利用交换接头技术构建大麦条纹花叶病毒新疆株RNA_2的全长cDNA克隆

本文采用双股交换接头(Crossover linker)技术对已建立的大麦条纹花叶病毒新疆株(BSMV-XJ)RNA_2 cDNA重组质粒pUBS_(112)进行修饰。使cDNA两端不必要的poly(dG):poly(dC)尾准确地缺失,同时补上了cDNA中相对于RNA_2 5’端区缺少的三个核苷酸TAA,并在cDNA末端插入了预定的限制酶切顺序。通过原位杂交筛选、酶切图谱分析、cDNA两端序列测定等手段,证明已获得BSMV-XJ RNA_2组分的全长cDNA克隆。     

人成纤维细胞成纤维蛋白质cDNA片段的分离及亚克隆

我们用噬菌斑原位杂交的方法从人成纤维细胞cDNA基因库(λNMT-pCD-cDNA重组体)中分离到一株成纤维蛋白质cDNA克隆。经限制性内切酶酶切电泳及吸印转移法分析证明这是一个成纤维蛋白质cDNA片段克隆,并进一步将此cDNA片段克隆到pBR322质粒上。     

黄芪UGPase cDNA克隆、分析及其在大肠杆菌中的表达

在已报道的UGPase的植物cDNA序列基础上,从膜荚黄芪( Astragalus membranaceus (Fisch.) Bunge)毛状根中分离了此酶的cDNA.此cDNA全长为1 831 bp,推测编码分子量为51.5 kD、等电点为6.01的由471个氨基酸残基组成的多肽.将此cDNA的开放阅读框载入质粒pET28(a)+并转入大肠杆菌( Escherichia coli ) BL21.SDS-PAGE表明此酶已经在 E.coli 中获得大量表达,表达量约为总细菌蛋白的40%.酶活分析表明,转化菌中UGPase 的活性比非转化菌高0.50～3.27倍,证明此cDNA可以在原核生物中获得表达.Northern blot表明UGPase在黄芪的根、茎、叶及毛状根中均有表达,在根及毛状根中表达量较高,证明了此酶主要分布于植物贮藏组织的报道.     

RT-PCR克隆人纤溶酶cDNA大片段

目的:以人胎儿肝脏总RNA为模板,克隆人纤溶酶(plasmin)cDNA大片段。方法:采用异硫氰酸胍一步法提取总RNA,RT-PCR技术获取目的基因。结果:成功地扩增出1.74kb的人纤溶酶基因,并研究了扩增人纤溶酶cDNA大片段的特定实验条件。结论:为克隆cDNA大片段研究提供了简便、快速的方法。     

中国红豆杉紫杉烯合酶cDNA的分离、表达和鉴定

紫杉烯合酶是一种二萜环化酶,催化牛儿基牛儿基焦磷酸形成紫杉醇生物合成过程中的中间体紫杉烯.利用PCR扩增同源探针筛选cDNA文库,克隆了一个编码中国红豆杉(Taxus chinensis (Pilg.) Rehd.)紫杉烯合酶3′端的2 151 bp的cDNA片段,也通过PCR扩增得到了该基因5′端的611 bp的cDNA片段,将这两个cDNA片段拼接在一起,得到长2 712 bp的cDNA片段,具有一个2 586个碱基的开放阅读框架(ORF),编码包括质体转移肽在内的共862个氨基酸残基;该酶与太平洋红豆杉紫杉烯合酶有97%的同源性(identity),与其他植物萜类环化酶也有较高的同源性.利用融合表达载体pET-32a在大肠杆菌BL21trxB中表达,所表达的融合蛋白以包含体形式存在.包含体经过变性、复性和再折叠,利用His残基亲和凝胶柱层析得到融合的紫杉烯合酶.用毛细管气相色谱-质谱联用对酶促反应产物进行分析,结果表明,融合的紫杉烯合酶能催化产生4(5),11(12)-紫杉烯.     

青蒿鲨烯合酶基因的克隆、结构分析与大肠杆菌表达

用RT-PCR方法从青蒿(Artemisia annua L.)中克隆了一个1 539 bp全长鲨烯合酶cDNA.青蒿鲨烯合酶氨基酸序列与拟南芥、烟草、人类、酵母鲨烯合酶的一致性分别为70%、77%、44%和39%.青蒿鲨烯合酶基因组DNA结构很复杂,包括14个外显子和13个内含子.全长的或C末端截短的鲨烯合酶cDNA被克隆进原核表达载体pET30a并在大肠杆菌(Escherichia coli) BL21(DE3)中诱导表达.但在含有全长的鲨烯合酶cDNA的大肠杆菌中并没有观察到预期大小的鲨烯合酶表达,而C末端截短疏水区30个氨基酸的鲨烯合酶可在大肠杆菌中过量表达.     

苜蓿豆血红蛋白互补脱氧核糖核酸(cDNA)的合成及其无性繁殖

本文介绍了 cDNA 合成的详细方法。用苜蓿豆血红蛋白 poly A( )mRNA 作模板,在反转录酶作用下合成单股 cDNA(ss-cDNA),然后在 E.coli DNA 聚合酶 I 作用下合成双股 cDNA(ds-cDNA)。采用同聚物尾接方法和合成的内切酶寡核苷酸衔接物连接方法,将 ds-cDNA 与质粒 pBR322 DNA 重组,进行转化,得到对氨苄青霉素抗性(Amp~r)和四环素敏感(TeL~s)的75个转化子。经 cDNA-mRNA 的杂交选择和无细胞体外转译的初筛结果,有两个转化子具有与苜蓿豆血红蛋白 mRNA 有同源性的 cDNA。这种 cDNA 的性质有待于进一步研究.     

中国红豆杉紫杉烯合酶cDNA的分离、表达和鉴定

紫杉烯合酶是一种二萜环化酶 ,催化牛儿基牛儿基焦磷酸形成紫杉醇生物合成过程中的中间体紫杉烯。利用PCR扩增同源探针筛选cDNA文库 ,克隆了一个编码中国红豆杉 (Taxuschinensis (Pilg .)Rehd .)紫杉烯合酶 3′端的 2 15 1bp的cDNA片段 ,也通过PCR扩增得到了该基因 5′端的 6 11bp的cDNA片段 ,将这两个cDNA片段拼接在一起 ,得到长 2 712bp的cDNA片段 ,具有一个 2 5 86个碱基的开放阅读框架 (ORF) ,编码包括质体转移肽在内的共 86 2个氨基酸残基 ;该酶与太平洋红豆杉紫杉烯合酶有 97%的同源性 (identity) ,与其他植物萜类环化酶也有较高的同源性。利用融合表达载体pET_32a在大肠杆菌BL2 1trxB中表达 ,所表达的融合蛋白以包含体形式存在。包含体经过变性、复性和再折叠 ,利用His残基亲和凝胶柱层析得到融合的紫杉烯合酶。用毛细管气相色谱 质谱联用对酶促反应产物进行分析 ,结果表明 ,融合的紫杉烯合酶能催化产生 4(5 ) ,11(12 )_紫杉烯     

白皮黄瓜鲨烯合酶基因cDNA克隆及生物信息学分析

为认识葫芦科植物中葫芦素生物合成途径所需鲨烯合酶基因结构特征,克隆白皮黄瓜鲨烯合酶(squalene synthase,SS)基因c DNA并进行生物信息学分析。根据葫芦科植物绞股蓝、罗汉果、红花栝楼等的鲨烯合酶基因cDNA序列,设计白皮黄瓜鲨烯合酶引物,分别采用3'RACE和5'RACE技术扩增鲨烯合酶基因3'端和5'端。获得白皮黄瓜鲨烯合酶基因的两个cDNA克隆,命名为CsSS1和CsSS2,其cDNA序列全长分别为1 627 bp和1 534 bp,都编码417个氨基酸残基,分子质量为47.6 k D。成功克隆得到白皮黄瓜鲨烯合酶基因全长cDNA序列并对其进行序列分析,后续可用于葫芦素生物合成途径所需鲨烯合酶基因正选择位点功能分析。     

计算机在确定牛病毒性腹泻病毒基因组常用限制性内切酶位点中的应用

应用计算机测定71种限制性内切酶在牛病毒性腹泻病毒NADL株(BVDV NADL)基因组的cDNA核苷酸序列中酶切位点,结果表明其中S8种酶的酶切位点所在的核苷酸序列数,也表明了其中13种限制性内切酶在核苷酸序列中无酶切位点。这些结果有助于进一步研究BVDV InL株的cDNA基因库。     

比利时杜鹃花RhDFR基因克隆及分析

二氢黄酮醇-4-还原酶(DFR)是植物花青素合成过程中的关键酶,能够催化二氢黄酮醇生成无色花青素。该试验以红色和白色比利时杜鹃花(Rhododendron hybridum Hort.)不同器官和不同发育时期的花瓣为实验材料,利用反转录(RT-PCR)和RACE技术克隆RhDFR基因,利用植物酶联免疫试剂盒(ELISA)测定不同发育时期的花瓣RhDFR酶活性,利用qRT-PCR技术定量分析不同器官和不同发育时期的花瓣RhDFR基因,构建pET-28a-RhDFR原核表达载体对RhDFR蛋白进行制备和纯化,为进一步探究杜鹃花DFR基因功能以及花色的分子机理奠定基础。结果表明：(1)成功获得比利时杜鹃花RhDFR基因全长1 253 bp,其开放阅读框1 035 bp,编码344个氨基酸,含有1个NADPH结合保守基序和1个底物结合区域,具有高度保守性;系统进化分析显示,比利时杜鹃花RhDFR蛋白与越橘(Vaccinium corymbosum)DFR蛋白亲缘关系最近。(2)ELISA试剂盒分析显示,比利时杜鹃花不同发育时期的花瓣DFR酶活性呈先上升后下降的趋势,并于红花初开期和白花盛开期的...     

The <Emphasis Type="Italic">paleoAP3</Emphasis>-type gene <Emphasis Type="Italic">CpAP3</Emphasis>, an ancestral B-class gene from the basal angiosperm <Emphasis Type="Italic">Chimonanthus praecox</Emphasis>, can affect stamen and petal development in higher eudicots

Wintersweet (Chimonanthus praecox), a basal angiosperm endemic to China, has high ornamental value for developing beautiful flowers with strong fragrance. The molecular mechanism regulating flower development in wintersweet remains largely elusive. In this project, we seek to determine the molecular features and expression patterns of the C. praecox paleoAP3-type gene CpAP3 and examine its potential role in regulating floral development via ectopic expression in Arabidopsis thaliana and Petunia hybrida. The expression of CpAP3 is tissue-specific, with the highest level in the tepals, moderate level in carpels, and weak levels in stamen and vegetative stem tissues. Its dynamic expression during flowering is associated with flower-bud formation. Ectopic expression of CpAP3 partially rescued stamen development in ap3 mutant Arabidopsis. Although no phenotypic effect has been observed in wild-type Arabidopsis, CpAP3 overexpression in petunia brought rich morphological changes and homeotic conversions to flowers, mainly involving disruption of petal and stamen development. Expressed in a broader range than those canonical B-function regulators, the ancestral B-class gene CpAP3 can affect petal and stamen development in higher eudicots. This gene also holds some bioengineering potential in creating novel floral germplasms.     

MORPHOLOGICAL STUDIES OF THE NYMPHAEACEAE (SENSU LATO). XIII. CONTRIBUTIONS TO THE VEGETATIVE AND FLORAL STRUCTURE OF CABOMBA

Six species of Cabomba have been examined although the anatomy of the vegetative axes is based on the study of only C. caroliniana and C. palaeformis. A plant consists of an erect short shoot with decussate leaves which bears axillary flowering shoots and rhizomes. A rhizome bears decussate leaves and may also form axillary flowering shoots or turn upward and become a new short shoot. The phyllotaxies of the flowering shoots are proximately decussate or ternate (C. piauhyensis). The flowering shoots with decussate phyllotaxy change to 1/3 phyllotaxy distally; they bear axillary flowers proximally, and extra-axillary flowers distally. Flowering shoots with ternate phyllotaxy do not change distally but each produces first axillary and then extra-axillary flowers. Decussate vegetative axes and flowering shoots have four vascular bundles; ternate vegetative axes and flowering shoots have six vascular bundles, distantly paired into two or three vascular bundle-pairs, respectively. An elliptical vascular plexus occurs at each node. Each leaf receives one bundle-pair from one trace and each flower three bundle-pairs. A two-level receptacular vascular plexus occurs in flowers; the proximal, larger portion provides traces to perianth and stamens and the distal, smaller portion becomes carpellary traces. Each of the three sepals typically receives five branch traces from a basal principal trace, and each of the three petals receives, typically, three branch traces from a basal principal trace. Sepals and petals generally occur in a single, basally connate whorl. Each stamen receives one trace. Each stamen of three-stamen flowers is opposite a petal; each stamen of six-stamen flowers is aligned with an interval between a petal and adjacent sepal. Each staminal trace, which is just above the principal petal trace, in a three-petal flower, is frequently adnate to the latter trace. Each carpel receives one principal trace from the distal, small extension of the receptacular plexus, and each principal trace becomes three conventional veins of a carpel. Ovules may be borne directly over one of the veins or in any position between veins and are supplied by branches of the nearest vein or nearest two veins. All traces, ovular supply veins and the proximal portions of all veins are amphicribral. The several anatomical and morphological differences in vegetative axes and flowers between Cabomba and Brasenia suggest a greater taxonomic distance between the two genera than commonly supposed. It is suggested that extra-axillary flowers in 1/3 helical and ternate flowering shoots of Cabomba might be advantageous in preventing anthesis of flowers beneath peltate leaves. The aberrant position might be the initial evolutionary step toward what, in other nymphaeaceous genera, has shifted each flower to an adjacent helix. It is proposed that the zigzag stem accompanying the trigonal and sympodial flowering shoots may offer greater stability and floatability in water than the monopodial form. Several suggestions are offered for the variability of ovular positions: 1) the variability is a vestige of former laminar placentation in conduplicate carpels; 2) it is a vestige of a primitive condition antedating the current close association of ovules with ventral carpellary veins; 3) it is an early stage of evolution which might have terminated in laminar placentation and cantharophily, but which was replaced by a trend toward myophily.     

月季花瓣数量遗传分析

以‘窄叶藤本月季花’(Rosa chinensis‘Zhaiye Tengben Yuejihua’)ב月月粉’(R.chinensis‘Old Blush’)杂交群体为材料,分析其花瓣数量的分离特点,对单瓣花与重瓣花的花芽分化过程进行观察,并对花瓣、雄蕊及瓣化雄蕊进行表皮细胞超微结构的观察。结果显示:杂交群体的花瓣数量分离明显,出现从5~54片的连续变异;花瓣数量、瓣化雄蕊数量、雌蕊数量的遗传模型为2MG-AD(2对加性-显性-上位性主基因控制),雄蕊数量的遗传模型为0MG(无主基因控制);月季重瓣花形成的原因为雄蕊瓣化,重瓣花形成的关键时期为雄蕊原基形成后期,可见到雄蕊瓣化为花瓣的现象;月季瓣化雄蕊的表皮细胞形态、褶皱程度介于单瓣花花瓣和重瓣花外轮花瓣之间。     

Spatial fragrance patterns in flowers of Silene latifolia: Lilac compounds as olfactory nectar guides?

Floral odour can differ qualitatively and quantitatively between different parts of the flowers, and these spatial fragrance patterns within the flowers can be used by pollinators for orientation on flowers. Here we present results of spatial fragrance patterns within flowers of the dioecious Silene latifolia (Caryophyllaceae). Volatiles were collected and analysed using a highly sensitive dynamic headspace method, which allows dramatically reducing the sample time. From all flower parts, especially the petals and the anthophore emitted the typical flower volatiles of S. latifolia. However, compounds emitted from the petals differed from compounds emitted by the anthophore. The anthophore emitted the monoterpenoids lilac aldehydes and alcohols, whereas, all other typical scent compounds (e.g. benzoids, other monoterpenoids) were emitted by the petals. Lilac aldehydes are known to be behaviourally very attractive for noctuid moths, and they may serve as nectar guides in S. latifolia.     

The AGL6-like Gene CpAGL6, a Potential Regulator of Floral Time and Organ Identity in Wintersweet (Chimonanthus praecox)

Wintersweet (Chimonanthus praecox), a deciduous aromatic shrub endemic to China, has high ornamental value for developing beautiful flowers with strong fragrance. The transition from the vegetative to the reproductive phase in wintersweet takes 4-5 years. The molecular mechanism regulating flower development in this basal angiosperm is largely unknown. Here we characterized the molecular features and expression patterns of the C. praecox AGL6-like gene CpAGL6 and investigated its potential role in regulating floral time and organ development via ectopic expression in Arabidopsis thaliana. The expression of CpAGL6 is highly tissue-specific, with the highest level in the middle tepals, moderate levels in inner tepals and carpels, and weak levels in stamen and young leaf tissues. Its dynamic expression in the flower is coincident with tepal opening. Ectopic expression of CpAGL6 in Arabidopsis retarded the vegetative growth and led to precocious flowering, mainly correlated with the inhibition of the floral repressor FLC and promotion of the floral promoters AP1 and FT. Although no ectopic floral organs have been observed, transgenic plants exhibited abnormal stamen and carpel development in later-developing flowers, with fertility reduced to varying degrees. These results suggest that CpAGL6, the AGL6-like gene from the basal angiosperm C. praecox, is a potential E-function regulator involved in specifying floral time and organ identity, functionally homologous to those AGL6-like genes from higher eudicots and monocots.     

Evolution of flower shape in <Emphasis Type="Italic">Plantago lanceolata</Emphasis>

Plantago lanceolata produces small actinomorphic (radially symmetric), wind-pollinated flowers that have evolved from a zygomorphic, biotically pollinated ancestral state. To understand the developmental mechanisms that might underlie this change in flower shape, and associated change in pollination syndrome, we analyzed the role of CYC-like genes in P. lanceolata. Related zygomorphic species have two CYC-like genes that are expressed asymmetrically in the dorsal region of young floral meristems and in developing flowers, where they affect the rate of development of dorsal petals and stamens. Plantago has a single CYC-like gene (PlCYC) that is not expressed in early floral meristems and there is no apparent asymmetry in the pattern of PlCYC expression during later flower development. Thus, the evolution of actinomorphy in Plantago correlates with loss of dorsal-specific CYC-like gene function. PlCYC is expressed in the inflorescence stem, in pedicels, and relatively late in stamen development, suggesting a novel role for PlCYC in compacting the inflorescence and retarding stamen elongation in this wind pollinated species.     

B-class MADS-box genes in trioecious papaya: two paleoAP3 paralogs, CpTM6-1 and CpTM6-2, and a PI ortholog CpPI

In the ABC model of flower development, B function organ-identity genes act in the second and third whorls of the flower to control petal and stamen identity. The trioecious papaya has male, female, and hermaphrodite flowers and is an ideal system for testing the B-class gene expression patterns in trioecious plants. We cloned papaya B-class genes, CpTM6-1, CpTM6-2, and CpPI, using MADS box gene specific degenerate primers followed by cDNA library screening and sequencing of positive clones. While phylogenetic analyses show that CpPI is the ortholog of the Arabidopsis gene PI, the CpTM6-1 and CpTM6-2 loci are representatives of the paralogous TM6 lineage that contain paleoAP3 motifs unlike the euAP3 gene observed in Arabidopsis. These two paralogs appeared to have originated from a tandem duplication occurred approximately 13.4 million year ago (mya) (bootstrap range 13.36 ± 2.42). In-situ hybridization and RT-PCR showed that the papaya B-class genes were highly expressed in young flowers across all floral organ primordia. As the flower organs developed, all three B-class genes were highly expressed in petals of all three-sex types and in stamens of hermaphrodite and male flowers. CpTM6-1 expressed at low levels in sepals and carpels, whereas CpTM6-2 expressed at a low level in sepals and at a high level in leaves. Our results showed that B-class gene homologs could function as predicted by the ABC model in trioecous flowers but differential expressions of CpTM6-1, and CpTM6-2, and CpPI suggested the diversification of their functions after the duplication events. Christine M. Ackerman, Qingyi Yu contributed equally to this work.