84K杨愈伤组织再生体系和直接分化再生体系遗传转化的比较性研究

植物转基因必须以建立良好的植物转化受体系统为基础,而良好的受体系统必须以具有高频率的转化率及较强的再生能力为前提。实验以84K杨叶片为材料研究其在不同培养条件、不同种类及浓度的植物激素对其脱分化及再分化的影响,并建立了两种成熟的组织再生系统,得出组织培养体系与遗传转化体系的受体系统在激素配比方面存在一定差距,所以在此基础上进行了PCK1、PCK2两个基因的愈伤途径和不定芽途径途径的遗传转化,并对两种遗传转化体系进行了对比性分析并总结出两种体系的优缺点。     

草坪草生物技术研究进展

概述了草坪草植株再生体系和遗传转化体系建立的方法和进展.通过愈伤组织培养、悬浮细胞培养和原生质体培养方法对草坪草的一些种已建立较为完善的植株再生体系.在建立再生体系的基础上,利用原生质体融合、农杆菌介导、基因枪和碳化硅纤维介导等转基因方法在一些草坪草种上建立了遗传转化体系并获得了有一定价值的转基因植株.最后,对草坪草转基因存在的问题和前景作了讨论.     

草坪植物遗传转化的研究进展

从草坪植物组织培养与植株再生体系的建立、转基因的研究现状以及转基因育种的应用前景和存在的问题入手,综述了近年来草坪植物遗传转化的研究进展,并对草坪植物遗传转化的几种主要方法作了较为详细的阐述。     

香石竹植株再生及基因工程研究进展

本文对香石竹的再生体系、遗传转化体系及其分子育种现状作了较为系统的总结。香石竹的再生体系多以器官直接再生不定芽为主, 而通过愈伤组织和体细胞胚途径再生报道较少。用农杆菌介导法和基因枪法均可建立香石竹遗传转化体系, 但近年来的研究显示农杆菌介导法应用普遍且比较稳定。近年来以延长香石竹瓶插寿命为目标的分子育种研究已取得较大进展, 对其色、香和形等其他重要性状的分子育种也已经起步, 而有关香石竹抗性的分子育种有待进一步开拓。     

促进植物高效遗传转化的发育调节因子及其在玉米中的应用进展*

高效遗传转化技术体系的建立对植物功能基因组学研究和作物新品种的培育均具有促进作用,目前,再生效率低下是限制许多植物高效遗传转化体系建立的主要技术屏障之一。随着对植物分生组织和体细胞胚形成过程研究的深入,鉴定到了一些关键调控基因,统称为发育调节因子。发育调节因子应用于植物遗传转化后,可以有效改善植物分生组织诱导和再生能力,为提高遗传转化效率提供了重要机遇。综述了7类发育调节因子在提高植物遗传转化效率中的研究进展,重点介绍了其中3类在促进玉米遗传转化中的应用,最后展望了建立植物高效遗传转化体系的发展方向。     

香石竹植株再生及基因工程研究进展

本文对香石竹的再生体系、遗传转化体系及其分子育种现状作了较为系统的总结。香石竹的再生体系多以器官直接再生不定芽为主,而通过愈伤组织和体细胞胚途径再生报道较少。用农杆菌介导法和基因枪法均可建立香石竹遗传转化体系,但近年来的研究显示农杆菌介导法应用普遍且比较稳定。近年来以延长香石竹瓶插寿命为目标的分子育种研究已取得较大进展,对其色、香和形等其他重要性状的分子育种也已经起步,而有关香石竹抗性的分子育种有待进一步开拓。     

利用有性途径的植物转化

近年来 ,植物基因工程技术取得了重要进展 ,在农作物品种改良和育种方面发挥越来越重要的作用。然而 ,目前植物遗传转化所采用的受体系统 ,大都依赖于细胞组织培养技术才能获得转基因植株。其中 ,基因型限制和遗传变异是限制该技术发展和应用的两大障碍。因此 ,一些研究者试图避开组织培养和植株再生过程 ,利用植物有性生殖途径进行转化 ,并取得了一系列成果。这些方法包括以下方面 :(1 )利用花粉粒或花粉管作为转化DNA的载体 ;(2 )将外源DNA导入子房或胚珠中 ;(3 )以精、卵细胞、合子作为转化受体。这些方法利用了高等植物的有性生殖机制和胚胎发育过程 ,避免了无性繁殖过程中的遗传变异、植株再生困难及转基因植株嵌合等问题。该文归纳综合了该研究领域所取得的成果和最新进展 ,并对这些方法进行了评价及其发展趋势进行了分析。     

Enhancement of plant regeneration from embryogenic callus of commercial barley cultivars

Genotypic restrictions on plant regeneration from cultured cells have hindered the genetic transformation of most barley cultivars. Optimizing culturing protocols for specific cultivars of commercial interest may facilitate their genetic transformation. Plant regeneration from embryogenic callus of `Harrington', `Morex', and `Hector' as affected by certain protocol modifications was examined in replicated experiments. Regeneration was improved for all cultivars by separately autoclaving certain components of the culture media and by reducing the amount of embryogenic callus cultured per petri dish. Regeneration improvements in response to various concentrations of copper and 2,4-dichlorophenoxyacetic acid were more genotype specific. This study suggests that the development and use of genotype-specific protocols can enhance plant regeneration. Enhancements in plant regeneration are expected to facilitate the transformation of commercial barley germplasm. Received: 11 August 1997 / Revision reveived: 2 March 1998 / Accepted: 20 March 1998     

Genetic transformation technology: Status and problems

Summary Transfer of genes from heterologous species provides the means of selectively introducing new traits into crop plants and expanding the gene pool beyond what has been available to traditional breeding systems. With the recent advances in genetic engineering of plants, it is now feasible to introduce into crop plants, genes that have previously been inaccessible to the conventional plant breeder, or which did not exist in the crop of interest. This holds a tremendous potential for the genetic enhancement of important food crops. However, the availability of efficient transformation methods to introduce foreign DNA can be a substantial barrier to the application of recombinant DNA methods in some crop plants. Despite significant advances over the past decades, development of efficient transformation methods can take many years of painstaking research. The major components for the development of transgenic plants include the development of reliable tissue culture regeneration systems, preparation of gene constructs and efficient transformation techniques for the introduction of genes into the crop plants, recovery and multiplication of transgenic plants, molecular and genetic characterization of transgenic plants for stable and efficient gene expression, transfer of genes to elite cultivars by conventional breeding methods if required, and the evaluation of transgenic plants for their effectiveness in alleviating the biotic and abiotic stresses without being an environmental biohazard. Amongst these, protocols for the introduction of genes, including the efficient regeneration of shoots in tissue cultures, and transformation methods can be major bottlenecks to the application of genetic transformation technology. Some of the key constraints in transformation procedures and possible solutions for safe development and deployment of transgenic plants for crop improvement are discussed.     

An efficient protocol for Agrobacterium-mediated genetic transformation of Antirrhinum majus

Snapdragon (Antirrhinum majus L.) is a popular ornamental and model plant species, and the recently released reference genome could greatly boost its utilization in fundamental research. However, the lack of an efficient genetic transformation system is still a major limiting factor for its full application in genetic and molecular studies. In this study, a simple method for quick regeneration and efficient Agrobacterium-mediated transformation of snapdragon was developed. Cotyledon petiole and hypocotyl explants derived from two-week-old seedlings were cultured on MS media supplemented with 2 mg/L zeatin (ZT), 0.2 mg/L 1-naphthaleneacetic acid (NAA), and 2 mg/L AgNO₃, and adventitious shoots were regenerated through organogenesis with an average regeneration of 48.00% and 41.33%, respectively. By contrast, the regeneration frequency was only 22.67% for cotyledon petiole and 25.67% for hypocotyl explants in the absence of AgNO₃. Moreover, the application of AgNO₃ promoted indirect shoot organogenesis, while direct shoot organogenesis occurred in the absence of AgNO₃ from both hypocotyl or cotyledon petiole explants. Agrobacterium-mediated genetic transformation systems were developed with this high-efficient regeneration system. The transformation efficiency has been improved from 0 to 1% through the direct shoot organogenesis to 3 to 4% via the indirect shoot organogenesis. This efficient regeneration and genetic transformation method could be important for future use of snapdragon as a model plant to address some fundamental questions which are hard to be solved by using other model plant species, and to accelerate the breeding process through CRISPR/Cas9 genome editing.

     

Novel and potential application of cryopreservation to plant genetic transformation

The world population now is 6.7 billion and is predicted to reach 9 billion by 2050. Such a rapid growing population has tremendously increased the challenge for food security. Obviously, it is impossible for traditional agriculture to ensure the food security, while plant biotechnology offers considerable potential to realize this goal. Over the last 15 years, great benefits have been brought to sustainable agriculture by commercial cultivation of genetically modified (GM) crops. Further development of new GM crops will with no doubt contribute to meeting the requirements for food by the increasing population. The present article provides updated comprehensive information on novel and potential application of cryopreservation to genetic transformation. The major progresses that have been achieved in this subject include (1), long-term storage of a large number of valuable plant genes, which offers a good potential for further development of novel cultivars by genetic transformation; (2), retention of regenerative capacity of embryogenic tissues and protoplasts, which ensures efficient plant regeneration system for genetic transformation; (3), improvement of transformation efficiency and plant regeneration of transformed cells; (4), long-term preservation of transgenic materials with stable expression of transgenes and productive ability of recombinant proteins, which allows transgenic materials to be stored in a safe manner before being analyzed and evaluated, and allows establishment of stable seed stocks for commercial production of homologous proteins. Data provided in this article clearly demonstrate that cryo-technique has an important role to play in the whole chain of genetic transformation. Further studies coupling cryotechnique and genetic transformation are expected to significantly improve development of new GM crops.     

Improvement of tissue culture,genetic transformation,and applications of biotechnology to Brassica

Development of in vitro plant regeneration method from Brassica explants via organogenesis and somatic embryogenesis is influenced by many factors such as culture environment, culture medium composition, explant sources, and genotypes which are reviewed in this study. An efficient in vitro regeneration system to allow genetic transformation of Brassica is a crucial tool for improving its economical value. Methods to optimize transformation protocols for the efficient introduction of desirable traits, and a comparative analysis of these methods are also reviewed. Hence, binary vectors, selectable marker genes, minimum inhibitory concentration of selection agents, reporter marker genes, preculture media, Agrobacterium concentration and regeneration ability of putative transformants for improvement of Agrobacterium-mediated transformation of Brassica are discussed.     

葡萄基因工程研究进展

植物基因工程技术为培育优良葡萄品种开辟了一条全新而有效的途径。葡萄基因转化受体系统的建立主要包括器官发生途径和胚状体发生途径,建立良好的受体系统是葡萄基因转化成功的关键,遗传转化途径主要有根癌农杆菌介导的遗传转化和基因枪法。概述了迄今国内外葡萄基因工程的研究进展,着重对葡萄基因转化受体系统的建立、转化的方法、转化植株的筛选和检测、影响葡萄基因转化的主要因素等进行了综述,并展望了葡萄基因工程的发展前景。     

蓖麻生物工程研究进展

蓖麻是一种高蓄能植物和工业原料植物,具有很大的开发利用价值。本文从组织培养和遗传转化两个方面并结合本实验室的工作综述了蓖麻生物工程研究的最新进展。在蓖麻组织培养方面,不同的外植体中以成熟种子的胚轴最适宜,而在不同激素中以TDZ诱导丛生芽的效率最高,并以此为基础建立了蓖麻离体再生体系。在遗传转化方面,不同的转化方法中以农杆菌介导法最适合蓖麻转化。蓖麻胚轴对卡那霉素不敏感,潮霉素是蓖麻转化的适宜筛选剂。文中指出了蓖麻生物工程研究中存在的问题,并对应用生物技术培育蓖麻新品种和促进蓖麻生产的可能性进行了讨论。     

草坪草生物技术研究进展

草坪草转基因方法主要有原生质体融合法,基因枪法和农杆菌介导法。抗生素（潮霉素,G418)和除草剂（bialaphos,ppt)都可用于草坪草也可能存在生态风险性。     

Transformation of fruit trees. Useful breeding tool or continued future prospect?

Regeneration and transformation systems using mature plant material of woody fruit species have to be achieved as a necessary requirement for the introduction of useful genes into specific cultivars and the rapid evaluation of resulting horticultural traits. Although the commercial production of transgenic annual crops is a reality, commercial genetically-engineered fruit trees are still far from common. In most woody fruit species, transformation and regeneration of commercial cultivars are not routine, generally being limited to a few genotypes or to seedlings. The future of genetic transformation as a tool for the breeding of fruit trees requires the development of genotype-independent procedures, based on the transformation of meristematic cells with high regeneration potential and/or the use of regeneration-promoting genes. The public concern with the introduction of antibiotic resistance into food and the restrictions due to new European laws that do not allow deliberate release of plants transformed with antibiotic-resistance genes highlight the development of methods that avoid the use of antibiotic-dependent selection or allow elimination of marker genes from the transformed plant as a research priority in coming years     

普通小麦品种Alondra＇s遗传转化体系的建立

小麦（Triticum aestivum）幼胚愈伤组织的诱导和分化再生有高度依赖基因型特征。为了建立和优化Alondra’s的高效再生及遗传转化体系,为小麦遗传转化提供更多的受体基因型,以Alondra’s的幼胚为外植体,研究了培养基种类、不同激素配比等对其幼胚愈伤组织诱导及再生的影响。结果表明,在使用N6培养基时,添加3mg·L^-1的2,4-D并附加1000mg·L^-1的CH对愈伤组织的诱导效果较好;添加4mg·L^-1的ZT、不附加IAA对愈伤组织的分化效果最好。通过构建植物表达载体pCAMBIA1301-220.6,利用基因枪法将HYG基因导入Alondra’s幼胚愈伤组织中,以建立Alondra’s的高效遗传转化体系。结果在含100mg·L^-1潮霉素的选择培养基上进行筛选、分化,获得了30棵抗性植株。经PCR检测,其中5株为阳性转基因植株,转化率为0.5%。Alondra＇s遗传转化体系的建立丰富了小麦遗传转化的基因型,为小麦品种的转基因改良和在不同背景下研究基因的功能奠定了良好的基础。     

花生遗传转化的主要方法和研究进展

花生遗传转化研究对于花生品种改良、新品种繁育具有重要意义。农杆菌介导的遗传转化法和基因枪法是花生遗传转化的主要方法。随着对花生研究的深入开展,花生的遗传转化技术也越来越成熟。介绍了农杆菌介导的遗传转化法和基因枪法在花生遗传转化研究中的应用现状及存在的问题。     

月季的植株再生及遗传转化研究进展

本文对近20年月季植株再生和转基因研究进展进行了较为系统的回顾和总结.月季通过器官和体细胞胚发生途径都能再生植株,但遗传转化主要是利用体细胞胚发生途径.通过农杆菌介导法和基因枪法,外源基因如报告基因、抗病基因和改变花色的基因等已转化成功.文章还对今后月季转基因研究的方向进行了讨论.     

月季的植株再生及遗传转化研究进展

本文对近20年月季植株再生和转基因研究进展进行了较为系统的回顾和总结。月季通过器官和体细胞胚发生途径都能再生植株,但遗传转化主要是利用体细胞胚发生途径。通过农杆菌介导法和基因枪法,外源基因如报告基因、抗病基因和改变花色的基因等已转化成功。文章还对今后月季转基因研究的方向进行了讨论。