影响花椰菜农杆菌介导转化因素的研究

以花椰菜赛雪的带柄子叶为外植体,以MS为基本培养基,GUS基因为报告基因,分析了遗传转化过程中的影响因子,如预培养时间、农杆菌菌液浓度、侵染时间、共培养时间、乙酰丁香酮浓度、延迟筛选时间等对外植体瞬间表达和稳定表达的影响。结果显示,以花椰菜的带柄子叶为外植体,预培养2d,农杆菌菌液为OD6000.3～0.4,侵染8min,共培养2d,乙酰丁香酮浓度为100μmol/L,延迟筛选7d,卡那霉素筛选压为5mg/L为最优的遗传转化方案,转化率最高可达35.7%。另外,GUS瞬间表达率和转化率并不存在绝对的相关性,但瞬间表达分析仍然可以作为外源基因进入受体细胞的指示。花椰菜农杆菌介导转化方案的优化研究为芸薹属蔬菜高效遗传转化提供了技术保障,有利于芸薹属蔬菜遗传育种与种质创新研究。     

农杆菌介导的墨兰遗传转化

转基因育种是快速定向改良兰花育种目标性状的有效方法,但迄今未见有关墨兰转基因育种的研究报道。试验以‘企剑白墨’墨兰Cymbidium sinensis cv.‘Qijianbaimo’的根状茎为受体材料,研究了影响农杆菌介导墨兰遗传转化效率的因素,以建立有实用价值的墨兰遗传转化技术体系。结果表明,受体的预培养时间、乙酰丁香酮的添加方式及浓度、农杆菌工程菌液浓度(OD600)、侵染时间和共培养时间均对‘企剑白墨’根状茎的GUS瞬时表达率有显著影响。以预培养39 d的根状茎尖为材料,在添加200μmol/L乙酰丁香酮,OD600为0.9的工程菌液中侵染35 min后,转入添加200μmol/L乙酰丁香酮的共培养基中培养7 d时,‘企剑白墨’根状茎的GUS瞬时表达率最高,为11.67%。采用上述条件对‘企剑白墨’墨兰进行遗传转化,经PCR鉴定和GUS染色检测,从400株再生植株中获得了3株转基因植株,转化率为0.75%。研究表明通过农杆菌介导法对墨兰进行遗传改良是可行的。     

新疆杨高效遗传转化系统的建立

选择新疆杨(Populus alba L.var．pyramidalis Bge．)为遗传转化受体材料,为建立根癌农杆菌介导新疆杨高效遗传转化系统,从预培养时间、侵染时间、共培养时间、添加乙酰丁香酮(AS)的时机、共培养培养基中添加乙酰丁香酮浓度、侵染菌液的制备方法、外植体继代方式等7个方面优化筛选。结果显示较合适的转化系统为：预培养8h,农杆菌菌液(OD600=0．4)侵染15min,共培养5d,侵染菌液的最优制备方法是液体培养活化农杆菌2次加离心收集菌体重悬,共培养培养基中添加乙酰丁香酮80μmol／L。新疆杨叶盘转化频率可达38．10％。     

根癌农杆菌介导转化谷子的影响因素

利用GUS报告基因,建立了农杆菌介导的谷子(Setaria italica)遗传转化体系,并研究了多种影响因素对转化效率的影响,包括受体基因型、外植体类型、菌液浓度、培养基中乙酰丁香酮的浓度、侵染时间和共培养时间.确定了最优的转化条件为:以谷子幼穗诱导的愈伤组织为外植体,用低浓度的农杆菌菌液侵染30～40min,然后在含有0.1mmol/L乙酰丁香酮的LS培养基上共培养2d.     

根癌农杆菌介导的金发草遗传转化条件的优化

金发草(Pogonatherum paniceum)是一种多年生岩生草本植物,在生态恢复和景观建设中起着重要的作用。利用根癌农杆菌介导转化金发草胚性愈伤组织,通过GUS(β-葡萄糖苷酸酶)瞬时表达率研究菌液浓度、浸染时间、乙酰丁香酮(AS)浓度、葡萄糖浓度、共培养时间等因素对金发草转化的影响,并利用确定的最佳条件将GUS基因转入金发草,获得稳定表达转化植株。结果表明:菌液浓度(OD₆₀₀)为0.6,浸染时间为10min,添加20mg/L的乙酰丁香酮(AS)和10g/L的葡萄糖,共培养时间5d为最佳条件,GUS瞬时表达率最高。经过抗性筛选后最终获得阳性转基因植株频率为57%。再生植株经GUS染色和PCR检测证明,GUS基因已成功整合到金发草基因组中。此转化体系的建立为金发草的遗传改良及相关功能基因的研究奠定了基础。     

农杆菌介导韭菜遗传转化相关因素的研究

以"汉中冬韭"韭菜品种为试验材料,用含有pCAMBIA3301质粒的根癌农杆菌菌株EHA105对影响韭菜遗传转化效率的多种因素进行研究。结果表明,诱导40 d的愈伤组织,GUS基因瞬时表达率达到93%,且最适宜于不定芽的分化;当乙酰丁香酮(AS)的浓度为100μmol/L时,愈伤的GUS表达率达到91%,植株再生率为7.9%,AS浓度增加时其值也不会增加;菌液OD600值为0.6侵染10 min时,与其他组合相比,外植体受伤程度小,GUS表达率及再生率最高;侵染后的愈伤共培养3 d后,农杆菌生长较少,GUS表达率为91.1%,而再生率达到7.2%,为最佳的共培养时间。通过试验得到韭菜遗传转化因素的最佳条件,为今后的遗传转化提供一些参考。     

EuFPS基因表达载体构建及对杜仲遗传转化的研究

本实验用EcoRⅠ和BamHⅠ双酶切植物表达载体pSH737和含有目的基因的pUC-FPS,定向连接得到重组质粒pSH-FPS,将其导入农杆菌EHA105.采用农杆菌介导法对杜仲进行遗传转化,研究了卡那霉素(kanamycin,Km)浓度、预培养时间、菌液浓度及侵染时间、乙酰丁香酮(acetosyringone,AS)浓度、共培养时间等对杜仲遗传转化效率的影响.结果表明,选择无菌苗苗龄15 d的杜仲下胚轴,卡那霉素浓度50mg/L,农杆菌浓度OD600值0.3-0.6,侵染时间8 min,侵染时菌体重悬液中添加50 μmol/L乙酰丁香酮,共培养时间3 d,抗性芽的获得率最高.对再生植株进行GUS检测发现有45%的植株呈阳性.     

农杆菌介导佛手遗传转化主要影响因素的研究

采用根癌农杆菌介导的佛手叶盘转化法,在建立转海藻糖合酶基因(TPS)佛手体系过程中,对影响农杆菌转化频率的各种因素进行了研究。结果表明,佛手叶盘需在黑暗条件下MT培养基上预培养2-3d,与农杆菌共培养3d较合适;农杆菌菌液浓度OD600约为0.6-0.8,感染时间20min;抑制农杆菌生长的抗生素浓度以头孢霉素(Cef)250mgL-1和羧苄青霉素(Cb)250mgL-1且延迟筛选时间4d最好;共培养基中添加100μmol/L乙酰丁香酮(AS)和400mgL-1半胱氨酸(L-Cys)对佛手遗传转化有明显的促进作用。经GUS报告基因和PCR技术检测,初步证实TPS基因已整合到佛手基因组中,且GUS报告基因瞬时表达率为5.9%。     

影响农杆菌介导狗牙根遗传转化的因素

农杆菌LBA4404/pCAMBIA1301介导转化狗牙根的体系中,遗传转化的最佳优化条件是:胚性愈伤组织预培养10 d,农杆菌菌液浓度为OD600 0.5～0.8,共培养时间为2d.共培养基中添加100μmol·L-1乙酰丁香酮能有效地提高植物瞬时表达率.侵染处理方法中滤纸滴加法比浸泡法效果更好.黑暗条件下的瞬时表达率比12 h光照/12 h黑暗培养条件下的高.在最佳优化条件下狗牙根的GUS瞬时表达率达到36.36%.     

农杆菌介导GUS基因对多年生黑麦草转化的研究

通过检测愈伤组织中GUS基因的瞬间表达,研究农杆菌LBA4404/pCAMBIA1301介导多年生黑麦草的转化体系。通过对多年生黑麦草瞬间表达率的比较,确立了其遗传转化的最佳优化条件。研究发现,多年生黑麦草不同品种的转化率在25%~45%之间变化。多年生黑麦草遗传转化最佳优化条件是预培养10d的胚性愈伤组织、浓度为0.5~0.8OD的农杆菌菌液以及2d共培养时间。在共培养基中添加100μmol/L乙酰丁香酮能有效地提高植物瞬间表达率。两种侵染处理方法比较结果为滤纸滴加法比浸泡法更优。转化后对愈伤组织的干燥处理能抑制农杆菌过度繁殖,能改善愈伤状态,有利于提高转化率。     

Coccystes undoxylophus

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UeberAquila pennata undminuta

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Prosthecium species with Stegonsporium anamorphs on Acer

Data from microscopic morphology, single-spore cultures, and DNA analyses of teleomorphs and anamorphs support the recognition of five species of Prosthecium with Stegonsporium anamorphs on Acer: P. acerinum sp. nov., the teleomorph of S. acerinum; P. acerophilum comb. nov., formerly known as Dictyoporthe acerophila; P. galeatum comb. nov., originally described as Massaria galeata; P. opalus sp. nov.; and P. pyriforme sp. nov., the teleomorph of S. pyriforme s. str. The morphology of both type specimens and freshly collected material was investigated. The teleomorphs have brown ellipsoidal ascospores with five distosepta and often a longitudinal distoseptum. The anamorphs of all species described here belong to Stegonsporium; their connection to the Prosthecium teleomorphs was demonstrated by morphology and DNA sequences of single spore cultures derived from both ascospores and conidia. The anamorphs and teleomorphs of all five Prosthecium species are described and illustrated by LM images, and a key to these species is provided. As perceived from this work, S. pyriforme is restricted to Europe and does not occur in North America, whereas S. acerinum is restricted to North America, not found in Europe. The host associations given in the literature are revised and evidence is provided that only A. opalus, A. pseudoplatanus, and A. saccharum are confirmed hosts of Prosthecium with Stegonsporium anamorphs. Molecular phylogenetic analyses of tef1, ITS rDNA, and partial nuLSU rDNA sequences confirm that the species with Stegonsporium anamorphs are closely related to P. ellipsosporum, the generic type species. Stilbospora macrosperma is confirmed as the anamorph of P. ellipsosporum by DNA data of single spore isolates obtained from both ascospores and conidia.     

Ester production in E. coli and C. acetobutylicum

Genetic engineering has improved the product yield of a variety of compounds by overexpressing, inactivating, or introducing new genes in microbial systems. The production of flavor-enhancing ester compounds is an emerging area of heterologous gene expression for desired product yield in Escherichia coli. Isoamyl acetate, butyl acetate, ethyl acetate, and butyl butyrate are reported here to be produced by expressing Saccharomyces cerevisiae genes ATF1 or ATF2 and the strawberry gene SAAT in E. coli when the appropriate substrates are provided. Increasing the concentration of alcohol added to the reaction generally resulted in increased ester production. ATF1 expression was found to produce more isoamyl acetate and butyl acetate than ATF2 expression or SAAT expression in the strains and culture conditions examined. Additionally, SAAT expression resulted in greater isoamyl acetate and butyl acetate production than ATF2 expression. Butyl butyrate is produced by cell-free extracts of E. coli harboring SAAT but not ATF1 or ATF2.     

Chemical composition, in situ ruminal degradability and post-ruminal disappearance of dry matter and crude protein from the halophytic plants Kochia scoparia, Atriplex dimorphostegia, Suaeda arcuata and Gamanthus gamacarpus

Samples of Kochia (K. scoparia), Atriplex (A. dimorphostegia), Suaeda (S. arcuata) and Gamanthus (G. gamacarpus) were collected and analyzed for chemical composition including crude protein (CP), ether extract (EE), ash, neutral detergent fiber (NDFom), acid detergent fiber (ADFom), non-protein N (NPN), Ca, P, Na, K, Cl, Mg, Fe, Cu and Se. In addition, in situ ruminal degradability and post-ruminal disappearance of dry matter (DM) and CP of the samples using a mobile bag technique were determined. Results indicate that the chemical composition of Kochia and Atriplex was notably different from those of Suaeda and Gamanthus. All of these halophytic plants had high concentrations of Na, K, Cl, Cu and Se, and low levels of Ca, P and Mg. The rapidly degradable fractions of DM and CP (g/g) of Kochia (0.31 and 0.35, respectively) and Atriplex (0.39 and 0.50, respectively) were lower than for Suaeda (0.53 and 0.55, respectively) and Gamanthus (0.56 and 0.66, respectively). Ruminal DM and CP disappearance of Kochia (444 and 517 g/kg, respectively) and Atriplex (472 and 529 g/kg, respectively) were lower (P<0.05) than those of Suaeda (553 and 577 g/kg, respectively) and Gamanthus (663 and 677 g/kg, respectively) (P<0.05) using the mobile bag technique. Suaeda had the lowest (P<0.05) NDFom and ADFom disappearance (214 and 232 g/kg, respectively) in the rumen. Kochia scoparia and Atriplex dimorphostegia have more beneficial chemical nutritive components and digestible values versus Suaeda arcuata and Gamanthus gamacarpus.     

Aquila pennata undminuta

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Effects of MULTIFOLIATE-PINNA, AFILA, TENDRIL-LESS and UNIFOLIATA genes on leafblade architecture in Pisum sativum

In order to dissect the genetic regulation of leafblade morphogenesis, 16 genotypes of pea, constructed by combining the wild-type and mutant alleles of MFP, AF, TL and UNI genes, were quantitatively phenotyped. The morphological features of the three domains of leafblades of four genotypes, unknown earlier, were described. All the genotypes were found to differ in leafblade morphology. It was evident that MFP and TL functions acted as repressor of pinna ramification, in the distal domain. These functions, with and without interaction with UNI, also repressed the ramification of proximal pinnae in the absence of AF function. The expression of MFP and TL required UNI function. AF function was found to control leafblade architecture multifariously. The earlier identified role of AF as a repressor of UNI in the proximal domain was confirmed. Negative control of AF on the UNI-dependent pinna ramification in the distal domain was revealed. It was found that AF establishes a boundary between proximal and distal domains and activates formation of leaflet pinnae in the proximal domain.     

Revision der GeneraSpermospiza undPyrenestes

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