矮牵牛育种研究进展

从常规育种、基因工程育种、体细胞育种和单倍体育种4个方面评述了矮牵牛(Petunia hybrida Vilm.)育种研究进展.国外对矮牵牛育种研究较多,新品种面世推陈出新,国内对其研究则较为薄弱.其常规育种最为成功,不断有新品种推出,基因工程育种也取得了一定成就,已有新品种面世,而体细胞育种及单倍体育种尚无新品种产生,但对这两种方法在育种上应用的可能性和前景作出了一定探索.     

“生物的育种”专题复习教学设计

<正>1教学设计思路1.1教学内容的处理在高中阶段所介绍的育种方法主要有:杂交育种、诱变育种、多倍体育种、单倍体育种、基因工程育种(转基因育种)、细胞工程育种。"生物的育种"是"遗传和变异"知识     

生物技术用于黄瓜遗传育种

“十五”期间,生物技术在黄瓜遗传育种上的应用更加广泛,分子标记辅助育种、单倍体育种以及黄瓜基因工程改良取得了重要进展。本文综述了黄瓜基因分子标记、遗传图谱构建、基因定位、基因克隆与表达、品种DNA指纹图谱分析、分子技术鉴定病害、单倍体和三倍体培养、遗传转化体系建立及基因工程改良方面的最新进展,并讨论了存在的问题和前景。     

我国杂交水稻基因工程育种策略探讨

杂交水稻在我国水稻及粮食生产中占有突出地位 ,基因工程可在杂交水稻育种中发挥重要作用。针对杂交水稻育种存在的主要问题 ,指出应将优质、抗虫和抗病作为当前基因工程育种的研究重点。同时提出基因工程育种与常规育种紧密结合 ,优质基因工程着重改良保持系及聚合转基因等策略 ,以培育出超高产优质抗病虫转基因聚合杂交稻新组合。     

植物单倍体诱导技术发展与创新

单倍体育种是培育作物新品种的主要育种技术之一,提高单倍体诱导频率和简化诱导程序是单倍体育种技术的关键。随着单倍体诱导技术的发展与改进,单倍体育种技术已被广泛应用于许多重要植物的育种研究中,展现出基因纯合快速、育种年限缩短、育种效率提高等优势。单倍体诱导技术与杂交育种、诱变育种、反向育种和分子标记辅助选择育种等技术相结合,在作物品种改良上的作用更加显著。单倍体和双单倍体在遗传群体构建、基因功能鉴定、转基因研究、细胞学研究等方面具有重要应用价值。本文从单倍体诱导技术、单倍体和双单倍体应用等方面综述了植物单倍体诱导技术的发展,尤其是近年来利用基因组编辑技术创制主要作物单倍体诱导系的进展,并分析了目前研究中存在的问题和今后的发展方向,以期促进单倍体诱导技术尤其是利用基因编辑创造诱导系技术在作物育种中的应用。     

植物细胞工程在小麦抗赤霉病育种中的应用

小麦赤霉病是全球性小麦病害,严重影响小麦产量和品质,赤霉菌产生的毒素进一步威胁人畜安全,培育抗病品种是控制小麦赤霉病危害的根本途径。植物细胞工程技术可创造新的遗传变异、加快育种进程,已经广泛应用于小麦抗赤霉病育种。概述了体细胞无性系变异诱导、花药培养、小麦与玉米杂交培育加倍单倍体以及幼胚培养一年多代快速成苗等植物细胞工程技术研究进展,着重介绍了其在抗小麦赤霉病育种中的应用。最后对未来发展趋势做了展望,植物细胞工程结合分子育种技术将在小麦抗赤霉病品种培育中发挥更重要的作用。     

花卉育种技术研究进展(综述)

本文综述近年来国内外花卉育种技术及成果。常规育种仍是花卉育种的主要方法,但日益成熟的生物技术为花卉育种提供了新的途径,尤其是基因工程在改良花卉的色、香、形及延缓衰老等方面将发挥重要作用。     

农业基因工程研究进展报道

基因工程是生物工程的四大工程之一;是分子水平上的遗传工程。这项新技术自1973年美国斯坦福大学的Cohen和Boyer共同开创以来,得到了突飞猛进的发展。本文仅就所了解到的国外基因工程研究1987、1988两个年度所取得的新进展,作一综合介绍。 一、植物基因工程 植物基因工程的主要目标同常规的遗传育种的目标一致,即创造出具有丰产、优质、抗逆、抗旱、抗病虫害、耐盐碱等优良性状的农作物新品种。     

报春花属植物的育种研究进展

本文对报春花属植物引种的历史和现状、育种途径和育种成果进行了综述。报春花属是报春花科最大的属, 全世界约500余种, 我国有296种。国外在杂交育种、多倍体育种、组织培养和体细胞融合等方面取得了许多研究成果, 而国内有关报春花属植物育种的研究相对较少。目前通过杂交育种或多倍体育种等手段已培育出众多花色丰富、花型各异或不含报春碱的报春花新品种。今后我国应在保护种质资源的基础上, 加强报春花新品种的培育, 并尽快实现产业化生产。     

报春花属植物的育种研究进展

本文对报春花属植物引种的历史和现状、育种途径和育种成果进行了综述.报春花属是报春花科最大的属,全世界约500余种,我国有296种.国外在杂交育种、多倍体育种、组织培养和体细胞融合等方面取得了许多研究成果,而国内有关报春花属植物育种的研究相对较少.目前通过杂交育种或多倍体育种等手段已培育出众多花色丰富、花型各异或不含报春碱的报春花新品种.今后我国应在保护种质资源的基础上,加强报春花新品种的培育,并尽快实现产业化生产.     

Protoplast fusion for production of tetraploids and triploids: applications for scion and rootstock breeding in citrus

Protoplast fusion technology has been utilized in many crops to generate allotetraploid somatic hybrids, and sometimes autotetraploids as a byproduct of the process. A brief history of this technology development is provided, along with a simple protocol developed for citrus, which can be easily adapted to other plants. Protoplast fusion has become a significant tool in ploidy manipulation that can be applied in various cultivar improvement schemes. In rare cases, a new somatic hybrid may have direct utility as an improved cultivar; however, the most important application of somatic hybridization is the building of novel germplasm as a source of elite breeding parents for various types of conventional crosses for both scion and rootstock improvement. Somatic hybridization is generating superior allotetraploid breeding parents for use in interploid crosses to generate seedless triploids. Seedlessness is a primary breeding objective for new fresh fruit citrus varieties, and several thousand triploid hybrids have been produced using somatic hybrids as the tetraploid parent. Protoplast fusion is also being utilized to produce somatic hybrids that combine complementary diploid rootstocks, which have shown good potential for tree size control. Tree size control has gained importance as a means of reducing harvesting costs, maximizing the efficiency of modern cold protection methodology, and facilitating the adaptation of new fruit production systems. Successful somatic hybridization in citrus rootstock improvement has enabled rootstock breeding at the tetraploid level via sexual hybridization, which can yield maximum genetic diversity in zygotic progeny upon which to impose selection for the many traits required in improved rootstock cultivars, including disease and insect resistance, broad adaptation, tree size control, and the ability to consistently produce high yields of quality fruit. Recent progress and successful examples of these applications are discussed. Finally, a discussion of the genetic potential of somatic hybrids as breeding parents, including meiotic behavior and inheritance is provided.     

我国葫芦科植物离体培养研究进展

葫芦科植物包括多种瓜类蔬菜,对其进行离体培养研究具有重要的理论和实践意义。综述了国内在葫芦科植物器官培养、体细胞胚胎发生、花药培养、原生质体培养和体细胞杂交及离体遗传转化等方面取得的研究进展,并对葫芦科植物离体培养、遗传转化与育种的前景作了展望。     

我国葫芦科植物离体培养研究进展

葫芦科植物包括多种瓜类蔬菜,对其进行离体培养研究具有重要的理论和实践意义.综述了国内在葫芦科植物器官培养、体细胞胚胎发生、花药培养、原生质体培养和体细胞杂交及离体遗传转化等方面取得的研究进展,并对葫芦科植物离体培养、遗传转化与育种的前景作了展望.     

Biotechnological advances in mango (Mangifera indica L.) and their future implication in crop improvement: a review

Biotechnology can complement conventional breeding and expedite the mango improvement programmes. Studies involving in vitro culture and selection, micropropagation, embryo rescue, genetic transformation, marker-assisted characterization and DNA fingerprinting, etc. are underway at different centers worldwide. In vitro culture and somatic embryogenesis of several different genotypes have been achieved. The nucellus excised from immature fruitlets is the appropriate explant for induction of embryogenic cultures. High frequency somatic embryogenesis has been achieved in some genotypes; however, some abnormalities can occur during somatic embryo germination. Embryo rescue from young and dropped fruitlets can improve the hybridization success in a limited flowering season. Protocols for protoplast culture and regeneration have also been developed. In vitro selections for antibiotic tolerance and fungal toxin resistance have been very promising for germplasm screening. Genetic transformation using Agrobacterium tumefaciens has been reported. Genes that are involved with fruit ripening have been cloned and there have been attempts to deliver these genes into plants. DNA fingerprinting and studies on genetic diversity of mango cultivars and Mangifera species are also being conducted at several research stations. The purpose of this review is to focus upon contemporary information on biotechnological advances made in mango. It also describes some ways of overcoming the problems encountered during in vitro propagation of mango.     

Gametic and somatic embryogenesis through in vitro anther culture of different Citrus genotypes

In vitro tissue culture represents a useful technique for advancing Citrus breeding and propagation. Among in vitro regeneration systems, anther culture is commonly used to produce haploids and doubled haploids for a fast-track producing homozygous lines, in comparison with the traditional self-pollination approach, which involves several generations of selfing. In addition, anthers culture can produce somatic embryos that can also be used for clonal propagation. In this study, two thermal shocks were applied to the anthers of six Citrus genotypes (two clementine and four sweet oranges), just after they were put in culture. The response obtained was different depending on the genotype: both clementines, namely Hernandina and Corsica, produced homozygous and triploid regenerants (microspore-derived embryos), whereas all of the analyzed regenerants from sweet oranges, three cultivars of Tarocco and Moro, produced heterozygous and diploid regenerants similar to the parental genotypes (somatic embryos).     

柑橘生物技术研究进展

综述了近年来国内外柑橘生物技术的研究进展,主要涉及到以下4个方面:(1)组织培养(包括胚培养、胚珠培养、胚乳培养、花药培养和营养器官培养)与快繁、脱毒和种质资源保存;(2)原生质体培养、再生和融合及体细胞杂种在柑橘砧木及接穗品种改良中的应用;(3)分子标记技术在柑橘遗传多样性检测、基因定位、亲缘关系分析及体细胞杂种鉴定等方面的应用;(4)转基因技术。目前,现代生物技术是柑橘传统育种的有效补充,已成为柑橘遗传改良、种质资源创新和科学研究的重要技术。     

Biotechnology Applications for Sugar Beet

Sugar beet (Beta vulgaris L.) is an important industrial crop, being one of only two plant sources from which sucrose (i.e., sugar) can be economically produced. Despite its relatively short period of cultivation (ca. 200 years), its yield and quality parameters have been significantly improved by conventional breeding methods. However, during the last two decades or so, advanced in vitro culture and genetic transformation technologies have been incorporated with classical breeding programs, the main aim being the production of herbicide-and salt-tolerant, disease- and pest-resistant cultivars. Among the many applications of in vitro culture techniques, sugar beet has benefited the most from haploid plant production, protoplast culture, and somaclonal variation and in vitro cell selection. Several genetic transformation technologies have been developed, such as Agrobacterium-meditated, PEG-mediated, particle bombardment, electroporation, sonication and somatic hybridization, the first two being the most successful. Development of herbicide- and salt-tolerant, virus-, pest/nematode-, fungus/Cercospora- and insect-resistant sugar beet has been demonstrated. However, only herbicide-tolerant varieties have been approved for commercialization but not yet available in the marketplace; rhizomania-resistant varieties are being evaluated in field trials. Transgenic plants that convert sucrose into fructan, a polymer of fructose, were also developed. Initial attempts to increase sucrose yields produced promising results, but it still requires additional work. Despite marked progress in improving regeneration and transformation of sugar beet, genotype dependence and low regeneration and transformation frequencies are still serious restrictions for routine application of in vitro culture and, more importantly, transformation technologies. Selected food safety and environmental impact, as well as regulatory and public acceptance issues relating to transgenic sugar beet are also discussed.     

Indica rice anther culture: can the impasse be surpassed?

During the past two decades numerous papers have been published on anther culture of rice. These studies clearly indicate that while anther culture is a technique that can be adopted for breeding japonica rice, it being a useful adjunct in indica rice breeding is still some way away. The main reasons why anther culture cannot be utilized for indica rice breeding is analyzed, and aspects that may be manipulated to achieve progress are presented in this review. The two stages of rice anther culture, callus induction and green plant regeneration, are genetically determined traits that show quantitative inheritance. Indica rice is known to have a recalcitrant genetic background that supports these traits poorly. While improvement of the genetic background through recombination or gene transfer remains possible, manipulation of culture media, particularly the nitrogen and carbon sources, has brought about substantial improvements in indica rice anther culture. Adjustments to pre- and post-culture conditions, that include application of various stresses on anthers before and after culture, also have had beneficial effects. The importance of reducing the tissue culture phase to achieve direct embryogenesis is discussed with special reference to improving green plant regeneration potential. The necessity to understand the processes involved in microspore embryogenesis is highlighted in order to support empirical knowledge and achieve a breakthrough in technology. In this regard, rice genome sequence information may be leveraged to elucidate functions of genes involved in microspore embryogenesis.