Plant tissue culture. Biotechnology. Milestones

Summary The progress in the development of the technologies of plant tissue and cell culture over the past four decades has been remarkable. This article covers my personal reflections on the various topics and is based on my involvement in the field during that period. There are three fundamental technologies which constitute most of what is referred to as plant in vitro technologies or tissue culture. The origin and some of the key persons involved in the development of each of these procedures will be discussed. The technology that is most common is growing plant tissue on gel-solidified nutrient media. That technology is being used in the most vital procedures, namely the regeneration of plants from cultured cells. The culture of plant cells in liquid suspension was developed very shortly after that, and has become a very effective technology for plant regeneration by somatic embryogenesis. The method of meristem culture arose out of a need for developing plants that were virus-free. In many species the technique is now being used to produce virus-free crop plants. Another important technology is the culture of anthers and microspores for producing haploid and homozygous plants. Included with plant tissue culture is the development of the plant protoplast and cell fusion technologies for the production of new plant hybrids. The final aspect of the development concerns the integration of tissue culture with molecular genetics, which has developed into the rapidly expanding field of biotechnology.     

SOMACLONAL AND GAMETOCLONAL VARIATION

For several years it has been recognized that introduction of plant cells into culture results in genetic changes. These genetic alterations have been recovered in the plants regenerated from cell cultures. More recently it has been recognized that this method of introducing genetic changes into crop plants could be used to develop new breeding lines. The technology of introducing genetic variation by using cell culture has been termed somaclonal and gametoclonal variation. This paper reviews the history of this technology and offers genetic documentation of somaclonal variation in tomato. As this variation represents a new tool for the plant breeder, breeding strategies for the use of this variation are presented and discussed. Somaclonal and gametoclonal variation are new tools for the geneticist and plant breeder that permit reduction in the time period for new variety development and that permit access to new classes of genetic variation.     

Biotechnology and agricultural improvement

A range of emerging technologies are expected to play a significant role in agricultural improvement in the next 20 years. Some are only now being explored, but others have already produced significant results. Recent progress in the tissue culture and genetic engineering of crop plants has opened the door to: (1) large scale and rapid propagation of genetically uniform plants from elite materials; (2) the selection of novel and improved varieties using somaclonal variation technology; (3) the development of new hybrids between different cultivars and species by means of protoplast fusion and (4) the use of recombinant DNA to introduce new genetic material into plant cells. It is expected that, by the year 2000, a wide range of crops will be affected by these advances in biotechnology.     

Germplasm Modification and Its Potential for Finding New Sources of Resistance to Diseases

In vitro procedures are playing a major role in plant breeding. Embryo rescue, either through the culture of excised embryos derived from incompatible crosses or by means of ovule culture, has been a standard procedure for the introgression of genes conferring disease resistance into economically important plants. Somatic hybridization (i.e., protoplast fusion) has also been demonstrated to have some potential in obtaining hybrids that result from very wide interspecific and intergeneric crosses. Wide crosses have also been achieved by means of in vitro pollination of excised ovaries or ovules. Tissue culture-induced variability in regenerated plant (i.e., somaclonal variation) appears to be an effective way of obtaining undirected genetic change that can enhance disease resistance and yield and alter the growth habit of crops that are normally propagated vegetatively (e.g., potato) or by seed (e.g., tomato). In the near future, the isolation and sequencing of genes that confer resistance to specific plant pathogens will be possible, and transfer of this information between species will become a reality.     

Somaclonal variation — a novel source of variability from cell cultures for plant improvement

Summary It is concluded from a review of the literature that plant cell culture itself generates genetic variability (somaclonal variation). Extensive examples are discussed of such variation in culture subclones and in regenerated plants (somaclones). A number of possible mechanisms for the origin of this phenomenon are considered. It is argued that this variation already is proving to be of significance for plant improvement. In particular the phenomenon may be employed to enhance the exchange required in sexual hybrids for the introgression of desirable alien genes into a crop species. It may also be used to generate variants of a commercial cultivar in high frequency without hybridizing to other genotypes.     

Crop improvement through tissue culture

Plant tissue culture comprises a set of in vitro techniques, methods and strategies that are part of the group of technologies called plant biotechnology. Tissue culture has been exploited to create genetic variability from which crop plants can be improved, to improve the state of health of the planted material and to increase the number of desirable germplasms available to the plant breeder. Tissue-culture protocols are available for most crop species, although continued optimization is still required for many crops, especially cereals and woody plants. Tissueculture techniques, in combination with molecular techniques, have been successfully used to incorporate specific traits through gene transfer. In vitro techniques for the culture of protoplasts, anthers, microspores, ovules and embryos have been used to create new genetic variation in the breeding lines, often via haploid production. Cell culture has also produced somaclonal and gametoclonal variants with crop-improvement potential. The culture of single cells and meristems can be effectively used to eradicate pathogens from planting material and thereby dramatically improve the yield of established cultivars. Large-scale micropropagation laboratories are providing millions of plants for the commercial ornamental market and the agricultural, clonally-propagated crop market. With selected laboratory material typically taking one or two decades to reach the commercial market through plant breeding, this technology can be expected to have an ever increasing impact on crop improvement as we approach the new millenium.D.C.W. Brown is with Agriculture and Agri-Food Canada, Central Experimental Farm, Plant Research Centre, Ottawa, Ontario, K1A 0C6, Canada. T.A. Thorpe is with the Plant Physiology Research Group, Department of Biological Sciences, University of Calgary, Calgary, Alberta, T2N 1N4, Canada     

The impact of hybrids between genetically modified crop plants and their related species: general considerations

Factors influencing the fate and impact of hybrids between crop plants and their related species operate from the early zygote, through to plant establishment in different habitats, to their ability to form self-sustaining populations. Many of the classes of genes being introduced by modern methods of genetic modification are similar to those manipulated by conventional plant breeding. In assessing the impact of transgenes in hybrids between crops and related species, therefore, it is important to be informed about the consequences of hybridization between conventionally bred varieties and their relatives. Some transgenes will have novel effects (e.g. production of pharmaceutical substances or certain fatty acids) on plants, and are likely to need specific assessment studies to determine their impact on hybrids. This will be particularly important if there is the possibility of these transgenes becoming established in wild populations. Some recommendations for further research are outlined.     

Organ-specific and ploidy-dependent somaclonal variation; a new tool in breeding

The organ-specific somaclonal variation means the differences between the variability of somaclones originated from different somatic tissue of plant. Significant differences in some agronomical characters were achieved among somaclones of seed and plumule meristem origin. The ploidy-dependent somaclonal variation means the differences between the variability of somaclones originated from different ploidy-level tissue. Increased variation among regenerated plants was postulated by origin from cultured cells of reduced ploidy level. The comparison of somaclonal variation in the progenies of diploid plants regenerated from callus of haploid and diploid origin supported the ploidy dependent theory. The pollenhaploid somaclone method (PHS-method) was developed and tested for utilization somaclonal variation in rice breeding. The PHS-method comprises the two well-known and widely applied in vitro methods which are the androgenesis (another culture) and genetic instability of cultured haploid somatic cells (callus cultures). Developmental varieties produced by this breeding sheme are under certification in Hungary.     

水稻(Oryza sativa)原生质体经钝化后诱导融合再生可育体细胞杂种

本研究在初步实现水稻原生质体培养的程序化后,选用普通栽培稻P339和特种稻苏御糯选的原生质体为融合亲本,利用碘乙酸(IA)和罗丹明-6G(R-6G)这两个代谢互补抑制剂钝化处理亲本原生质体,确定了合适的抑制条件。P339用0.25mmol/L IA,苏御糯选用50μg/ml R-6G分别经30min钝化处理,通过PEG和高Ca~(2 )、高pH法诱导融合,异源融合体具有代谢互补效应,经培养得到愈伤组织17块,并进一步分化获得不同形态的再生植株12棵。移栽存活的再生植株成熟后可育,通过对这些植株的形态以及酯酶和过氧化物酶同工酶电泳的分析表明是融合后的体细胞杂种植株。     

Insect-resistant plants with improved horticultural traits from interspecific potato hybrids grown in vitro

Summary Plants were regenerated from petiole calli of interspecific hybrids of Solanum tuberosum x S. berthaultii, an insect-resistant wild species. Callus culture was used to generate genetic changes to overcome the restricted recombination between the two genomes. Two plants out of 58 (3.5%) from calli of hybrid J114-1 showed stable and heritable differences from the hybrid over two cycles of evaluations in the field. Replicated trials were conducted in 1987 and 1988, using two populations of plants propagated by nodal cuttings from the original regenerates maintained in vitro. One regenerate showed insect resistance and increased marketable yield (approximately two fold) in the field. The other had higher levels of phenolic exudate in one of the two types of foliar trichomes associated with the insect resistance mechanism. Some desirable changes were discernible only in sexual progeny of regenerates, not in the regenerates themselves. In a backcross to S. tuberosum, 7 of 14 (50%) regenerates from hybrid F743-4 showed more progeny (up to 15-fold) with improved trichome traits and horticultural characteristics than the original hybrid. The variations were not associated with changes in ploidy. Fifteen plants obtained from these crosses are currently being incorporated into breeding lines. These results suggest that a period of callus culture followed by plant regeneration may aid in the introgression of desirable traits from wild species into crop plants.     

Stable transformation and tissue culture response in current European winter wheats (Triticum aestivum L.)

In order to efficiently complement traditional wheat breeding with genetic transformation technology it will be desirable to introduce transgenes into the ideal genetic background. Poor tissue culture performance is limiting the number of wheat genotypes that can be stably transformed. We statistically analysed the tissue culture response of 38 current European winter wheats and discuss genetic factors influencing this trait. Although regenerable callus cultures could be initiated from immature embryos of all 38 winter wheats analysed, the number of regenerated plants per cultured explant differed highly significantly (p<0.01) among genotypes. Ten cultivars with excellent ranking in this parameter were selected for transformation experiments. Independent transgenic plants were recovered from nine winter wheat genotypes with a frequency ranging between 0.2% and 2.0% of the cultured immature embryos after biolistic transfer of the bar gene and bialaphos selection. The nine transformable winter wheat genotypes included a recently released high-yielding, disease-resistant cultivar (cv. Certo), well established cultivars with elite bread-making quality (cv. Tarso, Alidos) and current breeding lines differing in yield, disease resistance and grain quality. Transgene integration and expression were confirmed by Southern blot analysis, polymerase chain reaction, phosphinothricin acetyltransferase activity assay and herbicide application. Transgene expression was stably transmitted to the sexual progeny of all transgenic lines analysed and segregated in a Mendelian fashion in the majority of lines. The introduction of transgenes into the ideal genetic background will allow a thorough evaluation of their crop improvement potential.     

植物体细胞杂交及其杂种鉴定方法研究进展

植物体细胞杂交使远缘杂交不亲和的植物有可能实现遗传物质重组,创造和培养植物新品种乃至新物种,尤其在多基因控制农艺性状的改良上具有较大优势.随着原生质体融合技术和现代分子生物学的发展,体细胞融合再生植株的植物种属范围不断扩大,杂种鉴定的方法和手段也有了很大提高.本文就近年来植物体细胞杂交的技术手段、筛选体系和杂种检测方法进行了综述,并展望了其应用和发展前景.     

月季组织培养和遗传转化体系的研究进展

月季通过器官和体细胞胚发生途径都可以获得再生植株,在遗传转化中主要是利用体细胞胚作为转化受体。目前,利用农杆菌介导法和基因枪法已成功将外源基因如报告基因、抗病基因和改变花色的基因等导入月季基因组中。本文对近年来月季组织培养和转基因研究进展进行了综述,为建立月季高效遗传转化体系奠定了理论基础。     

Improved isolation of dihaploidsolanum tubersoum protoplasts and the production of somatic hybrids between dihaploidS. tuberosum andS. brevidens

Summary A modified protoplast isolation technique, applicable to a range of dihaploidSolanum tuberosum genotypes, has been developed. A combination of high calcium and high pH was used to fuse mesophyl protoplasts of dihaploidS. tuberosum (PDH40) and the diploid wild speciesS. brevidens. Large numbers of colonies were obtained after fusion and putative hybrids selected on the basis of phenotype from regenerated shoots. From these, 11 somatic hybrid plants have been identified by their isoenzyme patterns and morphologic characteristics. Four of these hybrids had the expected chromosome number of 48. The approach of mass culture after fusion followed by selection of hybrids from regenerated shoots and the application of somatic hybridization to potato breeding are discussed.     

Developing stress tolerant plants through in vitro selection—An overview of the recent progress

Biotic and abiotic stresses impose a major threat to agriculture. Therefore, the efforts to develop stress-tolerant plants are of immense importance to increase crop productivity. In recent years, tissue culture based in vitro selection has emerged as a feasible and cost-effective tool for developing stress-tolerant plants. Plants tolerant to both the biotic and the abiotic stresses can be acquired by applying the selecting agents such as NaCl (for salt tolerance), PEG or mannitol (for drought tolerance) and pathogen culture filtrate, phytotoxin or pathogen itself (for disease resistance) in the culture media. Only the explants capable of sustaining such environments survive in the long run and are selected. In vitro selection is based on the induction of genetic variation among cells, tissues and/or organs in cultured and regenerated plants. The selection of somaclonal variations appearing in the regenerated plants may be genetically stable and useful in crop improvement. This review focuses on the progress made towards the development of stress-tolerant lines through tissue culture based in vitro selection. Plants have evolved many biochemical and molecular mechanisms to survive under stress conditions. The mechanisms of ROS (reaction oxygen species) generation and removal in plants under biotic and abiotic stress conditions have also been reviewed.     

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.     

High frequency plant regeneration from rice protoplasts by novel nurse culture methods

Summary Novel nurse culture methods have been developed for plant regeneration from protoplasts of rice (Oryza sativa). The nurse culture methods use the agarose-bead type culture in combination with actively growing nurse cells that are either in the liquid part of the culture or inside a culture plate insert placed in the centre of the dish. Protoplasts isolated from either primary seed calluses or suspension cultures of various callus origins, divided and formed colonies with a frequency of up to 10% depending on the protoplast source and the genotype. The presence of nurse cells was absolutely required for the induction of protoplast division. Plants were regenerated from protoplast-derived calluses of five tested cultivars with a frequency of 17%–50%. Close examination of the plant regeneration process suggested that plants are regenerated through somatic embryogenesis from protoplast-derived calluses. Over 300 protoplast-derived plants were transferred to either pots or the field and are being examined for karyotypic stability and various plant phenotypes.     

Improving salinity tolerance in crop plants: a biotechnological view

Salinity limits the production capabilities of agricultural soils in large areas of the world. Both breeding and screening germplasm for salt tolerance encounter the following limitations: (a) different phenotypic responses of plants at different growth stages, (b) different physiological mechanisms, (c) complicated genotype × environment interactions, and (d) variability of the salt-affected field in its chemical and physical soil composition. Plant molecular and physiological traits provide the bases for efficient germplasm screening procedures through traditional breeding, molecular breeding, and transgenic approaches. However, the quantitative nature of salinity stress tolerance and the problems associated with developing appropriate and replicable testing environments make it difficult to distinguish salt-tolerant lines from sensitive lines. In order to develop more efficient screening procedures for germplasm evaluation and improvement of salt tolerance, implementation of a rapid and reliable screening procedure is essential. Field selection for salinity tolerance is a laborious task; therefore, plant breeders are seeking reliable ways to assess the salt tolerance of plant germplasm. Salt tolerance in several plant species may operate at the cellular level, and glycophytes are believed to have special cellular mechanisms for salt tolerance. Ion exclusion, ion sequestration, osmotic adjustment, macromolecule protection, and membrane transport system adaptation to saline environments are important strategies that may confer salt tolerance to plants. Cell and tissue culture techniques have been used to obtain salt tolerant plants employing two in vitro culture approaches. The first approach is selection of mutant cell lines from cultured cells and plant regeneration from such cells (somaclones). In vitro screening of plant germplasm for salt tolerance is the second approach, and a successful employment of this method in durum wheat is presented here. Doubled haploid lines derived from pollen culture of F₁ hybrids of salt-tolerant parents are promising tools to further improve salt tolerance of plant cultivars. Enhancement of resistance against both hyper-osmotic stress and ion toxicity may also be achieved via molecular breeding of salt-tolerant plants using either molecular markers or genetic engineering.     

The effect of genotype on the rate of regeneration of plants in a microspore culture of Triticum aestivum L

The effect of genotype on the productivity of in vitro microspore culture of wheat (Triticum aestivum) was studied. Wheat cultivars and hybrids bred in Kazakhstan and used in the programs on breeding new high-productivity and disease-resistant cultivars and forms of plants were tested. The genotypes that are responsive to androgenesis have been found among the cultivars tested: cultivars Kazakhstanskaya 4, Kazakhstanskaya 5, and hybrids obtained from crosses with the participation of these cultivars (K-6, B-5, and B-10). Such genotypes are recommended to be used as model objects in the studies on androgenesis and plant biotechnology. Based on the use of haploid technology, wheat dihaploid lines were created that are currently tested by breeders.