987 resultados para gene transformation
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In this study, the background activity of beta-glucuronidase (GUS) was analyzed histochemically and fluorometrically in the negative control of Laminaria japonica (Phaeophyta) thalli, showing low level of activity. GUS gene transformation without selectable gene in L. japonica was performed using four different promoters, i.e., Cauliflower mosaic virus 35S promoter (CaMV35S) from cauliflower mosaic virus, ubiquitin promoter (UBI) from maize, adenine-methyl transfer enzyme gene promoter (AMT) from virus in green alga Chlorella, and fucoxanthin chlorophyll a/c-binding protein gene promoter (FCP) from diatom Phaeodactylum tricornutum. The GUS transient activity was determined fluorometrically after bombarding sliced parthenogenetic sporophytes explants, and it was found that the activity resulting from CaMV35S and FCP promoters (in 114.3 and 80.6 pmol MU min(-1) (mg protein)(-1), respectively) was higher than for the other two promoters. The female gametophytes were bombarded and regenerated parthenogenetic sporophytes. FCP was the only promoter that resulted in detectable GUS chimeric expression activity during histochemical staining and polymerase chain reaction. Results of Southern blot showed that GUS gene was integrated with the L. japonica genome.
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The first topic area of this thesis involved studies on the accumulation and translocation of glucosinolates (GSs), bioactive secondary plant compounds, in broccoli plants. Changes in GS accumulation and gene expression levels in response to exogeneous methyl jasmonate (MeJA) treatment were analyzed in different tissue types at different developmental stages of broccoli. Greater accumulation of GSs with MeJA treatment was observed in apical leaves of broccoli seedlings and florets of plants at harvest maturity. Increases in indolyl GS in apical leaves of seedlings and florets were coupled with the up-regulation of indolyl GS biosynthesis genes. The accumulation of indolyl GSs appears to be modulated by MeJA treatment in an organ-specific manner for optimal distribution of defense substances in the plant. Metabolic profiling of hydrophilic metabolites using GC-MS demonstrated increased accumulation of various phenolics, ascorbates and amino acids in broccoli tissues after MeJA treatment. Distinct changes in carbohydrate levels observed between different tissues (vegetative leaves and floret tissues) of broccoli plants after treatment suggest that carbon metabolism is differentially modulated by MeJA treatment in different tissue types depending on sink-source relationships. Reduced levels of hexose sugars and tricarboxylic acid intermediates after MeJA treatment may reflect the increased requirement for carbon and energy needed to drive secondary product biosynthesis to accumulate metabolites for defense against insects and other herbivores. Substantial increases of indolyl and aromatic GSs after exogenous treatment with MeJA in stem and petioles of seedlings and the existence of intact indolyl-GS forms in phloem exudates suggest enhanced de novo synthesis in combination with active transport. Indoly GSs share structural similarities with the auxin, IAA, and may interact with components of the auxin transport system for intra- and extra-cellular transport or translocation. Application of the auxin efflux inhibitor, 1-naphthylphthalamic acid (NPA) reduced MeJA-mediated accumulation of indolyl GSs in broccoli florets and seedling tissues. NPA did not inhibit expression of indolyl GS biosynthesis genes shown to be upregulated by MeJA treatment or the accumulation of tryptophan, the amino acid precursor of indolyl GSs. Exogenous application of benzyl GS to Arabidopsis roots induced ectopic expression of the PIN1 protein associated with the auxin transport system similar to treatment with NPA, again suggesting GS interaction with the auxin efflux carrier system. The inhibitory effect of NPA on MeJA-mediated accumulation of GS may be due to competitive binding of NPA to auxin efflux carrier components and that GS transport is mediated by the auxin transport system. The inhibitory effect of NPA on indolyl and aromatic GS accumulation and the bioactivity of exogenous treatment of these GS compounds in PIN1 localization, Arabidopsis root growth, and gravitrophic response suggest that indolyl and aromatic GSs may be antagonistic to IAA transport and biosynthesis. Indolyl and aromatic GSs can also be potentially converted into IAA by hydrolysis. This intrinsic feature of GSs may be the part of a sophisticated regulatory process where the metabolic pathways in the plant shift from active growth to a reversible defense posture in response to biotic or abiotic stress. It seems likely that indolyl and aromatic GSs are important compounds that provide connections between jasmonate and auxin signaling. Further studies are required to reveal the regulatory mechanism for crosstalk between the two hormones. The third part of this research was to investigate effect of selenium fertilization and MeJA treatment on accumulation of GSs in broccoli florets. Increasing dietary intake of the element selenium (Se) has been shown to reduce the risk of cancer. Simultaneous enhancement of both Se and GS concentrations in broccoli floret tissue were conducted through the combined treatment of MeJA with Se fertilization. A low level of Se fertilization (concentration) with MeJA treatment displayed no significant changes in total aliphatic GS concentrations with 90% and 50% increases in indolyl and total GSs concentrations, respectively. This result suggests that Se- and GS-enriched broccoli with improved health-promoting properties can be generated by this combined treatment. The second topic of this thesis was conducted to provide basic information required to improve biomass quality and productivity and develop tools for gene transformation in Miscanthus x giganteus. The perennial rhizomatous grass, Miscanthus x giganteus is an ideal biomass crop due to its rapid vegetative growth and high biomass yield potential. As a naturally occurring sterile hybrid, M. x giganteus must be propagated vegetatively by mechanicalling divided rhizomes or from micropropagated plantlets. The effect of callus type, age and culture methods on regeneration competence was studied to improve regeneration efficiency and shorten the period of tissue culture in M. x giganteus propagation. Seven lignin biosynthesis genes and one putative flowering gene were isolated from M. x giganteus by PCR reactions using maize othologous sequences. Southern hybridization and nuclear DNA content analysis indicated that the genes isolated from M. x giganteus exist in the genome of other Miscanthus species as multiple copies. Analysis of lignin content and histological staining of lignin deposition indicated that higher lignin content is found in mature stem node tissues compared to young leaves and apical stem nodal tissues. Cell wall lignification is associated with increasing tissue maturity in Miscanthus species. RNAi and antisense constructs harboring sequences of these genes were developed to generate Miscanthus transgenic plants with suppressed of lignin biosynthesis and delayed flowering.
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The development of biotechnology techniques in plant breeding and the new commercial applications have raised public and scientific concerns about the safety of genetically modified (GM) crops and trees. To find out the feasibility of these new technologies in the breeding of commercially important Finnish hardwood species and to estimate the ecological risks of the produced transgenic plants, the experiments of this study have been conducted as a part of a larger project focusing on the risk assessment of GM-trees. Transgenic Betula pendula and Populus trees were produced via Agrobacterium mediated transformation. Stilbene synthase (STS) gene from pine (Pinus sylvestris) and chitinase gene from sugar beet (Beta vulgaris) were transferred to (hybrid) aspen and birch, respectively, to improve disease resistance against fungal pathogens. To modify lignin biosynthesis, a 4-coumarate:coenzyme A ligase (4CL) gene fragment in antisense orientation was introduced into two birch clones. In in vitro test, one transgenic aspen line expressing pine STS gene showed increased resistance to decay fungus Phellinus tremulae. In the field, chitinase transgenic birch lines were more susceptible to leaf spot (Pyrenopeziza betulicola) than the non-transgenic control clone while the resistance against birch rust (Melampsoridium betulinum) was improved. No changes in the content or composition of lignin were detected in the 4CL antisense birch lines. In order to evaluate the ecological effects of the produced GM trees on non-target organisms, an in vitro mycorrhiza experiment with Paxillus involutus and a decomposition experiment in the field were performed. The expression of a transgenic chitinase did not disturb the establishment of mycorrhizal symbiosis between birch and P. involutus in vitro. 4CL antisense transformed birch lines showed retarded root growth but were able to form normal ectomycorrhizal associations with the mycorrhizal fungus in vitro. 4CL lines also showed normal litter decomposition. Unexpected growth reductions resulting from the gene transformation were observed in chitinase transgenic and 4CL antisense birch lines. These results indicate that genetic engineering can provide a tool in increasing disease resistance in Finnish tree species. More extensive data with several ectomycorrhizal species is needed to evaluate the consequences of transgene expression on beneficial plant-fungus symbioses. The potential pleiotropic effects of the transgene should also be taken into account when considering the safety of transgenic trees.
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本文应用聚合酶链式反应技术(PCR)在体外从玉米基因组中扩增富于含硫氨基酸的10KD玉米醇溶蛋白基因、克隆及序列分析结果,并用该基因转化豆科牧草百脉根以期获得有良好营养平衡的转基因牧草,从玉米无菌苗提取大片段的DNA.根据目的基因两端的DNA顺序合成一对引物,利用PCR技术经30个活环DNA扩增,得到了一特异的0.57Kb片段,克隆后对该片段进行限制性内切酶物理图谱分析并测定了其全部编码区序列.结果表明,克隆到的完整的10 Kd玉米醇溶蛋白基因编码区与国外报道的相比,其核苷酸顺序及推测的氧基酸序列同源率分别为96%和90%.将基因分别置于质粒pKYLX5及pKYLX71表达戴体,构建了分别在rbcS及CaMV 35S启动子调控下的10 KD zein基因的嵌合质粒.列用农杆菌介导的叶盘法及茎切段法,选用百脉根( Lotus corniculatus)品种一名分别为“里澳”及“马库”,以5-10天的无菌苗子叶和茎切段为外植体,进行基因转化,在含50mg/L km的MS培养基上,2-3周获得抗性的芽,将芽转到无激素的MS培养基上诱导生根,获得抗性植株,捡测工作正在进行中。
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本工作用BT基因、PinⅡ基因和bar基因对青饲玉米、谷子进行了基因转化的研究,并且对转基因的受体、转基因的方法、转化后的筛选、检测及植株再生等问题进行了探讨。 玉米胚性细胞系,包括胚性愈伤组织和胚性细胞悬浮系,可作为基因转化的受体,它亦是原生质体培养的关键。玉米的基因型对胚性细胞系的获得有很大的影响。在相同的培养条件下,九个青饲玉米品系都得到了I型愈伤组织,但仅有两个品系(232和235)得到了胚性细胞系(L32和L35)。幼胚的长度及年龄也是影响诱导形成胚性愈伤组织的一个重要因素,最佳胚长是1-1.5mm,最佳胚龄是授粉后10-12天的幼胚。另外,适当提高蔗糖浓度对胚性细胞悬浮系的建立及保持均有好处。 从玉米原生质体培养获得了再生植株.在此基础上用电激法和PEG法将BT基因导入玉米原生体,发现在原生质体培养过程中,同对照相比,第一次细胞分裂及形成愈伤组织的时间往后推移. 诱导玉米I型愈伤组织没有基因型的限制,可以从大多数玉米品系中得到。并且玉米I型愈伤组织具有极强的分化能力.我们将玉米I型愈伤组织作为基因枪法转化的受体,获得了转基因工程植株。目前,尚未见这方面的报道. 基因枪法转化玉米胚性细胞系,得到抗性愈伤组织的效率约为1/40。用直径约3mm的玉米I型愈伤组织块作基因枪法转化受体,转化后经筛选平均每块可得到1-4个抗性愈伤组织系。用PEG和电激法转化玉米原生质体,转化后原生质体再生愈伤组织中,抗性愈伤组织的得率为9.3%和8.9%, 基因枪法适应完整的细胞和组织的转化,可较快得到抗性植株,在玉米基因转化研究中, 为了较快地得到转化植株,用基因枪法较电激法和PEG法更好,在玉米三种基因转化的受体中(原生质体、胚性细胞系和I型愈伤组织),以I型愈伤组织作受体最好,用它作受体可以避免原生质体培养的困难,克服获得胚性细胞系的基因型的限制。 胚性细胞系对抗菌素的耐受性随继代时间增长而增加.I型愈伤组织对抗菌素的耐受性 同愈伤组织块的大小呈正相关。 由于玉米愈伤组织对卡那霉素的本底抗性较高,所以需要用高浓度(800mg/L)的卡那霉 素进行筛选,过高的选择压力对芽的分化有抑制作用.用电激和PEG处理后的原生质体再生的愈伤组织,经卡那霉素筛选出的抗性愈伤组织未能得到再生植株。而对照则得到了再生植株。用PPT和Hyg筛选出的抗性愈伤组织得到了再生植株. 用PCR和Southern杂交对抗性愈伤组织和再生植株进行检测,证明外源基因已整合到 玉米基因组中。得到了携有BT基因、bar基因或PinⅡ基因的愈伤组织或工程植株。 用豫谷一号的幼穗诱导获得了胚性愈伤组织,基因枪转化后,经PPT筛选得到抗性愈伤组织。每个5cm的培养皿内装有谷子胚性愈伤组织约0.5g,经筛选后可得到5-10块抗性愈伤组织,此PPT抗性的愈伤组织用PCR和Southern杂交检测,证明bar基因已整合到了谷子的基因组中。从转化愈伤组织中已分化出了再生植株。
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植物血红蛋白在共生固氮根瘤中主要是对固氮酶进行嫌氧保护,确保固氮酶活性,在植物根中协助氧的运输或作为感觉氧压的信号分子.豆科植物凝集素功能之一是对相应专一的根瘤菌有识别作用,并有利于根瘤菌的聚集和侵染。本论文将非豆科结瘤植物Parasponia andersonii血红蛋白基因及豌豆凝集索基因转入水稻,目的是此二基因表达后,豌豆凝集素可聚集、识别豌豆根瘤菌,并有助于它们的侵染,血红蛋白则可对根瘤菌固氮酶进行嫌氧保护,保障其发挥固氮作用,从而为实现水稻结瘤和固氮打下初步基础。 本论文将带有Parasponia血红蛋白基因的pL305质粒,带有潮霉素磷酸转移酶基因及Parasponia血红蛋白基因的农杆菌双元载体质粒pLX412-Hb用花粉管通道法转化水稻l用pLX412-Hb和带有Bar基因、豌豆凝集素基因、Parasponia血红蛋白基因的质粒pLHB用基因枪法转化水稻幼胚及愈伤组织,带有pLX412-Hb的Agrobactmum tumefaciens LBA4404转化烟草,得到如下结果: 1.用pL305质粒花粉管通道法转化水稻,运作1512朵花,得到707粒种子.将230粒种子萌发,发芽220粒;白化苗4株,成苗206株;计发芽率96%,白化苗率1.7%,成苗率90%。取120株提取DNA以Parasponia血红蛋白基因为探针进行点杂交,有6株为阳性结果,阳性率5%.再取4株DNA点杂交阳性植株DNA,以Parasponia血红蛋白基因为探针进行Southem杂交,有3株有阳性结果,阳性率为75%,照此推算转化植株约占总植株的4%.目前,这些转基因植株已开花结实。 2.用pLX412-Hb质粒花粉管通道法转化水稻,运作743朵花,得到340粒种子。将120粒种子萌发,发芽117粒,白化苗3株,成苗111株;计发芽率97. 5%,白化苗率2. 5%,成苗率92. 5%.取30株提取DNA以Parasponia血红蛋白基因为探针进行点杂交,有4株为阳性结果,阳性率13%。再取4株DNA点杂交呈阳性的植株DNA,以Parasponia血红蛋白基因为探针进行Southern杂交,有2株有阳性结果,阳性率为50%,照此推算转化植株约占总植株的7%。目前部分转基因植株巳开花结实. 3.用pLX412 - Hb质粒基因枪法转化水稻幼胚及愈伤组织,抗性筛选得到15株再生植株,以Parasponia血红蛋白基因为探针进行点杂交,有14株为阳性结果,阳性率93%.取7株DNA点杂交呈阳性的植株DNA,以Parasponia血红蛋白基因为探针进行Southern杂交,都为阳性结果,阳性率为100%,照此推算转化植株约占总植株的93%.目前,部分转基因植株已开花结实. 4.用pLX412 -Hb质粒通过Agrobacterrum tumeFaciens LBA4404转化烟草,抗性筛选得到的再生植株以Parasponia血红蛋白基因为探针进行Southern杂交,结果为阳性. 5.用pLHB基因枪法转化的愈伤组织,抗性筛选得到已分化出绿芽点的愈伤组织,以Parasponia血红蛋白基因为探针或以豌豆凝集素基因为探针进行Southern杂交,杂交结果均为阳性. 6.最近国外巳发现大麦有血红蛋白基因.本论文以大麦血红蛋白cDNA为探针对未转基因的水稻进行Southern杂交,结果有阳性带。说明水稻有与大麦血红蛋白基因高度同源序列。以Parasponia血红蛋白基因为探针时杂交结果为阴性,说明水稻血红蛋白基因与Parasponiaa血红蛋白基因核苷酸序列相差较大. 7.提取Southern杂交证明有Parasponia血红蛋白基因整合的水稻根及叶总RNA,以Parasponia血红蛋白基因cDNA为探针进行RNA点杂交,结果根总RNA为阳性,叶总RNA为阴性。初步证明Parasponia血红蛋白基因在水稻根中表达。 8.提取未转基因的水稻根及叶RNA,以大麦血红蛋白基因cDNA为探针进行RNA点杂交,结果:根总RNA为阳性结果,叶总RNA为阴性结果.初步证明水稻血红蛋白基因在水稻根中表达。 总之,本论文证明已将Parasponia血红蛋白基因整合进水稻植株染色体,将豌豆凝集素基因、Parasponia血红蛋白基因整合进水稻愈伤组织染色体,初步证明水稻有血红蛋白基因,内外源血红蛋白基因都有组织特异性表达,从而为本研究的战略设想奠定初步基础。
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谷子是我国北方具有区域重要性的禾谷类粮食作物。谷子的体细胞无性系变异和外源基因转化相对其它作物研究较少。本研究利用谷子生产的育种中应用的多个优良品种为材料,分析了谷子体细无性系变异发生的影响因素、变异性和频率、DNA分子水平变异和育种应用等问题;采用基因枪法和花粉管通道法,进行了谷子抗除草剂基因转化研究。 主要结果包括: 1. 通过几种外植体的愈伤组织诱导分析,找到了小花分化期前后的谷子幼穗是愈伤组织诱导的最好外植体.提出谷子愈伤组织可按生长状态和结构划分为质密型、松软型和松散型三种基本类型的观点。前两种为胚性愈伤组织并可相互转换,松软型愈伤组织生长状态稳定,可塑性好,是继代培养和因基化的首选类型。供试品种中豫谷1号、高39、郑407和矮宁黄为易培养品种,矮88、豫谷2号、系238、冀14号、C445和青丰谷为相对难培养品种。这些结果为谷子组织培养和生物技术操作提供了基础资料。 2. 首次对多个谷子品种较大群体的无性系变异进行了分析。结果表明,以R_2株系为单位的谷子体细胞无性系表现型变异频率平均为13.0%,不同基因型的变幅为4.3~32.9%;变异涉及株高、抽穗期、穗粒重、出谷率、叶鞘色、育性、抗病性、米色、穗型等多个性状,多数变异为株高和抽穗期等数量性状,少数为矮秆等质量性状:变异的性状多数能在R_3稳定并遗传给后代。从谷子体细胞无性系变异中选出了一批农艺性状得到改良的新品系,其中系103已进入省区域试验,并提供给多家育种单位作为亲本应用。 3. 将RAPD分析技术引入谷子体细胞无性系变异研究。豫谷2号无性系的RAPD多态性变化既有亲本带的缺失,也有新带的产生。用RAPD多态性变化的SMC值度量无性系同亲本相比DNA水平变异的大小,表现型发生变异的无性系,其SMC值分别为0.905~1.0;表现型未发生变异的无性系,RAPD多态性也可能发生变化,其SMC值分布为0.953~1.0。 4. 通过Gus基因瞬时表达单位数的比较,优化了JQ-700基因枪转化谷子松型愈伤组织的操作参数:质粒DNA用量3μg/mg钨粉,CaCl_2农度1.5M,亚精胺浓度40mM,样品室高度7cm,粗弹头为微弹载体,每皿愈伤组织用量1~2g,每次轰击钨粉用量50μg,轰击前4小时和轰击后16~20小时,用含蔗糖150g/l的高渗培养基处理。利用该技术体系,以bar基因为目的基因转化豫谷2号愈伤组织。经选择培养和植株再生,首次获得了抗0.1% bialaphos的正常可育植株,经PCR和Southern blot分析,bar基因已整合到转化体的基因组中,为创造抗除草剂的谷子新种质提供了材料和技术基础。 5. 研究了花粉管通道法转化和花粉介导的基因枪转化谷子的可行性。花粉管通道法转化后代中,获得了抗0.1% bialaphos的抗性植株,经X-gluc组织化学检测,抗性植株叶片的Gus反应为阳性。初步说明该植株可能为转化体,在谷子上为花粉管通道法转化的可行性提供了佐证。花粉介导的基因枪转化未获得转化体。 本文对体细胞无性系变异形成的原因和应用、无性系变异的分子生物学分析、以及谷子的外源基因转化方法等问题进行了讨论。
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玉米的单倍体育种,是利用花药培养或孤雌生殖产生单倍体后,进行人工或自然加倍,迅速获得稳定的新品种的育种方法。单倍体育种可以缩短育种时间,单倍体培养体系如果作为转基因的受体,可保证外源基因在后代中稳定遗传,而不发生分离。因此,玉米单倍体育种无论在实践中还是在理论研究方面都具有重大的意义。 本文针对玉米花药培养中长期以来未能解决的诱导频率低、基因型之间差异大、小苗移栽不容易成活等问题,重点探讨了各种因素对玉米花药培养的影响。结果表明:不同基因型之间的诱导频率差异明显,杂交种的诱导频率比纯系高,并选择出诱导频率高达20%的材料“中0198”;接种时花药中的花粉处于单核中期时,其诱导频率最高;采用液体培养基比采用固体培养基诱导频率提高一倍;培养基中加入0.5%的活性炭,可使诱导频率由5.25%提高到9.35%;15%的蔗糖浓度对玉米的花药培养是最适宜的,培养2周后,将培养基的蔗糖浓度从15%调整为10%,将明显提高诱导频率;培养基中高浓度的KT和低浓度的BA有利于诱导体细胞胚的发生,而低浓度的KT和高浓度的BA有利于诱导芽的发生;接种前将花药在4℃条件下进行低温预处理,可将诱导频率从3.13%提高到11.71%;培养基中添加2 mg/l的多效唑,可有效地促进小苗的生根;再生植株于冬季拿到海南种植,可明显提高移栽的成活率。 在玉米孤雌生殖的实验中,将未受粉的玉米雌穗接种在成份为N6 + 2,4-D 1mg/L + NAA 1mg/L + BA 1mg/L + CH 200mg/L + colchicine 2 mg/L + sucrose 5% + agar 0.7% 的培养基上。第一轮实验共接种了三个材料的26个雌穗(约3900个未受精的子房)。每种材料均有单性结实,诱导频率由高到低分别3.06%,2.29%,1.90%。直接获得了5株再生植株,通过染色体检查,发现其中3株为单倍体(n=10),另外2株为二倍体。移栽到土壤中后,有4株成活,其中一株二倍体植株能够正常开花、结实。得到的种子播种于实验田中,表现整齐一致,有纯系的特征,而且出现了2株白化苗。通过石蜡切片初步观察了孤雌生殖的胚胎发生过程,发现胚胎发生是从胚囊里的单倍体细胞起源的。第二、三轮实验又接种了10个基因型的玉米材料,证实了上述结果。 外源基因转导是利用生物技术进行玉米育种的一个有效途径。本文首次尝试了用离体子房注射法对玉米进行基因转化。首先构建了含有开花促进因子基因FPF1及植物选择标记抗除草剂基因pat的植物表达载体pFBR,采用离体注射培养法,取授粉24小时后的玉米雌穗,剥去苞叶,在超净工作台进行微量注射,然后切成小块接种在培养基上,在光照培养箱内培养,3-4周可直接获得种子或小植株。种子萌发后进行植株抗性筛选和分子检测,共注射了3个品种的47个雌穗(约16450个子房)得到再生植株109株,其中经PPT筛选有抗性的植株为23株,占再生植株的21.1%。经PCR检测,13株植株有阳性反应。但Southern杂交检测有杂带出现。出现杂带的原因、RNA水平的分子检测、转基因后代T1代的分子检测和早开花农艺性状的观察,由于时间关系没有完成,还需要进一步的实验。实验初步证明了离体子房注射法对玉米进行基因转化的可行性,而且与田间注射法相比,此方法具有省力省时,容易控制污染,转化效率提高的优点, 克服了玉米培养再生植株受基因型限制的困境, 将为玉米分子育种的基因工程提供更易行的手段。 同时,也为子房较大的其它植物的基因转化提供了方法。
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生物固氮和植物光合作用作为全球生态系统的两个基本生物学过程, 在碳氮循环、自然生态系统的维持和演替,以及农业生产中起了重要作用。尽管过去关于共生固氮与光合作用的研究取得了巨大成就,但是,很少将两者直接联系起来。本研究通过比较低光效和高光效大豆接种高效固氮根瘤菌后固氮与光合作用的差异,比较接种根瘤菌和施用铵态氮肥对大豆光合生理的影响或光照强度对大豆光合固氮的影响,以及C4基因转化C3 豆科植物—苜蓿的研究,试图将两者偶联起来。研究获得以下结果: 1.用nifA和dct工程根瘤菌接种低光效和高光效大豆后,与出发菌株比,均提高了大豆的固氮和光合作用。两者相比,nifA工程菌对低光效大豆黑农37号发挥了比较好的作用,大豆的光合作用参数,固氮活性和植物株高、株重等产量参数比dct工程菌好;dct工程菌接种高光效大豆黑农40号后,尽管固氮酶活性与nifA工程菌相比没有明显差异,但是大豆光合作用和产量参数有了比较明显的提高。 2.光照培养条件下,对大豆进行了接种根瘤菌(108细菌/ mL)、低氮(5 mmol/L (NH4)2SO4)和高氮(30 mmol/L (NH4)2SO4)处理。测定的大豆生长状况和光合作用系列参数结果表明:低氮处理的最好,接种根瘤菌的次之,高氮处理的最差。由此说明单纯接种根瘤菌满足不了大豆发育过程中的氮营养要求,其光合作用和生长受到不利影响。但是,高氮处理也并没有提高大豆的光合作用,其生长发育甚至受到抑制。该结果为生产实践中合理施肥提供了光合生理方面的参考。 3.接根瘤菌和不接根瘤菌的大豆在正常光强(150μmol photons m-2s-1)下生长三周后进行遮光(15μmol photons m-2s-1,7天)和复光(正常光强,7天)处理,大豆的光合作用有下降和回复。测定的一系列光合参数、叶绿素荧光参数,以及植物的生长生理参数结果表明:接根瘤菌大豆与不接根瘤菌的大豆对遮光的响应有不同。正常光照下,接种根瘤菌能促进大豆生长与光合作用;遮光处理后,根瘤菌对大豆的促进作用不显著。 4.获得了不同苜蓿品种的愈伤组织及其诱导的再生植株。并作了用小米、甘蔗的PEPC基因转化苜蓿的研究。由于在实验过程中,考虑转基因植物的安全性,着重于用甘露糖筛选转化体系的研究工作,忽略了用抗生素筛选转化体。用PCR法从苜蓿中扩增出甘露糖异构酶基因(pmi),表明苜蓿体内含有自己的甘露糖异构酶基因,使得甘露糖筛选没有成功。
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从中国传统药用植物青蒿(Artemisia annua L.)中提取的青蒿素及其半合成衍生物如蒿甲醚等是一类新型的抗疟特效药,特别是对抗氯喹的恶性疟疾和脑型疟疾有很好的疗效。由于青蒿素在植物中的含量极低,使得其价格很高,特别是对于亚非拉等第三世界国家来说。因此如何提高青蒿素的产量成为近年来研究的热点。各种传统的育种、生理生化手段和细胞培养技术均未取得较好的结果,因此,利用植物基因工程技术提高青蒿素产量已成为研究的重点之一。 本论文围绕青蒿素的生物合成途径开展了以下的工作: 一、中药青蒿紫穗槐二烯合酶的大肠杆菌表达、纯化与功能鉴定 利用RT-PCR方法,从中药青蒿高产株系001中克隆到的中药青蒿紫穗槐二烯合酶(ADS) cDNA, 其推测编码蛋白与前人报道的有两个位点的突变。将其开放阅读框插入到原核表达载体pET30a(+)的BamHⅠ和XhoⅠ酶切位点之间,构建N端携带有HIS6表达标签的紫穗槐二烯合酶重组表达载体pETADS。将pETADS转入大肠杆菌BL21(DE3), IPTG (Isopropyl-beta -D-thiogalactoside)诱导重组紫穗槐二烯合酶的表达。表达产物经镍琼脂糖柱纯化。纯化蛋白加入酶促反应体系(含FPP),GC-MS分析酶促反应体系的正己烷萃取物,结果显示重组紫穗槐二烯合酶可以催化FPP向紫穗槐二烯的转化。体外酶促动力学分析表明,两个位点的氨基酸突变,并没有影响到青蒿紫穗槐二烯合酶的催化活性。基因组DNA杂交表明,紫穗槐二烯合酶基因在001株系基因组中至少有4个拷贝。 二、中药青蒿鲨烯合酶的大肠杆菌表达、纯化与功能鉴定 将经RACE方法克隆到的中药青蒿鲨烯合酶cDNA(AF302464) 开放阅读框的3'末端截短99 bp,插入到原核表达载体pET30a(+)的NcoⅠ和BamHⅠ酶切位点之间,构建N端和C端均携带有HIS6表达标签的鲨烯合酶重组表达载体pETSSA。将pETSSA转入大肠杆菌BL21(DE3), IPTG (Isopropyl-beta-D-thio galactoside)诱导重组鲨烯合酶的表达。表达产物经镍琼脂糖柱纯化。纯化蛋白加入酶促反应体系(含FPP和NADPH),GC-MS分析酶促反应体系的正己烷萃取物,结果显示重组鲨烯合酶可以催化FPP向鲨烯的转化。青蒿鲨烯合酶的功能鉴定,为进一步利用反义或RNAi技术限制甾类生物合成,从而提高青蒿中的青蒿素含量提供了基础。 三、中药青蒿法呢醇合酶原核表达、纯化与功能鉴定 将经RACE方法克隆到的中药青蒿倍半萜合酶cDNA ( AF304444) 开放阅读框插入到原核表达载体pET30a(+)的NcoⅠ和BamHⅠ酶切位点之间,构建N端和C端均携带有HIS6表达标签的重组表达载体pET30SESQ。将pET30SESQ转入大肠杆菌BL21(DE3), IPTG (Isopropyl-beta-D-thioga lactoside)诱导蛋白表达,表达产物经镍琼脂糖柱纯化。纯化蛋白加入酶促反应体系(FPP),GC-MS分析酶促反应体系的正己烷萃取物,结果显示此重组酶可以催化FPP向法呢醇的转化。 四、中药青蒿FPS、ADS双功能酶基因的构建、表达与功能鉴定 将青蒿素生物合成途径中催化两步连续反应的酶:法呢基焦磷酸合酶和紫穗槐二烯合酶的基因进行融合,经大肠杆菌表达后鉴定融合蛋白的功能,结果表明融合蛋白具有了双功能酶活性。进一步将融合酶基因转入酿酒酵母中,发酵后检测紫穗槐二烯的含量,并与同时转入法呢基焦磷酸合酶和紫穗槐二烯合酶单个基因的酵母、单独转入紫穗槐二烯合酶基因的酵母进行了比较,结果表明,转入双功能酶的酵母发酵获得的紫穗槐二烯含量要比两个对照酵母高,这表明,获得的双功能酶的催化效率要比两个单独酶的催化效率高。 五、过量表达青蒿紫穗槐二烯合酶对青蒿中青蒿素及其前体物含量的影响 利用根癌农杆菌介导,将青蒿紫穗槐二烯合酶转入青蒿株系001,分子检测证明,紫穗槐二烯合酶整合到了青蒿基因组中并在mRNA水平得到了高效表达。部分转基因青蒿的青蒿素含量有明显增加,最多的比001株系提高了41%。青蒿酸和二氢青蒿酸含量测定表明,转基因青蒿株系的青蒿酸和二氢青蒿酸含量最多的比对照分别提高了47%和79%。这些结果表明,紫穗槐二烯合成在青蒿素生物合成途径中是一个限速步骤,同时,也显示青蒿酸或二氢青蒿酸的进一步转化也可能是青蒿素生物合成中下游的限速步骤。
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水稻是我国重要的粮食作物之一,它是一种典型的C3植物。与其它C3作物不一样的是,水稻的生长需要相对较高的温度和充足的阳光照射。然而高温和高光强的生长环境更加适合于C4植物的生长,更加有利于发挥C4植物高光合效率的特点。因此本论文希望将C4植物中固定CO2的酶磷酸烯醇式丙酮酸羧化酶基因导入水稻,获得一种更加适合高温和高光强生活环境的“C4型”水稻,这对于提高水稻的产量,满足人口增长对粮食需求具有重大意义。 本论文从C4植物谷子和甘蔗中克隆了其C4型磷酸烯醇式丙酮酸羧化酶cDNA基因,获得了具有自主知识产权的基因克隆,并将它们导入粳稻品种中花8号,进而对转基因材料的光合生理特性进行了研究。结果如下: 首次从谷子中得到了ppc基因两个cDNA克隆,分别命名为Mppc1和Mppc2。前者是一个C3型的ppc基因,它可能属于在根中特异表达的C3-2型ppc基因;后者是在绿色叶片中大量表达的C4型ppc基因。它们所编码的蛋白的氨基酸残基数分别为961和964,序列同源性为82.5%。C4型PEPC多出的3个氨基酸位于N末端。利用RACE的方法我们得到了谷子C4型ppc基因完整的cDNA序列,包括63bp的5'非编码区,2895bp的编码区和256bp的3'非编码区。 首次获得了甘蔗C4型ppc基因完整的cDNA序列的克隆,命名为Sppc。它包括95bp的5'非编码区、2886bp的编码区,和224bp的3'非编码区。 利用所克隆的基因,分别连上强组成型启动子Ubiquitin启动子和强光调控启动子Rubisco小亚基启动子后,再插入两个标记基因不同的表达载体pCB和pPCB的多克隆位点中,构建了八个含有外源ppc基因的植物表达载体pCB-Pubi-Mppc、pCB-Pubi-Sppc、pCB-PrbcS-Mppc、pCB-PrbcS-Sppc、pPCB-Pubi-Mppc、pPCB-Pubi-Sppc、pPCB-PrbcS-Mppc和pPCB-PrbcS-Sppc。再加上含有玉米完整的C4型ppc 核基因的载体pCB-ZMppc,共有9个载体。利用农杆菌介导法进行了水稻的转化,各个载体都获得了大量的转基因植株。对标记基因潮霉素磷酸转移酶基因hpt和磷酸甘露糖异构酶基因pmi以及导入的目的ppc基因的PCR扩增检测,结果显示绝大多数转基因植株都能扩增出目的片段,而未转化的植株则没有扩增产物。对部分转基因水稻的Southern和Western杂交以及RT-PCR分析都表明,无论从DNA水平、mRNA水平,还是从蛋白质水平上都证明外源ppc基因都成功地导入了水稻,并获得了正确的表达。 对各载体转基因植株PEPC活性大规模的测定表明,转入玉米完整C4型PEPC核基因(有内含子)的水稻表现出极大的表达效率,大多数转基因材料的PEPC活性为对照的10-20倍,其活性最高可达到对照的44倍。转入谷子和甘蔗PEPC基因cDNA的水稻,表达的效率很低,多数材料活性增加仅为对照的2-5倍,但也有极少数材料活性增加了10倍以上。用Rubisco小亚基启动子控制的ppc基因在水稻的表达活性要略高于Ubiquitin启动子控制的ppc基因。以上结果说明ppc基因的内含子在其转录或mRNA的稳定上起着重要作用。 对部分转基因材料气体交换特征的研究发现,随着转基因水稻PEPC活性的增加,净光合速率也有逐渐增加的趋势。其中PEPC活性最大的ZM24株系的三个单株净光合速率比对照增加了39.8%、13.7%和28.6%,而它们的PEPC活性比对照分别增加了21.2、21.9和23.6倍。 转PEPC水稻的净光合速率与气孔导度具有显著的相关性。这说明表达的外源ppc 基因产物PEPC参与了转基因水稻的气孔运动,使气孔开放程度增加。更有意义的是过表达PEPC的水稻具有更高的水分利用效率,这就增加了其耐旱能力。在光抑制条件下转基因水稻也具有更高的光合能力。这些特征表明转ppc基因的水稻比对照更加适合于水稻高温高光强和干旱的原生环境。
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Fishes, the biggest and most diverse community in vertebrates are good experimental models for studies of cell and developmental biology by many favorable characteristics. Nuclear transplantation in fish has been thoroughly studied in China since 1960s. Fish nuclei of embryonic cells from different genera were transplanted into enucleated eggs generating nucleo-cytoplasmic hybrids of adults. Most importantly, nuclei of cultured goldfish kidney cells had been reprogrammed in enucleated eggs to support embryogenesis and ontogenesis of a fertile fish. This was the first case of cloned fish with somatic cells. Based on the technique of microinjection, recombinant MThGH gene has been transferred into fish eggs and the first batch of transgenic fish were produced in 1984. The behavior of foreign gene was characterized and the onset of the foreign gene replication occurred between the blastula to gastrula stages and random integration mainly occurred at later stages of embryogenesis. This eventually led to the transgenic mosaicism. The MThGH-transferred common carp enhanced growth rate by 2-4 times in the founder juveniles and doubled the body weight in the adults. The transgenic common carp were more efficient in utilizing dietary protein than the controls. An "all-fish" gene construct CAgcGH has been made by splicing the common carp beta-actin gene (CA) promoter onto the grass carp growth hormone gene (gcGH) coding sequence. The CAgcGH-transferred Yellow River Carp have also shown significantly fast-growth trait. Combination of techniques of fish cell culture, gene transformation with cultured cells and nuclear transplantation should be able to generate homogeneous strain of valuable transgenic fish to fulfil human requirement in 21(st) century.
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To identify new loci that are involved in the assembly and targeting of dynein complexes, we have screened a collection of motility mutants that were generated by insertional mutagenesis. One such mutant, 5B10, lacks the inner arm isoform known as the I1 complex. This isoform is located proximal to the first radial spoke in each 96-nm axoneme repeat and is an important target for the regulation of flagellar motility. Complementation tests reveal that 5B10 represents a new I1 locus, IDA7. Biochemical analyses confirm that ida7 axonemes lack at least five I1 complex subunits. Southern blots probed with a clone containing the gene encoding the 140-kDa intermediate chain (IC) indicate that the ida7 mutation is the result of plasmid insertion into the IC140 gene. Transformation with a wild-type copy of the IC140 gene completely rescues the mutant defects. Surprisingly, transformation with a construct of the IC140 gene lacking the first four exons of the coding sequence also rescues the mutant phenotype. These studies indicate that IC140 is essential for assembly of the I1 complex, but unlike other dynein ICs, the N-terminal region is not critical for its activity.
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The accumulation of the disaccharide trehalose in anhydrobiotic organisms allows them to survive severe environmental stress. A plant cDNA, SlTPS1, encoding a 109-kD protein, was isolated from the resurrection plant Selaginella lepidophylla, which accumulates high levels of trehalose. Protein-sequence comparison showed that SlTPS1 shares high similarity to trehalose-6-phosphate synthase genes from prokaryotes and eukaryotes. SlTPS1 mRNA was constitutively expressed in S. lepidophylla. DNA gel-blot analysis indicated that SlTPS1 is present as a single-copy gene. Transformation of a Saccharomyces cerevisiae tps1Δ mutant disrupted in the ScTPS1 gene with S. lepidophylla SlTPS1 restored growth on fermentable sugars and the synthesis of trehalose at high levels. Moreover, the SlTPS1 gene introduced into the tps1Δ mutant was able to complement both deficiencies: sensitivity to sublethal heat treatment at 39°C and induced thermotolerance at 50°C. The osmosensitive phenotype of the yeast tps1Δ mutant grown in NaCl and sorbitol was also restored by the SlTPS1 gene. Thus, SlTPS1 protein is a functional plant homolog capable of sustaining trehalose biosynthesis and could play a major role in stress tolerance in S. lepidophylla.
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We have tested a methodology for the elimination of the selectable marker gene after Agrobacterium-mediated transformation of barley. This involves segregation of the selectable marker gene away from the gene of interest following co-transformation using a plasmid carrying two T-DNAs, which were located adjacent to each other with no intervening region. A standard binary transformation vector was modified by insertion of a small section composed of an additional left and right T-DNA border, so that the selectable marker gene and the site for insertion of the gene of interest (GOI) were each flanked by a left and right border. Using this vector three different GOIs were transformed into barley. Analysis of transgene inheritance was facilitated by a novel and rapid assay utilizing PCR amplification from macerated leaf tissue. Co-insertion was observed in two thirds of transformants, and among these approximately one quarter had transgene inserts which segregated in the next generation to yield selectable marker-free transgenic plants. Insertion of non-T-DNA plasmid sequences was observed in only one of fourteen SMF lines tested. This technique thus provides a workable system for generating transgenic barley free from selectable marker genes, thereby obviating public concerns regarding proliferation of these genes.
