Screening wheat genotypes for high callus induction and regeneration capability from anther and immature embryo cultures

Plant regeneration via tissue culture varies with the genotype and is an important factor in establishing cell selection and genetic transformation systems. To select genotypes – especially Japanese ones – with a high regeneration capability, we screened 107 wheat genotypes (78 domestic, 29 foreign) for callus induction and regeneration capability from anther and immature embryo cultures. For anther culture, 83 of 107 genotypes tested induced calli and 45 regenerated plants. Only 9 genotypes, however, produced green plants, 25 produced only albino plants, and 11 produced both green and albino plants. Glennson 81 was the highest in callus induction, followed by Orofen, Danchi–komugi and Chris. The genotypes with a relatively high regeneration capability were Framala 80 at 24% and Glennson 81 at 19%, these two genotypes produced only green plants. For immature embryo culture, 97 genotypes showed a 90% callus induction rate and 74 genotypes regenerated plants. Very few genotypes produced albino plants. The genotypes with a high regeneration capability were Genaro 81 at 90%, Chinese Spring at 80%, and Norin 75 at 75%. This revised version was published online in June 2006 with corrections to the Cover Date.     

荔枝生物技术研究进展

综述了离体培养、有利基因的克隆及遗传转化等生物技术的三个方面在荔枝研究中的应用进展。已有研究者分别建立了花粉培养、叶片培养、幼胚培养等获得植株的再生体系,克隆了部分荔枝基因,建立了基因枪与根癌农杆菌转化体系。这些研究为荔枝生物技术育种提供了基础。     

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。     

Plant tissue culture and biotechnology: perspectives in the history and prospects of the International Association of Plant Biotechnology (IAPB)

The evolutionary route from plant tissue culture (IAPTC) to plant biotechnology (IAPB). Plant biotechnology is an evolutionary scientific process, formulated and maintained by our accumulated cultural-societal knowledge and the invention of new technologies (Altman and Mesoudi submitted). It emerged thousands of years ago when wheat, rice, chickpeas, potatoes, and coffee (and other plants) were first domesticated; when grains were fermented by yeasts to produce bread; and when grape juice, barley, and tubers fermentation resulted in wine, alcohol, and beer. The modern era of plant biotechnology started in the beginning of the twentieth century and is associated with the ability to grow plant cells and tissues in vitro, to regenerate and clone new plants and, later, to modify their genetic characteristics by molecular breeding, including molecular marker-assisted selection (MAS), genetic modification (GM), and, more recently, genome editing. Additional novel procedures will most probably follow in the future.

     

From axenic spore germination to molecular farming

The first bryophyte tissue culture techniques were established almost a century ago. All of the techniques that have been developed for tissue culture of seed plants have also been adapted for bryophytes, and these range from mere axenic culture to molecular farming. However, specific characteristics of bryophyte biology—for example, a unique regeneration capacity—have also resulted in the development of methodologies and techniques different than those used for seed plants. In this review we provide an overview of the application of in vitro techniques to bryophytes, emphasising the differences as well as the similarities between bryophytes and seed plants. These are discussed within the framework of physiological and developmental processes as well as with respect to potential applications in plant biotechnology.     

Analysis of biochemical and physiological changes in wheat tissue culture using different germplasms and explant types

To select adequate wheat germplasms for genetic transformation, tissue culture efficiency of 21 different wheat lines (Einkorn, Emmer, Durum wheat, etc.) were compared, along with two different explants, namely, immature embryo and mature embryo. The results showed that the average differentiation rate and regeneration rate of immature embryo calli (46.5 and 20.82 %) were better than those for mature embryo calli (14.03 and 4.37 %). The best genotypes for immature embryo callus culture were ‘Ningchun 16’ and ‘Ei 15’, ‘Xiaoyan 22’, followed by ‘Durum 332’ and ‘Tr 256’. The best genotypes for mature embryo callus culture were ‘Ying 4286’, ‘Yunyin 01’, and ‘Xiaoyan 22’. To analyze how physiological and biochemical settings influence the totipotency of calli, different physiological and biochemical indices were analyzed. Differences between immature embryo callus and mature embryo callus were significant, as well as differences of most indices among different wheat types. The interaction effects between explant types and genotypes were also significant. Correlation analysis results showed that the total phenol and soluble sugar contents were significantly correlated with callus differentiation and regeneration rates.     

不同组织培养途径对小麦再生能力的研究

从现在推广的小麦优良品种和有苗头的新品系中选用10个小麦基因型品种进行组织培养,从愈伤组织诱导率、绿苗分化率等方面比较了幼穗培养、花药培养、幼胚培养三种培养方式的培养效果。结果表明,幼胚培养效果最好,基因型间差异小,都能获得足够数量的再生植株。幼穗的培养效果最差,愈伤组织分化生根和绿芽十分容易,但分化成完整植株则较为困难。花药培养在基因型间差异非常明显而且有较多白化苗。此外,本研究还分析了影响小麦再生能力的因素,建立了一套高效、可靠的小麦组培再生系统,为小麦的转基因技术提供优良的受体材料。     

History of plant tissue culture

Plant tissue culture, or the aseptic culture of cells, tissues, organs, and their components under defined physical and chemical conditions in vitro, is an important tool in both basic and applied studies as well as in commercial application. It owes its origin to the ideas of the German scientist, Haberlandt, at the begining of the 20th century. The early studies led to root cultures, embryo cultures, and the first true callus/tissue cultures. The period between the 1940s and the 1960s was marked by the development of new techniques and the improvement of those that were already in use. It was the availability of these techniques that led to the application of tissue culture to five broad areas, namely, cell behavior (including cytology, nutrition, metabolism, morphogenesis, embryogenesis, and pathology), plant modification and improvement, pathogen-free plants and germplasm storage, clonal propagation, and product (mainly secondary metabolite) formation, starting in the mid-1960s. The 1990s saw continued expansion in the application of the in vitro technologies to an increasing number of plant species. Cell cultures have remained an important tool in the study of basic areas of plant biology and biochemistry and have assumed major significance in studies in molecular biology and agricultural biotechnology. The historical development of these in vitro technologies and their applications are the focus of this chapter.     

Zygote implantation to cultured ovules leads to direct embryogenesis and plant regeneration of wheat

Direct embryogenesis and plant regeneration were obtained by implantation of individual wheat ( Triticum aestivum L.) zygotes into cultured ovules of wheat or barley. The zygotes were isolated mechanically from emasculated spikes, 3–9 h after hand-pollination. In 13 independent experiments, a total of 186 zygotes were implanted into excised ovules obtained from emasculated spikes which had been treated previously with 2,4-dichlorophenoxyacetic acid to induce parthenocarpic, embryoless ovary development. On average, 17.2% of the implanted zygotes gave rise to dorsiventrally differentiated embryos. The embryos resembled those growing in planta with no obvious deviation from the zygotic embryogenesis pathway. In contrast to previously described regeneration systems from individual zygotes of higher plants, this is the first study in which direct embryo formation is reproducibly obtained without intermediate tissue dedifferentiation. Most embryos germinated when transferred to regeneration medium, and later formed phenotypically normal, fully fertile plants. Regenerants were confirmed to be derived from the implanted zygotes by means of AFLP and/or morphological analyses. Although zygote implantation has long been established as a useful method in sexual animal reproduction, an equivalent technique for plants is described here for the first time. Since the zygotes enter the embryogenic pathway directly, the genome is presumably as stable as during embryogenesis in planta . With this new approach, isolated wheat zygotes are accessible to micromanipulation without affecting their subsequent embryonic development.     

Efficient callus induction and plant regeneration from mature embryo culture of winter wheat (Triticum aestivum L.) genotypes

Immature and mature embryos of 12 common winter wheat (Triticum aestivum) genotypes were cultured in vitro to develop an efficient method of callus formation and plant regeneration from mature embryo culture, and to compare the responses of both embryo cultures. Fifteen days after anthesis, immature embryos were aseptically dissected from seeds and placed with the scutellum upwards on a solid agar medium containing the inorganic components of Murashige and Skoog (MS) and 2 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D). Mature embryos were moved slightly in the imbibed seeds. The seeds with moved embryos were placed furrow downwards in dishes containing 8 mg/l 2,4-D for callus induction. The developed calli and regenerated plants were maintained on 2,4-D-free MS medium. Plants regenerated from both embryo cultures were vernalized and grown to maturity in soil. Regenerated plantlets all maintained the hexaploid chromosome number. A strong genotypic effect on the culture responses was found for both explant cultures. Callus induction rate, regeneration capacity of callus and number of plants regenerated were independent of each other. Mature embryos had a high frequency of callus induction and regeneration capacity, and therefore, being available throughout the year, can be used as an effective explant source in wheat tissue culture. Received: 4 February 1997 / Revision received: 1 April 1997 / Accepted: 5 May 1997     

Chromosomal location of genes controlling short-term and long-term somatic embryogenesis in wheat revealed by immature embryo culture of aneuploid lines

The expression of essential genes during somatic embryogenesis can be analysed by inducing aneuploid cells to undergo embryogenesis during immature embryo culture and then determining whether defects occur. Triticum aestivum disomic and aneuploid stocks, including 36 ditelosomics and 7 nullitetrasomic Chinese Spring wheats, were compared for their ability to undergo somatic embryogenesis after 2 months of in vitro immature embryo culture. Their regeneration capacity was observed after 4 and 14 months of in vitro culture to determine which chromosome arms influence the process. The large range of variation found among the tested aneuploids suggested that genetic control of the somatic tissue culture ability is polygenic. Our results indicate that genes affecting somatic embryo-genesis and regeneration are located in all of the homoeologous chromosome groups. The lack of chromosome arms 1AL (DT 1AS) and 3DL (DT 3DS) practically suppresses somatic embryogenesis, demonstrating that major genes on wheat chromosome arms 1AL and 3DL control regeneration capacity. Results suggest that plants were mainly produced from somatic embryo development. Although the control of somatic embryogenesis and regeneration is polygenic, the genes located on the long arms of homoeologous group 3 chromosomes have a major effect. We also have evidence of chromosome arms that determine the time required for regeneration.     

魔芋属植物组织培养与遗传转化研究进展

本文对近20年来魔芋生物技术研究取得的进展进行了系统的回顾分析。组织培养是当前魔芋生物技术研究的主要内容, 魔芋离体植株再生以器官发生途径为主, 包括不定芽和拟球茎两种途径, 后者是当前研究的热点。利用组织培养进行有用突变体的筛选和种质资源的保存也取得了一些有价值的结果。以抗病和品质改良为目的的转基因技术取得了较快发展, 如抗病基因和抗除草剂基因等已实现成功转化。此外, 本文还分析了魔芋生物技术研究中存在的主要问题并提出了相应的对策。     

The role of abscisic acid in plant tissue culture: a review of recent progress

Abscisic acid (ABA) plays a significant role in the regulation of many physiological processes of plants. It is often used in tissue culture systems to promote somatic embryogenesis and enhance somatic embryo quality by increasing desiccation tolerance and preventing precocious germination. ABA is also employed to induce somatic embryos to enter a quiescent state in plant tissue culture systems and during synthetic seed research. Application of exogenous ABA improves in vitro conservation and the adaptive response of plant cell and tissues to various environmental stresses. ABA can act as anti-transpirant during the acclimatization of tissue culture-raised plantlets and reduces relative water loss of leaves during the ex vitro transfer of plantlets even when non-functional stomata are present. This review focuses on the possible roles of ABA in plant tissue culture and recent developments in this area.     

Doubled haploid production in Flax (Linum usitatissimum L.)

There is a requirement of haploid and double haploid material and homozygous lines for cell culture studies and breeding in flax. Anther culture is currently the most successful method producing doubled haploid lines in flax. Recently, ovary culture was also described as a good source of doubled haploids. In this review we focus on tissue and plants regeneration using anther culture, and cultivation of ovaries containing unfertilized ovules. The effect of genotype, physiological status of donor plants, donor material pre-treatment and cultivation conditions for flax anthers and ovaries is discussed here. The process of plant regeneration from anther and ovary derived calli is also in the focus of this review. Attention is paid to the ploidy level of regenerated tissue and to the use of molecular markers for determining of gametic origin of flax plants derived from anther and ovary cultures. Finally, some future prospects on the use of doubled haploids in flax biotechnology are outlined here.     

Genetic analysis of anther culture response in wheat using aneuploid,chromosome substitution and translocation lines

Summary Marked effects of genotype on wheat anther culture response have been observed. Genetic factors have been recognised to be one of the major contributors to in vitro responses of cultured wheat tissues. In wheat anther culture, embryo induction, plant regeneration and albina/green ratio have been determined to be heritable traits. Using Chinese Spring (CS) monosomic 1D, single chromosome substitution lines of chromosome 5B or chromosome arm 5BL from Chinese Spring into six varieties, and F₁ hybrids heterozygous for the 1B chromosome structure (1BL-1BS/1BL-1RS), the anther culture response was studied: genes on CS1D chromosome and 5BL chromosome arm increases the embryo frequency; gene(s) involved in regeneration ability are located on the 1RS chromosome arm; a gene increasing albina frequency is located on Chinese Spring 5B chromosome. Our results support the fact that without gametic selection, a differential development occurred from the particular classes of microspores carrying genes for higher regeneration ability. Moreover, in some crosses, a few genes with major effects were involved in determination of anther culture response.     

魔芋属植物组织培养与遗传转化研究进展

本文对近20年来魔芋生物技术研究取得的进展进行了系统的回顾分析。组织培养是当前魔芋生物技术研究的主要内容,魔芋离体植株再生以器官发生途径为主,包括不定芽和拟球茎两种途径,后者是当前研究的热点。利用组织培养进行有用突变体的筛选和种质资源的保存也取得了一些有价值的结果。以抗病和品质改良为目的的转基因技术取得了较快发展,如抗病基因和抗除草剂基因等已实现成功转化。此外,本文还分析了魔芋生物技术研究中存在的主要问题并提出了相应的对策。     

Plant cell and biotechnology studies in <Emphasis Type="Italic">Linum usitatissimum</Emphasis> – a review

The species Linum usitatissimum (flax/linseed) has been the focus of a great deal of both basic and applied research effort in plant cell and biotechnology studies in recent years. In this review we consider applications of the techniques of plant biotechnology in this species under several distinct headings. Plant cell and tissue regeneration strategies and applications are discussed, and the applications of the techniques of somatic embryogenesis, protoplast isolation, culture and fusion and cell suspension cultures in this species are described. A major area of study is the use of anther and microspore culture where clear advantages to breeding programmes could be applied. In addition, embryo and ovary culture studies have resulted in significant findings. The more recent technologies of gene transfer and expression by genetic transformation are reviewed, and a section on strategies for improvements in technological quality is also included. Finally we propose conclusions and future prospects for this ancient, but still highly relevant crop.     

植物体细胞无性系变异研究进展

植物体细胞无性系变异是植物组织培养中的普遍现象,泛指在植物细胞、组织和器官培养过程中, 培养细胞和再生植株中产生的遗传变异或表观遗传学变异。植物体细胞无性系变异的发生有其遗传学基础, 可从形态学、细胞学、生物化学和分子生物学等多个方面对其进行综合检测和鉴定。植物体细胞无性系变异是植物育种的有利资源, 但同时也是植物微繁和遗传转化工作中需要克服的一大难题,一直被众多研究者所关注。本文分别从细胞学和分子生物学两个层次综述了植物体细胞无性系变异的遗传学基础及其鉴定方法的研究进展,并就其在植物品质改良中的应用现状、存在的问题和应用前景进行了讨论。     

Chlorophyllian durum wheat plants obtained by isolated microspores culture: importance of the pre-treatments

In Triticum turgidum subsp. durum (Desf.) Husn., the utilization of in vitro anther culture is hampered by the very high frequency of albinism of the regenerated plants reaching in most cases 100%. Only in vitro ovary culture or intergeneric crosses with maize produce gynogenetic green haploid and doubled haploid plants. This paper is concerned with another very interesting method of androgenetic doubled haploid plant production, the in vitro isolated microspore culture. It is shown that this method, associated with cold alone or cold plus mannitol pre-treatments, of the spikes kept within their sheath leaves, during different times, have significant positive effects, not only on embryo production, but also on chlorophyllian plant regeneration. All pre-treatments and control taken together, a total of 16 490 embryos was obtained from 17.4 x 10(6) microspores of two T. durum varieties, among which 9320 embryos were transferred to regeneration medium and developed 150 chlorophyllian plants. Thus a long-term (five weeks) 4 degrees C cold pre-treatment of the microspores could be promising for green regeneration in durum wheat.     

Fundamentals and applications of light-emitting diodes (LEDs) in in vitro plant growth and morphogenesis

Advances in plant tissue culture methods with regard to lighting requirements are currently focused on the improved features of light-emitting diodes (LEDs). Over the years, the steady development of LED technology, with the emergence of new types of semi-conductor materials, has made it possible to apply it in an increasing number of new areas. As an alternative to conventional lighting systems, LED has been demonstrated to be an artificial flexible lighting source for plant tissue culture. Numerous studies have been conducted in order to investigate the effects of LED on plants, which have led to many satisfactory results. Various morphological, anatomical, and physiological attributes, such as shoot elongation, axillary shoot formation, somatic embryo induction, rhizogenesis, leaf anatomy, and photosynthetic abilities of plants grown in vitro have found to be regulated by spectral properties of LEDs. The present review gives an overview of the fundamentals of LEDs and describes their effects on in vitro plant growth and morphogenesis and their future potentials.