Functional interaction of phytochrome B and cryptochrome 2

Light is a crucial environmental signal that controls many photomorphogenic and circadian responses in plants. Perception and transduction of light is achieved by at least two principal groups of photoreceptors, phytochromes and cryptochromes. Phytochromes are red/far-red light-absorbing receptors encoded by a gene family of five members (phyA to phyE) in Arabidopsis. Cryptochrome 1 (cry1), cryptochrome 2 (cry2) and phototropin are the blue/ultraviolet-A light receptors that have been characterized in Arabidopsis. Previous studies showed that modulation of many physiological responses in plants is achieved by genetic interactions between different photoreceptors; however, little is known about the nature of these interactions and their roles in the signal transduction pathway. Here we show the genetic interaction that occurs between the Arabidopsis photoreceptors phyB and cry2 in the control of flowering time, hypocotyl elongation and circadian period by the clock. PhyB interacts directly with cry2 as observed in co-immunoprecipitation experiments with transgenic Arabidopsis plants overexpressing cry2. Using fluorescent resonance energy transfer microscopy, we show that phyB and cry2 interact in nuclear speckles that are formed in a light-dependent fashion.     

Role of ethylene signaling in the production of rice volatiles induced by the rice brown planthopper Nilaparvata lugens

In response to herbivory, plants release volatiles to attract the natural enemies of herbivores[1,2]. This phe- nomenon has been reported in more than 23 plant spe- cies[3―6], and several field studies have shown that these herbivore-induced volatiles en…     

β-Glucosidase treatment and infestation by the rice brown planthopper Nilaparvata lugens elicit similar signaling pathways in rice plants

β-Glucosidase has been reported to induce the production of herbivore-induced plant volatiles. However, how it works remains unclear. Here, we investigated the levels of salicylic acid （SA）, jasmonic acid （JA）, ethylene, and H2O2, all of which are known signaling molecules that play important roles in induced plant defense in rice plants treated with β-glucosidase, and compared these to levels in plants infested by the rice brown planthopper Nilaparvata lugens （Stal）. Results showed that wounding and treatment by β-glucosidase increased the levels of SA, ethylene, and H2O2, but not JA, in all plants compared to control plants. The signaling pathways activated by β-glucosidase treatment are similar to those activated by an infestation by N. lugens, although the magnitude and timing of the signals elicited by the two treatments are different. This may explain why both treatments have similar volatile profiles and are equally attractive to the parasitoid Anagrus nilaparvatae Pang et Wang.     

Salicylic acid and ethylene signaling pathways are involved in production of rice trypsin proteinase inhibitors induced by the leaf folder Cnaphalocrocis medinalis （Guenee）

The roles of signaling pathways in the production of trypsin proteinase inhibitors (TrypPIs) in rice infested by the leaf folder (LF) Cnaphalocrocis medinalis were studied. Infestation by LF increased TrypPI levels in the leaves of rice plants at the tillering, booting and flowering stages but decreased TrypPI levels at the ripening stage; TrypPI levels in rice stems did not increase at any developmental stage. Infestation by LF at the tillering stage systemically increased TrypPI levels in leaves but not in stems; it also enhanced salicylic acid (SA) levels in leaves and stems, and the ethylene level released from plants. However, LF infestation did not increase JA concentrations. Exogenous application of SA or ethylene enhanced TrypPI levels in the leaves and stems of plants at the tillering stage, whereas treatment with both SA and ethylene induced lower levels of TrypPIs than treatment with SA or ethylene alone, suggesting an antagonistic effect of SA and ethylene on TrypPIs induction. The results suggest that both SA and ethylene signaling pathways are involved in the production of TrypPIs in rice induced by LF; moreover, the antagonistic effect of SA and ethylene may explain the changes in TrypPI levels seen at different plant developmental stages and in different organs.     

植物激素调控籽粒大小的研究进展

植物种子的大小和品质是影响农作物产量的主要因素之一,研究控制种子籽粒大小发育的相关因素,对提高农作物产量具有重要意义.近年通过分析种子发育缺陷突变体或QTL等分子遗传学的方法,发现许多控制种子发育的重要基因影响着种子的大小和产量.对模式植物拟南芥和水稻的研究发现,许多调控种子发育的功能基因通过整合到植物激素的代谢或信号转导途径起作用,说明植物激素在调控籽粒发育中发挥重要作用,但有关作用的分子机理及其遗传调控网络待阐明.该文以模式植物拟南芥和水稻种子发育研究为例,着重介绍植物激素调控种子籽粒大小调控的研究进展.     

A novel tobacco gene coding for a product similar to bacterial two-component regulators

The two-component signaling system has been studied in bacteria. It takes part in signal transduction of adaptive behavior. Recent studies have shown that a similar two-component system is also present in eukaryotes. Examples of this areETRl andCKLl genes which may involve the signal transduction of plant hormone ethylene and cytokinin respectively. The cloning and characterization of a novel gene (NTHKl) fragment from tobacco are presented. Its partial sequence codes for a product which shows similarity to many two-component signaling proteins. Southern blot analysis indicated that there are 2 to 3 copies ofNTHKl gene in tobacco genome (allotetraploid). Homologous genes may also exist in other plants such as Arabidopsis, soybean and spinach. The expression ofNTHKl gene has also been analyzed in tobacco. Further studies on the isolation of full-length cDNA ofNTHKl gene will elucidate more clearly its function in signal perception and transduction.     

Cloning and expression of putative ethylene receptor genes in soybean plant

Ethylene plays important roles in plant growth, development, and stress responses, and ethylene receptors have been identified and studied extensively in various plant species. Here we report the cloning of four ethylene receptor genes from soybean, i.e. GmETR1, GmERS1, GmETR2 and GmEIN4. Construction of the phylogenic tree showed that GmETR1 and GmERS1 belong to subfamily I whereas GmETR2 and GmEIN4 belong to subfamily II. The four ethylene receptor genes showed different tissue-specific expression patterns in roots, stems, leaves, cotyledons, flowers, pods and seeds of soybean. These genes were differentially regulated by various abiotic stresses and plant hormones. The possible roles of the four genes in soybean plant were also discussed.     

水稻组蛋白单泛素化连接酶基因(OsHUB1)的克隆及其表达分析

对模式植物拟南芥的研究发现,AtHUB1基因参与调控植物对灰霉病的抗性.为了研究水稻的抗病机理,笔者利用同源搜索从水稻数据库中获得了目标基因的序列,并通过RT-PCR技术从水稻中克隆了组蛋白单泛素化连接酶基因,命名为OsHUB1.该片段包含1个2 655 bp的开放阅读框,编码了1个885氨基酸的多肽.与NCBI数据库的比对结果表明:OsHUB1的氨基酸序列与短柄草(Brachypodium distachyon)、葡萄(Vitis vinifera)、杨树(Populus tomentosa)、大豆(Glycine max)和拟南芥(Arabidopsis thaliana)的泛素E3连接酶的同源性分别为78%,68%,68%,67%和62%.这些不同来源的组蛋白单泛素化连接酶都含有一个高度保守的RING指结构域.半定量表达分析结果表明:OsHUB1基因能够被水杨酸(SA)和茉莉酸(JA)诱导表达,说明OsHUB1基因可能通过SA和JA介导的信号转导途径参与水稻的抗病反应.     

Cloning and expression of putative ethylene receptor genes in soybean plant

Ethylene plays important roles in plant growth, development, and stress responses, and ethylene receptors have been identified and studied extensively in various plant species. Here we report the cloning of four ethylene receptor genes from soybean, i.e. GmETR1, GmERS1, GmETR2 and GmEIN4. Construction of the phylogenic tree showed that GmETR1 and GmERS1 belong to subfamily I whereas GmETR2 and GmEIN4 belong to subfamily II. The four ethylene receptor genes showed different tissue-specific expression patterns in roots, stems, leaves, cotyledons, flowers, pods and seeds of soybean. These genes were differentially regulated by various abiotic stresses and plant hormones. The possible roles of the four genes in soybean plant were also discussed.     

Phytochrome signalling is mediated through nucleoside diphosphate kinase 2.

Because plants are sessile, they have developed intricate strategies to adapt to changing environmental variables, including light. Their growth and development, from germination to flowering, is critically influenced by light, particularly at red (660 nm) and far-red (730 nm) wavelengths. Higher plants perceive red and far-red light by means of specific light sensors called phytochromes(A-E). However, very little is known about how light signals are transduced to elicit responses in plants. Here we report that nucleoside diphosphate kinase 2 (NDPK2) is an upstream component in the phytochrome signalling pathway in the plant Arabidopsis thaliana. In animal and human cells, NDPK acts as a tumour suppressor. We show that recombinant NDPK2 in Arabidopsis preferentially binds to the red-light-activated form of phytochrome in vitro and that this interaction increases the activity of recombinant NDPK2. Furthermore, a mutant lacking NDPK2 showed a partial defect in responses to both red and farred light, including cotyledon opening and greening. These results indicate that NDPK2 is a positive signalling component of the phytochrome-mediated light-signal-transduction pathway in Arabidopsis.     

LysM蛋白在植物免疫中的作用

溶解素基序（LysM）是在多种蛋白质中普遍存在的结构域.植物LysM蛋白能够感知几丁质及其寡糖等分子配体，从而启动植物对病原菌的免疫反应.在水稻、拟南芥等植物免疫应答过程中，LysM蛋白作为一种重要的模式识别受体，通过不同形式的寡聚化，激活多种类受体胞质激酶及其下游的MAPK（mitogen activated protein kinase）级联反应传递信号.同时，蛋白质可逆磷酸化和蛋白质降解途径可以负调节LysM蛋白介导的防御信号转导.文章综述了植物免疫过程中LysM蛋白介导的信号转导分子机制.     

拟南芥CARK家族响应脱落酸信号的研究

植物激素脱落酸(Abscisic acid,ABA)在植物应对生物和非生物胁迫中起着重要作用.本研究利用以carks单基因突变体为亲本,构建双重突变体来检测CARKs在ABA信号途径中的功能.然后,分析多重突变体在ABA处理下,种子萌发率和子叶变绿的响应.结果显示:单基因突变体和双重变体与野生型相比,萌发率更高,双重突变体的子叶绿芽率高于单基因突变体.以上结果表明,CARKs家族基因在ABA信号途径中起正调控作用,而且它们的功能是冗余的.     

植物盐胁迫的信号传导途径

植物耐盐性研究具有重要意义.近年来,植物盐胁迫信号传导途径一直是植物耐盐性研究的热点.目前已阐明的盐胁迫信号传导途径有酵母和植物中的MAPK(mitogen-actirated protein kinase)途径、拟南芥中缓解离子胁迫的SOS(salt overIy sensitive)途径以及其他蛋白激酶参与的信号传导途径,其中包括钙依赖而钙调素不依赖的蛋白激酶、受体蛋白激酶、糖原合成酶的激酶和组蛋白激酶.因此,植物的耐盐性是个非常复杂的问题,可能是由多种信号分子参与的网络体系.大量转基因实验证明,信号传导途径中的某些组分可改善植物的耐盐性.因此,深入研究植物的盐胁迫信号传导是提高植物耐盐性的前提和基础.     

Cytokinin signal transduction： Known simplicity and unknown complexity

Cytokinin plays a critical role in plant growth and development by regulating cell divisions and cell differentiation. Recent studies suggest that cytokinin signaling is presumably mediated by a two-component system analogous to those found in bacteria and fungi, which transduces an external signal via a phosphorelay from the plasma membrane-anchored receptors to downstream effectors and regulators. Moreover, cytokinin signaling is highly interactive with other pathways, and many components of the pathway appear to be functionally redundant. Proper address of these questions will be crucial for our further understanding on this important network.     

Promoter of soybean early nodulin gene<Emphasis Type="Italic">enod2B</Emphasis> is induced by rhizobial Nod factors in transgenic rice

Nod factors, which are signaling molecules produced by Rhizobia, are the principal determinants of host specificity in Rhizobium-legume symbiosis. Nod factors can elicit a number of characteristic developmental responses in the roots of legumes, such as depolarization of the membrane potential in epidermal cells, specific expression of early nodulin genes and changes in the flux of calcium in root hairs, deformation of root hairs, cell division in the root cortex and formation of the nodule primordinm. Whether the rice plant can respond to signaling molecules (i.e. Nod factors) is an important question, as it could establish the potential for symbiotic nitrogen fixation in rice. The promoter of the soybean (Glycine max) early nodulin gene Gmenod2B fused to the β-glucuronidase (GUS) reporter gene was used as a molecular marker to explore whether Nod factors can be recognized by rice cells as signaling molecules. Transgenic rice plants harboring the chimeric gene Gmenod2BP-GUS were obtained via an Agrobacterium tumefaciens-mediated system. NodNGR factors produced by a broad-host-range Rhizobium strain NGR234(pA28) were used as probes to investigate the activity of the Gmenod2B promoter in rice. Our results showed that the early nodulin gene Gmenod2B promoter was induced by NodNGR factors in transgenic rice, and that it was specifically expressed in rice plant roots. Moreover, GUS gene expression driven by the Gmenod2B promoter in transgenic rice was regulated by nitrogen status. These findings indicated that rice possessed the ability to respond to Nod factor signals, and that this signal transduction system resulted in activation of the Gmenod2B promoter. Thus, we predict that the Nod-factor inducible nodulin expression system, which is similar to Rhizobium-legume symbiosis, may also exist in rice.     

AGO1基因对拟南芥叶边缘锯齿状发育的影响

在拟南芥和水稻中Argonaute(AGO)蛋白是RNA介导的沉默复合体(RISC)的核心组分,在植物叶极性的分化方面具有重要的调节作用。实验根据AGO1基因序列设计一对特异引物,提取野生型拟南芥RNA作为模板,采用反转录PCR方法扩增出AGO1基因,并插入到克隆载体pGEM-T中。筛选鉴定后将AGO1连接到植物表达载体pBI121上,构建起植物表达载体pBI121-AGO1。并且利用农杆菌介导的方法转化拟南芥,通过抗性筛选,获得转基因植株。然后对转基因植株进行表型分析及AGO1蛋白的RT-PCR检测。通过对转基因拟南芥表达分析发现,与野生型拟南芥相比超表达AGO1蛋白的转基因拟南芥叶片明显呈锯齿状,说明AGO1基因影响拟南芥叶片发育。     

植物中钙解码机制的研究进展

Ca2＋作为重要的第二信使,在植物生长发育中起着非常重要的作用．目前已经鉴定的植物Ca2＋传感器蛋白有：钙调素（CaM）、类钙调素蛋白（CMLs）、钙依赖型蛋白激酶（CDPKs）和类钙调磷酸酶B亚基蛋白（CBLs）及其互作蛋白激酶（CIPKs）,这些传感器蛋白多以基因家族形式存在,并且在植物中能够形成错综复杂的钙离子信号传递网络系统．主要从植物Ca2＋传感器蛋白的生化特性、生理功能和靶蛋白3个方面,综述了植物解码钙信号机制的最新研究进展．     

木本植物响应干旱胁迫的研究现状

为深入了解木本植物响应干旱胁迫的分子机理，本文系统的从木本植物对干旱信号的感知、信号转导到转录调控、生理生化反应以及表型变化等方面总结了木本植物对干旱胁迫可能的响应过程.认为木本植物由于其固着根生的特点，不得不进化出相应的机制来应对不断变化的环境.当遭受干旱胁迫时，木本植物根系细胞膜上的感受器首先感知到土壤水分状态的变化，细胞内的蛋白质和激素调控系统触发相应的干旱适应反应.干旱信号通过细胞间的信号传导路径传递到植物体内的各个部位，主要的信号传导途径包括Ca²⁺信号、激素信号和转录因子调控等.一些关键基因和信号通路，如脱落酸(ABA)信号通路、DREB蛋白家族等也参与调控植物的干旱适应性.木本植物也会发生形态和解剖上的变化来减少水分蒸发和增强根系的吸水能力.本文可为抗旱型木本植物选育提供见解.