小立碗藓叶绿体分裂相关基因PpMinE的克隆及其功能与进化分析

用RT-PCR技术从小立碗藓中(Physcomitrella patens)克隆了核编码的MinE基因,命名为PpMinE,并克隆了该基因的基因组DNA。序列比对显示该基因编码的蛋白质与真细菌和绿藻叶绿体编码的MinE蛋白具有较高的相似性。pMinE-EGFP融合蛋白在烟草中的瞬时表达证明该蛋白定位于叶绿体内。在大肠杆菌中过量表达PpMinE导致细胞不正常分裂,产生无染色体的小细胞,这表明MinE的功能在进化上是保守的。在系统发育树中,PpMinE和高等陆生植物有较近的亲缘关系。在已知的陆生植物的叶绿体基因组中没有找到MinE的同源蛋白,这暗示在进化过程中MinE从叶绿体到细胞核的水平转移可能发生在陆生植物发生以前。     

三种不同抗冻性葡萄中CBF2基因的生物信息学分析及植物表达载体构建

从赤霞珠、贝达和山葡萄三种不同抗冻性葡萄的基因组DNA中分别克隆了CBF2全长基因,并利用生物信息学的方法进行了分析。结果显示：三种葡萄的CBF2基因长均为969 bp,编码253 个氨基酸,与GeneBank公布的的序列相比对,核苷酸相似性在96.7%～97.94%之间。生物信息学分析显示3种不同抗冻葡萄的CBF2基因具有连续的开放阅读框,推倒的氨基酸序列具有AP2结合域,初步判断克隆的CBF2具有诱导抗寒性产生的作用。但氨基酸序列、进化树、理化性质、疏水性/亲水性等在抗寒性较强的山葡萄、贝达与抗寒性较差的赤霞珠之间存在一些差异,与GenBank上的原始序列同源性最低的是赤霞珠,而且其CBF2 N端7个氨基酸残基序列与山葡萄和贝达的氨基酸序列存在较大差异,且具有较强的疏水性,这些差异可能与赤霞珠较弱的抗寒特性有关。以带有35S启动子的载体pBI121为基础,成功构建了植物表达载体pBI121 CaMV35S CBF2,为深入研究CBF2基因在葡萄抗寒性中的作用提供了基础资料。     

蜡梅Chimonanthus praecox (L.) Link COR413蛋白基因(Cpcor413pm1)的分子特性与表达分析

为研究蜡梅冬季开花过程的抗寒分子机理,在构建蜡梅花cDNA文库及EST分析的基础上,通过随机克隆测序,克隆了1个蜡梅COR413蛋白的cDNA基因,命名为Cpcor413pm1.Cpcor413pm1 cDNA长946　bp,推测的编码蛋白CpCOR413PM1包含201个氨基酸.CpCOR413PM1蛋白N端保守性差,没有信号肽,具有5个保守的跨膜区,1个潜在的GPI锚点,具有可能对蛋白结构或活性十分重要的位置保守的7个Pro、1个Cys, 1个被富Gly区一分为二的α螺旋区域,以及Tyr、Thr、Ser磷酸化位点各1个.序列比较分析表明,Cpcor413pm1是首次从蜡梅中克隆到的COR413蛋白基因.RT-PCR分析表明, 该基因在蜡梅的萌动期、蕾期、露瓣期、初开期、盛开期、衰老期均有表达,但在初开期和盛开期表达丰度更高,推测Cpcor413pm1与蜡梅花的抗冻性有密切关系.     

牦牛与其他物种ZFX/ZFY基因片段间的进化关系

利用PCR扩增、克隆和序列分析法对牦牛ZFX/ZFY基因第11外显子部分片段进行了研究,并同来自于NCBI GenBank中人、猩猩、普通牛等9个物种的ZFX/ZFY基因核苷酸及其氨基酸序列进行了进化分析.结果表明,牦牛ZFX、ZFY基因间核苷酸序列同源性为94.1%,显示同一物种同源基因ZFX/ZFY间存在变异;比较的10个物种间ZFX基因核苷酸序列同源性为87.7%、ZFY基因为81.7%,相应ZFX、ZFY氨基酸同源性分别为96.6%、91.0%,ZFY基因的变异性大于ZFX基因,显示X染色体与Y染色体可能是独立进化.     

彩叶草叶片衰老相关新基因Cbcbs的分子特征和功能分析

 叶片衰老是观叶植物观赏性降低的重要因素之一.为研究彩叶草叶片衰老变化的分子机理,在构建彩叶草衰老叶片cDNA文库及小型EST库的基础上,以1条新的具有胱硫醚 β 合酶(cystathionine beta synthase, CBS)结构域的EST序列为探针,通过RACE与文库结合的 方法,克隆了1个具有1对完整CBS结构域的全长cDNA,Cbcbs.Cbcbs cDNA 全长859 bp,包含1个609 bp的ORF框,编码202个氨基酸.其5′UTR区含有1个终止子TAA,3′UTR区含有推测的加尾信号AATAAA和ATTTA元件.CbCBS N端含有线粒体转运肽,具有2个保守的CBS结构域,4个酪蛋白激酶Ⅱ(casein kinase Ⅱ,CKⅡ)磷酸化位点,3个蛋白激酶C(protein kinase c,PKC)磷酸化位点和1个酪氨酸硫化(tyrosine sulfation,TS)位点.序列比较和进化分析表明,CbCBS是与衰老或应急相关的蛋白.二级结构和三级结构预测表明,CbCBS的功能主要由CBS结构域决定.RT-PCR分析表明,该基因在叶的各个时期均有表达,但随叶片衰老进程的加快而表达增加,是一个叶衰老相关基因（SAG）,推测在线粒体中成熟的CbCBS可能作为细胞能量传感器,在叶衰老引起的能量应急中参与细胞能量水平的调节.     

葡萄BRX基因家族生物信息学分析

BRX基因家族是一类植物特有的转录因子家族,在拟南芥中参与调节根细胞的增殖与伸长。利用生物信息学方法对葡萄基因组中存在的BRX基因家族进行了电子克隆,并对其进行了基因组的定位、蛋白质的结构、理化性质、二级结构及亚细胞定位的预测与分析,并对其与其它植物进化的亲缘关系进行了研究。基因组定位结果发现:葡萄基因组中6个BRX基因集中分布在3条染色体上,其中Vv BRX1和Vv BRX2分布在第2条染色体上,Vv BRX3和Vv BRX4分布在第9条染色体上,Vv BRX5和Vv BRX6分布在第11条染色体上;编码蛋白的氨基酸数目为360~560个,Vv BRX5的相对分子量(61 884.4)和理论等电点(9.38)均最大,而Vv BRX1的相对分子量(40 239.1)和理论等电点(6.23)均最小。研究显示,不同成员间氨基酸数目、氨基酸序列间存在一定的差异,但都为疏水性蛋白;α-螺旋和无规则卷曲为6个BRX氨基酸序列的主要组成部分;均不存在跨膜域及信号肽。基因结构分析表明,6个BRX基因都含有外显子和内含子结构。亚细胞定位分析表明:6个Vv BRX基因均定位于细胞核。系统进化分析结果表明,Vv BRX1、Vv BRX2基因与胡杨的亲缘关系最近,相似性达96%;Vv BRX3、Vv BRX4与蓖麻、麻疯树、柑橘、可可、大豆聚为一类,说明其进化关系较近;Vv BRX5与其它Vv BRX基因明显分开;Vv BRX6基因与莲的亲缘关系最近。试验结果为葡萄BRX基因家族的克隆和功能分析奠定了一定的研究基础。     

大黄鱼Flotillin-1基因分子特征分析

浮舰蛋白-1(Flotillin-1)是属于SPFH家族的蛋白,是重要的脂筏标志性蛋白.在构建大黄鱼(Larimichthys crocea)肌肉组织cDNA文库的基础上,克隆了Flotillin-1基因,并进一步扩增出内含子.克隆到的序列全长为2497 bp,其中编码区1194 bp,编码397个氨基酸.生物信息学分析大黄鱼Flotillin-1有5类20个功能位点,存在2次跨膜结构,N端和C端都位于细胞膜内.大黄鱼Flotillin-1氨基酸序列具有非常高的保守性,与大西洋鲑和斑马鱼的同源性都在80%以上.在组织中的表达也非常广泛,其中在脾中的表达最强.     

脂氧合酶OsRCI-1正调控水稻对二化螟的抗性

本文克隆了虫害诱导的水稻脂氧合酶基因OsRCI-1全编码序列, 实时定量QRT-PCR 检测结果表明二化螟Chilo suppressalia Walker取食能快速且持续地诱导OsRCI-1基因的表达。利用农杆菌介导的水稻遗传转化获得了两株OsRCI-1基因的RNAi沉默突变体,突变体株系ir-rci-1和ir-rci-2中目的基因OsRCI-1的表达被明显的抑制,其表达水平分别仅为对照(秀水11)的4773%和3233%。生测结果表明OsRCI-1基因沉默导致水稻对二化螟抗性显著地降低,取食RNAi突变体株系的二化螟体重分别是取食秀水11的158倍和215倍。因此,水稻OsRCI-1基因正调控对二化螟的抗性,该基因介导的防御途径可能在水稻虫害诱导防御反应中起重要的作用。     

小鼠BTB/锌指结构新基因Bsg6的克隆及表达谱分析

Bsg6 (brain specific gene 6) 是用消减差异筛选的方法克隆的小鼠头部特异表达 新基因. Bsg6基因cDNA长3 871 bp,编码一个670个氨基酸残基的蛋白,GenBank 登录号AY635051,位于小鼠第4号染色体,由2个外显子构成. Bsg6蛋白含有一个N端BTB（Broad complex, Tramtrack, and Bric a brac）结构域和两个C端C２Ｈ２型锌指结构域. 小鼠Bsg6蛋白与其在人类和鸡中同源蛋白的同源性分别为86.2%和79.1%. Bsg6在小鼠胚胎中的表达具有一定动态性,在E8.5的小鼠胚胎中,Bsg6主要在前脑和神经管表达. 在E9.5的小鼠胚胎中,Bsg6的表达明显增强并主要集中在前脑的端脑部. Bsg6在E10.5小鼠胚胎端脑的表达出现了下降,但是在中脑和后脑的表达增加,此外,Bsg6 mRNA的表达还出现在肢芽和尾部. 在HH10期的鸡胚中,Bsg6主要在头部和神经管前端表达. Northern杂交结果显示,Bsg6在很多小鼠成体组织中没有表达,但是在破骨细胞瘤中高表达. Bsg6的表达谱提示,Bsg6可能是在器官形成期对脑的发育起到重要作用的转录因子,而且其表达受到严格的调控,此外Bsg6还能与肿瘤的发生有关.     

西番莲PeERG基因克隆及其表达模式分析

ERA(Eecherichia coli Ras-like protein)蛋白是与已知异三聚体G蛋白和小分子G蛋白不同的一种新的GTP结合蛋白。为了在木本植物中开展其同源基因ERG(ERA-like GTPase)克隆和功能验证的相关研究,该文首次在西番莲新品种‘平塘1号’中采用cDNA末端快速克隆(RACE)技术克隆鉴定1个ERG基因。结果表明:西番莲PeERG基因cDNA全长为1 518 bp,包括1 260 bp的开放阅读框、38 bp的5'-端非翻译区和220 bp的3'-端非翻译区,该基因编码蛋白由420个氨基酸残基组成,其二级结构含有丰富的α-螺旋和延伸链。PeERG蛋白不含跨膜区域,也不存在信号肽酶切位点,既在其N端有典型的GTPase保守结构域(GTPase domain)又在其C端有独特的RNA结合结构域(KH domain)。系统进化树分析表明,西番莲PeERG蛋白和水稻OsERG1、拟南芥AtERG1、大肠杆菌ERA位于同一进化分枝。实时定量PCR检测揭示PeERG基因在西番莲根、茎、叶、花、果中均有表达,叶中表达最高;同时该基因响应低温胁迫信号,其表达呈动态变化模式。该研究首次鉴定和描述了木本植物西番莲的ERG基因,为深入挖掘西番莲特异基因资源提供参考,也有助于进一步探究ERG基因在植物中的生物学功能及其作用机制。     

高等植物质体的分裂

质体来源于早期具光合能力的原核生物与原始真核生物的内共生事件。原核起源的蛋白以及真核寄主起源的蛋白共同参与了质体的分裂过程。以原核生物的细胞分裂蛋白为蓝本, 近些年在植物中陆续鉴定出几种主要的原核生物细胞分裂蛋白的同源物, 如FtsZ、MinD和MinE蛋白。然而, 除此之外, 原核细胞大多数分裂相关因子在植物中找不到其同源物, 但却鉴定了许多真核寄主来源的分裂相关蛋白。当前研究的重点是剖析各种质体分裂蛋白协同作用的机制, 业已证明MinD和MinE的协同作用保证了FtsZ(Z)环的正确定位。尽管经典的FtsZ的抑制因子MinC在植物中不存在, 但实验表明ARC3在拟南芥中具有类似MinC的功能。ARC3蛋白与真核起源的蛋白如ARC5、ARTEMIS、FZL和PD环以及其它原核起源的蛋白如ARC6和GC1等共同构成了一个复杂的植物质体分裂调控系统。     

高等植物质体的分裂

质体来源于早期具光合能力的原核生物与原始真核生物的内共生事件。原核起源的蛋白以及真核寄主起源的蛋白共同参与了质体的分裂过程。以原核生物的细胞分裂蛋白为蓝本,近些年在植物中陆续鉴定出几种主要的原核生物细胞分裂蛋白的同源物,如FtsZ、MinD和MinE蛋白。然而,除此之外,原核细胞大多数分裂相关因子在植物中找不到其同源物,但却鉴定了许多真核寄主来源的分裂相关蛋白。当前研究的重点是剖析各种质体分裂蛋白协同作用的机制,业已证明MinD和Mine的协同作用保证了FtsZ（Z）环的正确定位。尽管经典的FtsZ的抑制因子MinC在植物中不存在,但实验表明ARC3在拟南芥中具有类似MinC的功能。ARC3蛋白与真核起源的蛋白如ARC5、ARTEMIS、FZL和PD环以及其它原核起源的蛋白如ARC6和GC1等共同构成了一个复杂的植物质体分裂调控系统。     

Plastid division: evolution, mechanism and complexity

BACKGROUND: The continuity of chloroplasts is maintained by division of pre-existing chloroplasts. Chloroplasts originated as bacterial endosymbionts; however, the majority of bacterial division factors are absent from chloroplasts and the eukaryotic host has added several new components. For example, the ftsZ gene has been duplicated and modified, and the Min system has retained MinE and MinD but lost MinC, acquiring at least one new component ARC3. Further, the mechanism has evolved to include two members of the dynamin protein family, ARC5 and FZL, and plastid-dividing (PD) rings were most probably added by the eukaryotic host. SCOPE: Deciphering how the division of plastids is coordinated and controlled by nuclear-encoded factors is key to our understanding of this important biological process. Through a number of molecular-genetic and biochemical approaches, it is evident that FtsZ initiates plastid division where the coordinated action of MinD and MinE ensures correct FtsZ (Z)-ring placement. Although the classical FtsZ antagonist MinC does not exist in plants, ARC3 may fulfil this role. Together with other prokaryotic-derived proteins such as ARC6 and GC1 and key eukaryotic-derived proteins such as ARC5 and FZL, these proteins make up a sophisticated division machinery. The regulation of plastid division in a cellular context is largely unknown; however, recent microarray data shed light on this. Here the current understanding of the mechanism of chloroplast division in higher plants is reviewed with an emphasis on how recent findings are beginning to shape our understanding of the function and evolution of the components. CONCLUSIONS: Extrapolation from the mechanism of bacterial cell division provides valuable clues as to how the chloroplast division process is achieved in plant cells. However, it is becoming increasingly clear that the highly regulated mechanism of plastid division within the host cell has led to the evolution of features unique to the plastid division process.     

叶绿体分裂相关蛋白CrMinD的保守功能

细胞或质体中部正确分裂位点的选择是MinD蛋白与其他Min蛋白（MinC／E）相互作用的结果,MinD蛋白在原核细胞以及植物叶绿体的分裂过程中发挥着重要的作用。细胞中MinD蛋白浓度的明显升高可影响正常细胞的分裂过程而产生丝状体细胞。为了研究叶绿体分裂蛋白CrMinD的保守功能,构建了衣藻CrMinD-gfp的原核表达重组质粒进行了原核功能验证。试验结果表明,衣藻CrMinD蛋白的过量表达严重影响了大肠杆菌的分裂,其在原核细胞中运动和定位与用GFP标记的原核细胞MinD蛋白具有相似性。更进一步证明了叶绿体分裂同源物CrMinD蛋白与原核细胞MinD蛋白有着相似的功能,是一个进化上功能保守的蛋白。同时,这一结果也为研究植物细胞中质体的分裂机制奠定了一定的基础。     

The molecular biology of plastid division in higher plants

Plastids are essential plant organelles vital for life on earth, responsible not only for photosynthesis but for many fundamental intermediary metabolic reactions. Plastids are not formed de novo but arise by binary fission from pre-existing plastids, and plastid division therefore represents an important process for the maintenance of appropriate plastid populations in plant cells. Plastid division comprises an elaborate pathway of co-ordinated events which include division machinery assembly at the division site, the constriction of envelope membranes, membrane fusion and, ultimately, the separation of the two new organelles. Because of their prokaryotic origin bacterial cell division has been successfully used as a paradigm for plastid division. This has resulted in the identification of the key plastid division components FtsZ, MinD, and MinE, as well as novel proteins with similarities to prokaryotic cell division proteins. Through a combination of approaches involving molecular genetics, cell biology, and biochemistry, it is now becoming clear that these proteins act in concert during plastid division, exhibiting both similarities and differences compared with their bacterial counterparts. Recent efforts in the cloning of the disrupted loci in several of the accumulation and replication of chloroplasts mutants has further revealed that the division of plastids is controlled by a combination of prokaryote-derived and host eukaryote-derived proteins residing not only in the plastid stroma but also in the cytoplasm. Based on the available data to date, a working model is presented showing the protein components involved in plastid division, their subcellular localization, and their protein interaction properties.     

Overexpression of MinE gene affects the plastid division in cassava

The MinE protein plays an important role in plastid division. In this study, the MinE gene was isolated from the cassava (Manihot esculenta Crantz) genome. We isolated high quality and quantity protoplasts and succeed in performing the transient expression of the GFP-fused Manihot esculenta MinE (MeMinE) protein in cassava mesophyll protoplasts. The transient expression of MeMinE-GFP in cassava protoplasts showed that the MeMinE protein was located in the chloroplast. Due to the abnormal division of chloroplasts, overexpression of MeMinE proteins in cassava mesophyll protoplasts could result in fewer and smaller chloroplasts. Overexpression of MeMinE proteins also showed abnormal cell division characteristics and minicell occurrence in Escherichia coli caused by aberrant septation events in the cell poles.     

The topological specificity factor AtMinE1 is essential for correct plastid division site placement in Arabidopsis

In plant cells, plastids divide by binary fission involving a complex pathway of events. Although there are clear similarities between bacterial and plastid division, limited information exists regarding the mechanism of plastid division in higher plants. Here we demonstrate that AtMinE1, an Arabidopsis homologue of the bacterial MinE topological specificity factor, is an essential integral component of the plastid division machinery. In prokaryotes MinE imparts topological specificity during cell division by blocking division apparatus assembly at sites other than midcell. We demonstrate that overexpression of AtMinE1 in E. coli results in loss of topological specificity and minicell formation suggesting evolutionary conservation of MinE mode of action. We further show that AtMinE1 can indeed act as a topological specificity factor during plastid division revealing that AtMinE1 overexpression in Arabidopsis seedlings results in division site misplacement giving rise to multiple constrictions along the length of plastids. In agreement with cell division studies in bacteria, AtMinE1 and AtMinD1 show distinct intraplastidic localisation patterns suggestive of dynamic localisation behaviour. Taken together our findings demonstrate that AtMinE1 is an evolutionary conserved topological specificity factor, most probably acting in concert with AtMinD1, required for correct plastid division in Arabidopsis.     

The plastid division protein AtMinD1 is a Ca2+-ATPase stimulated by AtMinE1

Bacteria and plastids divide symmetrically through binary fission by accurately placing the division site at midpoint, a process initiated by FtsZ polymerization, which forms a Z-ring. In Escherichia coli precise Z-ring placement at midcell depends on controlled oscillatory behavior of MinD and MinE: In the presence of ATP MinD interacts with the FtsZ inhibitor MinC and migrates to the membrane where the MinD-MinC complex recruits MinE, followed by MinD-mediated ATP hydrolysis and membrane release. Although correct Z-ring placement during Arabidopsis plastid division depends on the precise localization of the bacterial homologs AtMinD1 and AtMinE1, the underlying mechanism of this process remains unknown. Here we have shown that AtMinD1 is a Ca2+-dependent ATPase and through mutation analysis demonstrated the physiological importance of this activity where loss of ATP hydrolysis results in protein mislocalization within plastids. The observed mislocalization is not due to disrupted AtMinD1 dimerization, however; the active site AtMinD1(K72A) mutant is unable to interact with the topological specificity factor AtMinE1. We have shown that AtMinE1, but not E. coli MinE, stimulates AtMinD1-mediated ATP hydrolysis, but in contrast to prokaryotes stimulation occurs in the absence of membrane lipids. Although AtMinD1 appears highly evolutionarily conserved, we found that important biochemical and cell biological properties have diverged. We propose that correct intraplastidic AtMinD1 localization is dependent on AtMinE1-stimulated, Ca2+-dependent AtMinD1 ATP hydrolysis, ultimately ensuring precise Z-ring placement and symmetric plastid division.     

Visualization of a cytoskeleton-like FtsZ network in chloroplasts

It has been a long-standing dogma in life sciences that only eukaryotic organisms possess a cytoskeleton. Recently, this belief was questioned by the finding that the bacterial cell division protein FtsZ resembles tubulin in sequence and structure and, thus, may be the progenitor of this major eukaryotic cytoskeletal element. Here, we report two nuclear-encoded plant ftsZ genes which are highly conserved in coding sequence and intron structure. Both their encoded proteins are imported into plastids and there, like in bacteria, they act on the division process in a dose-dependent manner. Whereas in bacteria FtsZ only transiently polymerizes to a ring-like structure, in chloroplasts we identified persistent, highly organized filamentous scaffolds that are most likely involved in the maintenance of plastid integrity and in plastid division. As these networks resemble the eukaryotic cytoskeleton in form and function, we suggest the term "plastoskeleton" for this newly described subcellular structure.