白活性进行了探讨。ROP活性检测结果表明,在卷须缠绕过程中小G蛋白CsROP6的活性显著增强;同时,质谱鉴定结果显示,卷须缠绕过程中生长素的含量明显增加。进一步的实验表明,外源生长素处理能明显增强CsROP6的活性,暗示黄瓜卷须在缠绕过程中受机械刺激可能通过生长素增强ROP活性,且机械刺激激活小G蛋白信号在不同植物中存在一定的保守性。     

生物和非生物逆境胁迫下的植物系统信号

复杂多变的自然环境使植物进化出许多适应策略, 其中由局部胁迫引起的系统响应广泛存在, 精细调节植物的生长发育和环境适应能力。植物系统响应的诱导因素首先引起植物从局部到全株范围的信号转导, 这类信号称为系统信号。当受到外界刺激时, 植物首先在受刺激细胞内触发化学信号分子的变化, 如茉莉酸和水杨酸甲酯等在浓度和信号强度方面发生变化; 进而, 伴随着一系列复杂的信号转换, 多种信号组分共同完成系统响应的激活。植物激素、小分子肽和RNA等被认为是缓慢系统信号通路中的关键组分, 而目前也有大量研究阐释了由活性氧、钙信号和电信号相互偶联组成的快速系统信号通路。植物系统信号对其生存和繁衍至关重要, 其精确的转导机制仍值得深入研究。该文综述了植物响应环境的系统信号转导研究进展, 对关键的系统信号组分及其转导机制进行了总结, 同时对植物系统信号传递的研究方向进行了展望。     

Mechanosensory ion channels in charophyte cells: the response to touch and salinity stress

Mechanosensitive (MS) ion channels are activated by mechanical stress and then transduce this information into electrical signals. These channels are involved in the growth, development and response to environmental stress in higher plants. Detailed analyses of the electrophysiology in higher plants are difficult because such plants are composed of complex tissues. The large cells of the charophytes facilitate electrophysiological measurements and allow us to study MS ion channels at the level of single cells. We draw parallels between the process of touch-perception in freshwater Chara, and the turgor-regulating response to osmotic shock in salt-tolerant Lamprothamnium. In terms of electrophysiology, these responses can be considered in three stages: (1) stimulus perception, (2) signal transmission and (3) induction of response. In Chara the first stage is due to the receptor potential (RPD), a transient depolarization with a critical threshold that triggers action potentials, which are responsible for stages (2) and (3). Receptor potentials are generated by MS ion channels. Action potentials involve a transient influx of Ca(2+) to the cytoplasm, effluxes of K(+) and Cl(-) and a temporary decrease of turgor pressure. Reducing cell turgor increases sensitivity to mechanical stimulation. In Lamprothamnium, a hypotonic shock produces an extended depolarization that resembles an extended RPD and is responsive to osmotic rather than ionic changes. Like the action potential, a critical threshold depolarization triggers Ca(2+) influx, opening of Ca(2+)-sensitive Cl(-) channels and K(+) channels; effluxes that last over an hour and result in turgor regulation. These processes show us, in primal form and at the level of single cells, how mechanoperception occurs in higher plants. Recent progress in research into the role of MS ion channels in the freshwater and salt-tolerant Characeae is reviewed and the relevance of these findings to plants in general is considered.     

应力作用下软骨细胞信号传导的研究进展

研究显示应力刺激对软骨细胞生长及基质代谢具重要作用。软骨正常结构形态以及应力下的软骨细胞形态和基质代谢的变化是力-生物信号转化的基础,信号分子及信号通路则是应力信号传导的核心,二者是对软骨细胞应力下信号传导过程深入了解不可或缺的信息组成,了解应力对软骨细胞的作用方式及作用机制有助于软骨相关疾病诊治、组织工程等领域的研究,本文就这两个方面研究进展做一综述。     

植物响应对风致机械刺激研究进展

机械刺激在自然界中是无处不在的。研究机械刺激的生态学效应有助于将风的直接效应与间接效应区别开来。机械刺激与植物生长关系的研究已经成为近年来植物生态学与植物力学研究的热点之一。从机械刺激的生态学效应及其作用机理两方面综述了国内外研究进展,为深入系统地研究植物对风区等多机械刺激干扰生境的适应性策略做了理论上的概括。同时,为这一理论的应用及未来亟待解决的主要问题进行了总结。     

Mechanical signal transduction in skeletal muscle growth and adaptation.

The adaptability of skeletal muscle to changes in the mechanical environment has been well characterized at the tissue and system levels, but the mechanisms through which mechanical signals are transduced to chemical signals that influence muscle growth and metabolism remain largely unidentified. However, several findings have suggested that mechanical signal transduction in muscle may occur through signaling pathways that are shared with insulin-like growth factor (IGF)-I. The involvement of IGF-I-mediated signaling for mechanical signal transduction in muscle was originally suggested by the observations that muscle releases IGF-I on mechanical stimulation, that IGF-I is a potent agent for promoting muscle growth and affecting phenotype, and that IGF-I can function as an autocrine hormone in muscle. Accumulating evidence shows that at least two signaling pathways downstream of IGF-I binding can influence muscle growth and adaptation. Signaling via the calcineurin/nuclear factor of activated T-cell pathway has been shown to have a powerful influence on promoting the slow/type I phenotype in muscle but can also increase muscle mass. Neural stimulation of muscle can activate this pathway, although whether neural activation of the pathway can occur independent of mechanical activation or independent of IGF-I-mediated signaling remains to be explored. Signaling via the Akt/mammalian target of rapamycin pathway can also increase muscle growth, and recent findings show that activation of this pathway can occur as a response to mechanical stimulation applied directly to muscle cells, independent of signals derived from other cells. In addition, mechanical activation of mammalian target of rapamycin, Akt, and other downstream signals is apparently independent of autocrine factors, which suggests that activation of the mechanical pathway occurs independent of muscle-mediated IGF-I release.     

活细胞内MGTR1-3＇UTR的荧光标记及应激定位分析

利用噬菌体衣壳蛋白MS2和带有序列特异性茎环结构（含有MS2蛋白结合位点）的RNA之间的高度亲和力,对外源性入血管紧张素l型受体（angiotensin II receptor type1,AGTRl）mRNA3’端非翻译区（3＇untranslated region,3’UTR）片段进行红色荧光标记,进而在活细胞（HeLa）内研究该mRNA片段的应激生物学行为。通过在pSG5空载体质粒上先后插入两个双链DNA目的片段AGTR1-3qATR和24×MS2,构建重组质粒pSG5／AGTR1—3‘UTR／24×MS2,并将该质粒与重组质粒pERFP／MS2和pEGFP／C1-G3BP共转染入Hela细胞。荧光显微成像结果显示,AGTR1-3UTR-24×MS2 mNA片段能够携带具有入核信号的MS2-RFP融合蛋白离开胞核进入胞浆,而且在亚砷酸盐刺激下,红色荧光标记的AGTR1-3＇UTR-24×MS2 mRNA;4段可在胞浆中形成与应激蛋白G3BP—GFP共定位的颗粒。该结果表明,针对AGTR1-3‘UTR片段的MS2-RFP荧光标记系统构建成功,该荧光标记系统能有效避免假阳性的荧光信号。在细胞受到氧化应激时,AGTR1-3’UTR会被招募至胞浆中的应激颗粒结构中,启示了AGTR1-3＇UTR区域对于调控AGTR1 mRNA在细胞内的应激定位具有重要作用。     

机械力影响胚胎干细胞结构、形态和分化的研究进展

胚胎干细胞的生长、增殖、分化和形状改变等过程受微环境、机械力等多种因素的影响。胚胎干细胞能够感知微小机械力刺激,并将其转化成生物化学信号,进而通过F-肌动蛋白、肌球蛋白-II、Cdc42、Rho和Src等产生一系列分子水平的应答反应,最终导致基因差异表达。胚胎干细胞应答外力基本过程的研究对于胚胎早期发育和分化机制研究、克隆和再生药物的研制与开发等均有重要意义。该文就机械力对胚胎干细胞结构、形态和分化的影响及其潜在机制等进行论述。     

Effects of mechanical stretching on caspase and IGF-1 expression during the proliferation process of myoblasts

It has been reported that the synthesis, degradation, and metabolism of muscle proteins in myoblasts, as well as the proliferation and differentiation of cells, are influenced by various related to extracellular signaling molecules, such as neural transmitters, growth factors, and hormones, when muscle tissue has been exposed to mechanical stimulation. However, reports regarding the expression of growth factors during mechanical stimulation of myoblasts are few, and many questions remain unanswered. We examined the mRNA expression of insulin-like growth factor 1 (IGF-1) in myoblasts subjected to mechanical stretching in vitro. In addition, apoptosis caused by intracellular stress has been reported to occur during muscle development at the embryonic stage. To clarify the expression of intracellular stress factors, we here investigated related gene expression. Expression of IGF-1 increased in the early stage of cell stretching, followed by a decrease in the late stage. This suggests that mechanical stimulation resulted in an immediate increase in IGF-1 expression, followed by a decrease as cells acclimated to the inducing environment. Caspase was significantly expressed in a stretch group at 12 hours after the beginning of mechanical stimulation, compared with a control group. This suggests that cellular proliferation is also regulated by intracellular stress factors involving the endoplasmic reticulum, mitochondria, and other organelles during the process of muscle proliferation and differentiation.     

力学刺激诱导细胞自噬的研究进展

自噬是细胞重要的自我保护机制,多种伤害性刺激激活的自噬具有维持细胞稳态和正常功能的作用.此外,自噬还参与调控恶性肿瘤、动脉粥样硬化等多种疾病的发生发展过程.体内细胞处于复杂的力学微环境中,力学刺激参与调控细胞自噬,如压力可诱导心肌细胞的自噬、牵张力调控运动系统多种细胞的自噬、流体剪切力可激活血管内皮细胞和肿瘤细胞的自噬.力学刺激诱导的细胞自噬依赖众多信号通路.细胞骨架作为重要的调节因子,不仅参与细胞力学信号转导,同时可参与调控细胞自噬.因此,细胞骨架与力学刺激诱导的细胞自噬密切相关.本文结合最新的研究成果,综述力学刺激对细胞自噬的影响及其分子机制,以期为研究力学刺激对细胞生物学行为的影响提供新的视角,进而为相关疾病的治疗提供新思路和分子靶点.     

Mechanical Induction of β1-Integrin-Mediated Calcium Signaling in a Hepatocyte Cell Line

Mechanical stress influences growth, differentiation, and gene expression in a variety of cell types. It is believed that via extracellular matrix the mechanical stimulus is transmitted to integrin receptors which thus play a key role in transducing signals into the cell interior. Here we demonstrate that incubation of suspended hepatocytes with specific antibodies to β1-integrin subunits followed by a short-term mechanical stimulation is sufficient to induce a rise in intracellular Ca²⁺. The results indicate that mechanical loading of individual integrin subunits activates Ca²⁺-specific signal pathways.     

Label‐free quantitative proteome analysis of skeletal tissues under mechanical load

Skeletal tissue has the capability to adapt its mass and structure in response to mechanical stress. However, the molecular mechanism of bone and cartilage to respond to mechanical stress are not fully understood. A label‐free quantitative proteome approach was used for the first time to obtain a global perspective of the response of skeletal tissue to mechanical stress. Label‐free quantitative analysis of 1D‐PAGE‐LC/MS/MS based proteomics was applied to identify differentially expressed proteins. Differential expression analysis in the experimental groups and control group showed significant changes for 248 proteins including proteins related to proliferation, differentiation, regulation of signal transduction and energy metabolic pathways. Fluorescence labeling by incorporation of alizarin/calcein in newly formed bone minerals qualitatively demonstrated new bone formation. Skeletal tissues under mechanical load evoked marked new bone formation in comparison with the control group. Bone material apposition was evident. Our data suggest that 39 proteins were assigned a role in anabolic process. Comparisons of anabolic versus catabolic features of the proteomes show that 42 proteins were related to catabolic. In addition, some proteins were related to regulation of signal transduction and energy pathways, such as tropomyosin 4, fibronectin 1, and laminin, might be new molecular targets that are responsive to mechanical force. Differentially expressed proteins identified in this model may offer a useful starting point for elucidating novel aspects of the effects of mechanical force on skeletal tissue. J. Cell. Biochem. 108: 600–611, 2009. © 2009 Wiley‐Liss, Inc.