脯氨酸参与植物开花信号转导途径

作为一种渗透调节物质,人们对脯氨酸已经有了很多的研究,然而脯氨酸在生命体生长发育中的作用还知之甚少。为了研究脯氨酸在生长发育中的作用,筛选得到了拟南芥的脯氨酸抗性突变体kao2。突变体在不同浓度脯氨酸培养基上均表现出抗性,但是突变体中脯氨酸的吸收没有显著变化,降解关键基因表达也没有增多。Tail-PCR进行突变基因克隆的结果表明,T-DNA插入位点位于AtKAO2(At2g32440)的第一个外显子,且插入导致AtKAO2基因不再表达。拟南芥突变体库中订购的kao2-2同样表现出脯氨酸抗性表型。此外,kao2表现出胁迫敏感表型。kao2表现出明显的晚花表型,并且赤霉素的添加能够部分挽救晚花表型。而kao2突变体中开花抑制因子FLC表达升高,而开花促进基因FT的表达降低。研究在脯氨酸与开花信号转导途径之间建立了联系,为脯氨酸对开花途径的信号作用提供了新的证据,为以后的研究提供了新的材料。     

拟南芥SUA41基因的表达和功能分析

植物的开花受多条途径的控制, 其中包括光周期途径、春化途径、赤霉素途径、自主途径和温敏途径。SUA41(SUMO substrate in Arabidopsis 41)是本实验室筛选到的、SUMO(Small ubiquitin modifier)的潜在底物, 并且前人的研究发现它参与自主途径的开花调节, 但其对开花时间的调节机制没有详细报道。文章对SUA41基因的表达、sua41突变体对不同环境条件的反应以及SUA41对开花时间调节的可能机制进行初步分析。结果显示, 与野生型相比, sua41突变体在常温或低温、长日或者短日条件下均为早花, 并且在低温和常温下的开花时间没有太大差别。过表达SUA41能够恢复sua41突变体的早花表型。SUA41基因在拟南芥的幼苗、根、茎、叶和花以及各个植物发育阶段都有表达, 说明SUA41基因是一个组成型表达基因。SUA41基因的表达与GA处理无关, 长日低温条件能够诱导SUA41基因的表达, 且在温敏途径突变体fve和fca中SUA41基因的表达量减少。与野生型比较, sua41突变体中CO基因的mRNA表达量没有明显变化, FT和SOC1基因表达量增加且FT增加幅度更大, FLC的mRNA表达量减少。结果表明SUA41基因虽然在自主途径中起作用, 但主要在温敏途径中参与拟南芥开花时间调节。     

春化作用相关基因FLC的研究进展

拟南芥春化作用相关基因FLOWERING LOCUS C（FLC）属于MADS盒基因,它编码的蛋白转录因子对开花具抑制作用。春化作用通过负调控FLC的转录及蛋白表达水平,促进拟南芥的某些晚花生态型和晚花突变体开花。主要介绍了FLC基因在春化途径中的关键作用,及其春化作用通过FLC基因与其它开花途径相联系等内容。     

小黑杨FLC基因的克隆及功能解析

MADS-box家族蛋白是一类重要的调控开花的转录因子,FLC是其家族成员的编码基因之一。FLC在调节开花过程,其功能的发挥受多个途径的调控。本研究利用RT-PCR方法在小黑杨雄花芽中克隆出FLC基因的全长c DNA序列Pn FLC。该基因的开放读码框为726 bp,编码241个氨基酸残基组成的分子量为27.559 k D的蛋白质,蛋白质的等电点为9.37。实时定量荧光PCR结果显示,春化能够使Pn FLC在小黑杨根、茎、叶各组织中表达量下调57.9%~84%;启动子GUS染色结果表明,Pn FLC启动子在分裂活跃的组织中活性较高。拟南芥的遗传转化结果显示,Pn FLC可以调控At AP1、At SOC1和At FT基因的表达,同时延迟拟南芥的开花时间。     

拟南芥ERD15基因缺失突变体的分子鉴定和表型分析

为探究ERD15基因功能,利用反向遗传学,通过PCR及半定量PCR筛选鉴定出拟南芥(Arabidopsis thaliana) ERD15基因的T-DNA插入纯合突变体,并对其表型进行观察分析。结果表明,erd15突变体莲座叶数目显著增多,提前3～4 d开花,突变体比野生型更早从营养生长转向生殖生长。拟南芥野生型植株主茎为圆柱体,平均直径1.29 mm,而erd15突变体主茎扁平,平均直径达到2.27mm,具极显著差异。与野生型相比,erd15突变体果实心皮发育受到影响,隔膜上排列有多排种子,果荚顶端膨大,长度缩短37.67%,但角果平均结籽数升高。因此,ERD15基因参与了调控拟南芥植株的生殖生长过程。     

FLC基因表达在植物春化过程中的作用

在对以往有关不同开花途径研究简要总结的基础上综述了FLC基因在春化过程中的作用。近期以拟南芥不同生态型和突变体为模式的研究结果表明基因FLC可能是春化反应的关键基因。研究发现 ,FLC的表达水平与植株低温处理的时间呈数量关系 ,低温处理时间越长 ,FLC的表达越弱 ,去甲基化也可能对FLC起负调控的作用。同时FLC也存在于自主开花途径中 ,与其他基因共同作用以调节植株开花时间。而FLC的表达对开花起抑制作用。一系列研究表明 ,春化的低温作用可能在于相关基因的去甲基化 ,消除了FLC对开花的抑制作用 ,从而解除赤霉素合成途径的封锁最终导致植株在一定时期开花。     

FLC基因表达在植物春化过程中的作用

在对以往有关不同开花途径研究简要总结的基础上综述了FLC基因在春化过程中 的作用。近期以拟南芥不同生态型和突变体为模式的研究结果表明基因FLC可能是春化反应的关键基因。研究发现,FLC的表达水平与植株低温处理的时间呈数量关系,低温处理时间越长,FLC的表达越弱,去甲基化也可能对FLC起负调控的作用。同时FLC也存在于自主开花途径中,与其他基因共同作用以调节植株开花时间。而FLC的表达对开花起抑制作用。一系列研究表明,春化的低温作用可能在于相关基因的去甲基化,消除了FLC对开花的抑制作用,从而解除赤霉素合成途径的封锁最终导致植株在一定时期开花。     

IQM1基因过量表达对拟南芥气孔运动及根系生长的影响

拟南芥钙调素结合蛋白IQM家族共有6个成员,已证实IQM1是一个不依赖Ca2+的钙调素结合蛋白,其功能缺失突变体iqm1表现气孔开度小和根短的表型,而且突变体气孔开度并不因光、暗、脱落酸等诱导而变大或变小。该实验构建了IQM1基因双元表达载体并转化拟南芥,通过分子筛选及IQM1表达量分析,获得了IQM1基因过量表达植株。表型分析发现,IQM1过量表达植株在光诱导气孔开放处理后气孔开放度明显比野生型和iqm1-1增大,在暗诱导气孔关闭处理后气孔开度则显著变小;IQM1过量表达植株的主根比野生型和iqm1-1长,侧根数量比野生型和iqm1-1多,但IQM1过量表达对植株的生长形态、抽薹期、开花期及座果等方面却没有明显影响。研究表明,IQM1基因在植物气孔运动及根系生长中起着重要作用。     

拟南芥F-box蛋白FKF1与转录因子FUL互作调控开花研究

F-box蛋白FLAVIN-BINDING KELCH REPEAT F-BOX 1(FKF1)参与调控拟南芥光周期开花,但其分子机制尚不完全清楚。本研究通过体内和体外实验,证明FKF1与转录因子FRUITFULL(FUL)相互作用。qRT-PCR和Western blot结果显示,FKF1正调节FUL的转录水平,但不影响FUL蛋白的稳定性。遗传分析结果显示,35S-FKF1-Myc / ful-8双突变体的开花表型以及开花基因FLOWERING LOCUS T(FT)的转录水平与ful-8突变体相一致。研究结果表明FKF1可通过与FUL互作,在FUL的上游促进FT表达,进而促进开花。     

拟南芥晚花突变co-2和ft-1延迟营养生长时相转变

植物胚后发育主要分为营养生长和生殖生长两个阶段,营养生长阶段又包含幼龄期和成熟期。叶片远轴面表皮毛的出现是拟南芥营养生长时相转变的形态学标志。研究利用拟南芥晚花突变体co-2和ft-1,研究了光周期途径晚花突变对营养生长时相转变(vegetative phase change,VPC)的影响。形态学指标测定和茎端分生组织解剖特征表明,光周期途径相关的两种晚花突变体比野生型Ler晚开花近一倍的时间,莲座叶的数目也比野生型多了一倍;野生型叶片远轴面表皮毛多出现在第4片真叶上,co-2和ft-1多出现在第5片真叶上,茎顶端分生组织高宽比变异趋势亦然,说明拟南芥晚花突变延迟了营养生长时相转变。     

Genetic interactions between FLM and other flowering-time genes in Arabidopsis thaliana

FLOWERING LOCUS M (FLM) is a MADS-domain gene that acts as an inhibitor of flowering in Arabidopsis. Here we describe the genetic interaction of FLM with genes in the photoperiod and autonomous flowering pathways. Although the sequence of FLM is most similar to that of FLC, FLM and FLC interact with different flowering pathways. It has been previously shown that flc lesions suppress the late-flowering phenotype of FRI-containing lines and autonomous-pathway mutants. However, flm lesions suppress the late-flowering phenotype of photoperiod-pathway mutants but not that of FRI-containing lines or autonomous-pathway mutants. Another MADS-domain flowering repressor with a mutant phenotype similar to FLM is SVP. The late-flowering phenotype of FLM over-expression is suppressed by the svp mutation, and an svp flm double mutant behaves like the single mutants. Thus FLM and SVP are in the same flowering pathway which interacts with the photoperiod pathway. Abbreviations: CO, CONSTANS; FLC, FLOWERING LOCUS C; FLM, FLOWERING LOCUS M; FRI, FRIGIDA; GI, GIGANTEA; LD, LUMINIDEPENDENS; SVP, SHORT VEGETATIVE PHASE; FCA is not an abbreviation     

Tissue-specific and constitutive expression of a hypothetical gene At2g37610 in transgenic Arabidopsis

Hypothetical genes should play important roles in plant growth and development, although their biological functions await elucidation. One of these genes, namely At2g37610, caught our attention during the gene cloning of several salt-tolerant mutants. Promoter-GUS fusion analysis indicated a unique tissue-specific expression pattern of At2g37610 in Arabidopsis. Constitutive expression of the gene under 35S promoter caused obvious morphological changes in transgenic Arabidopsis plants, such as curled rosette leaves and bushy phenotype at maturity. Phenotypic characterization revealed that the cause of the bushy phenotype was the enhanced lateral bud outgrowth at the bottom region of the primary inflorescence, which is different from that of reported mutant plants (bushy or branched) such as max, axr1, and bus mutants. Together, these data suggest that At2g37610 is a possible novel gene related to the regulation of leaf development and shoot patterning.     

拟南芥叶形态建成基因ABL1的图位克隆及鉴定

前期研究表明ABL1可能在植物叶发育过程中扮演重要的角色,其突变表现为叶片生长迟缓、成熟叶片叶缘缺刻明显等生长缺陷特征。该研究利用图位克隆及其精细定位技术,将ABL1基因锁定在2个SSLP标记T23K8和T8F5之间,该区间包含44个基因。通过生物信息学成功找到ABL1突变基因为拟南芥FAS1,该基因编码染色质组装因子CAF1的一个亚基,在植物顶端分生组织生长调控中扮演重要角色。RT-PCR结果显示,该基因表达受阻,功能互补实验证实abl1突变体的确是FAS1基因的一个新等位突变。研究结果暗示,ABL1/FAS1在植物叶形态建成中也起着重要作用。     

A genetic and physiological analysis of late flowering mutants in Arabidopsis thaliana

Summary Monogenic mutants of the early ecotype Landsberg erecta were selected on the basis of late flowering under long day (LD) conditions after treatment with ethyl methanesulphonate or irradiation. In addition to later flowering the number of rosette and cauline leaves is proportionally higher in all mutants, although the correlation coefficient between the two parameters is not the same for all genotypes. Forty-two independently induced mutants were found to represent mutations at 11 loci. The mutations were either recessive, intermediate (co locus) or almost completely dominant (fwa locus). The loci are located at distinct positions on four of the five Arabidopsis chromosomes. Recombinants carrying mutations at different loci flower later than or as late as the later parental mutant. This distinction led to the assignment of eight of the loci to three epistatic groups. In wild type, vernalization promotes flowering to a small extent. For mutants at the loci fca, fve, fy and fpa, vernalization has a large effect both under LD and short day (SD) conditions, whereas co, gi, fd and fwa mutants are almost completely insensitive to this treatment. SD induces later flowering except for mutants at the co and gi loci, which flower with the same number of leaves under LD and SD conditions. This differential response of the mutants to environmental factors and their subdivision into epistatic groups is discussed in relation to a causal model for floral initiation in Arabidopsis thaliana.     

拟南芥ABA敏感突变体asm1的分离与鉴定

以拟南芥(Arabidopsis thaliana)为研究材料,从T-DNA突变体库中筛选分离得到1株脱落酸(ABA)敏感突变体asm1(ABA sensitive mutant 1,asm1),在含有ABA的培养基中,与野生型相比,asm1突变体的根伸长明显受到抑制,且其种子萌发结果显示asm1对ABA同样表现出敏感特性。在生长发育方面,asm1突变体抽苔时间提前,植株矮化,并且荚果长度明显小于野生型。利用远红外成像系统分析发现,在干旱胁迫下asm1突变体叶面温度高于野生型;失水率分析显示突变体失水率降低以及水分散失减少。遗传学分析表明,asm1是单基因隐性突变且与一个T-DNA插入共分离;通过图位克隆成功获得候选基因ASM1。RT-PCR结果显示,在突变体中ASM1的表达受到抑制,并且能够调控多种ABA信号通路和胁迫应答基因的表达水平。研究结果表明,ASM1可能参与调控ABA信号转导并应答干旱胁迫。     

siRNA介导的ERA1表达下调对拟南芥抗旱性的影响

ERA1是控制植物气孔开闭的一个重要基因,根据其保守域构建RNA干扰(RNAi)载体并转化拟南芥,考察转基因植株的生长、气孔导度、离体叶片失水率以及ERA1和相关基因表达,探讨siRNA介导的ERA1表达下调对拟南芥抗旱性的影响。结果表明:转基因拟南芥株系中ERA1的表达受到明显抑制,其离体叶片失水率低于野生型,但并未出现ERA1缺失突变体的负面生长表型;转基因株系对ABA处理比野生型更敏感,其ABA处理株的根长显著变短,气孔孔径更小;转基因株ABI1、ABI2、ATHB6的表达量降低,而RAB18、RD29B、ADH1的表达量升高,siRNA介导的ERA1表达下调可能会激活RAB18、RD29B等逆境响应元件。研究发现,采用RNAi技术可以有效下调ERA1表达,在没有过多负面生长表型的前提下提高拟南芥的抗旱性,且ERA1表达下调可能通过ABA途径正面影响拟南芥的抗旱性。     

拟南芥株型突变体zpr1的性状特征与基因鉴定分析

对本研究室经T-DNA插入法获得的拟南芥株型突变株系——隐性突变体zpr1植株进行植物学性状调查和遗传分析,并对该突变基因进行鉴定、表达定位和调控元件分析。结果显示:(1)性状分析表明,与野生型拟南芥Ws-2相比,突变体zpr1的茎生叶分枝数量增加,茎生叶分枝发生于拟南芥顶端花序部位;野生型拟南芥茎生叶为披针形,而突变体zpr1没有出现分枝的茎生叶呈倒卵形,出现分枝的茎生叶呈披针型;突变体zpr1的主花序高度、株高、分枝高度和分枝长度都高于野生型,且分枝数多于野生型。(2)利用质粒挽救和反向PCR法(IPCR)确定了ZPR1基因突变发生位置是该基因起始密码子上游426bp处,证明T-DNA插入破坏了ZPR1基因的启动子区域,导致该基因在拟南芥内不能正常表达。(3)基因转录调控区域的顺式作用元件分析发现在ZPR1基因的转录调控区有多个与植物激素相关的调控元件,还有与光周期调节相关的调控元件。(4)亚细胞定位发现,ZPR1基因在所有细胞中的细胞膜中表达,而在部分细胞的细胞膜、细胞质和细胞核中均有表达。研究表明,ZPR1基因的表达对植物株型发育有重要的调控作用,该基因的表达水平受植物激素和光照的调节,最终导致了植物株型的变化。     

Apple has two orthologues of FLORICAULA/LEAFY involved in flowering

Two orthologues of FLORICAULA/LEAFY, AFL1 and AFL2 (apple FLO/LFY), were isolated from the floral buds of apple trees. Their expression was detected in various tissues and during differentiation of the floral buds. Furthermore, the flowering effectiveness of each gene was assessed with transgenic Arabidopsis. Both AFL1 and AFL2 showed high homology to each other (90%) and a high degree of similarity to PTLF and PEAFLO (70%), which are homologues of FLO/LFY from poplar and pea, respectively. RNA blot analysis showed that AFL1 was expressed only in the floral bud during the transition from vegetative to reproductive growth, whereas AFL2 was expressed in vegetative shoot apex, floral buds, floral organs and root. Genomic Southern analysis showed that apple had other homologues in addition to AFL1 and AFL2. The transgenic Arabidopsis with over-expressed AFL2 showed accelerated flowering and gave rise to several solitary flowers from rosette axils directly. AFL1 had similar effects, but the phenotypes of the transgenic Arabidopsis with AFL1 were weaker than those with AFL2. These results suggest that both genes are involved in flower differentiation in apple.