A leaf-based regeneration and transformation system for maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.)

Efficient methods for in vitro propagation, regeneration, and transformation of plants are of pivotal importance to both basic and applied research. While being the world’s major food crops, cereals are among the most difficult-to-handle plants in tissue culture which severely limits genetic engineering approaches. In maize, immature zygotic embryos provide the predominantly used material for establishing regeneration-competent cell or callus cultures for genetic transformation experiments. The procedures involved are demanding, laborious and time consuming and depend on greenhouse facilities. We have developed a novel tissue culture and plant regeneration system that uses maize leaf tissue and thus is independent of zygotic embryos and greenhouse facilities. We report here: (i) a protocol for the efficient induction of regeneration-competent callus from maize leaves in the dark, (ii) a protocol for inducing highly regenerable callus in the light, and (iii) the use of leaf-derived callus for the generation of stably transformed maize plants.     

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.     

In vitro chili pepper biotechnology

Summary Chili pepper is an important horticultural crop that can surely benefit from plant biotechnology. However, although it is a Solanaceous member, developments in plant cell, tissue, and organ culture, as well as on plant genetic transformation, have lagged far behind those achieved for other members of the same family, such as tobacco (Nicotiana tabacum), tomato (Lycopersicon esculentum), and potato (Solanum tuberosum), species frequently used as model systems because of their facility to regenerate organs and eventually whole plants in vitro, and also for their ability to be genetically engineered by the currently available transformation methods. Capsicum members have been shown to be recalcitrant to differentiation and plant regeneration under in vitro conditions, which in turn makes it very difficult or inefficient to apply recombinant DNA technologies via genetic transformation aimed at genetic improvement against pests and diseases. Some approaches, however, have made possible the regeneration of chili pepper plants from in vitro-cultured cells, tissues, and organs through organogenesis or embryogenesis. Anther culture has been successfully applied to obtain haploid and doubledhaploid plants. Organogenic systems have been used for in vitro micropropagation as well as for genetic transformation. Application of both tissue culture and genetic transformation techniques have led to the development of chili pepper plants more resistant to at least one type of virus. Cell and tissue cultures have been applied successfully to the selection of variant cells exhibiting increased resistance to abiotic stresses, but no plants exhibiting the selected traits have been regenerated. Production of capsaicinoids, the hot principle of chili pepper fruits, by cells and callus tissues has been another area of intense research. The advances, limitations, and applications of chili pepper biotechnology 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.     

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.     

Growth modulation of transgenic potato plants by heterologous expression of bacterial carbohydrate-binding module

Transgenic potato plants (Solanum tuberosum cv. Desiree) expressing the bacterial carbohydrate-binding module (CBM) family III, which is part of the Clostridium cellulovorans CBPA, under control of the CaMV 35S promoter were employed to investigate the influence of this protein on plant development. Eleven independent transgenic plants were found to express the cbm gene, at levels varying from one to four copies. Relative to non-transgenic controls, CBM-expressing plants were characterized by significantly more rapid elongation of the main stem. In addition, under both greenhouse and field conditions, the emergence rate of these plants was higher than in the controls, and their leaf area at early stages of development was larger, resulting in faster accumulation of fresh and dry weight than in control plants. Determination of cell size indicated that epidermal cells in young tissue were significantly larger in CBM-expressing than in control potato plants. These findings suggest that the CBM influence at the cellular level my cause significant alterations in plant growth both in tissue culture and in vivo under field conditions.     

In Vitro selection of groundnut cell lines fromCercosporidium personatum culture filtrates and regeneration of resistant plants through cell culture

Cell suspensions derived from immature leaves of the groundnut (Arachis hypogaea L.) were cultured in the presence and absence ofCercosporidium personatum pathotoxic culture filtrates. Cell viability and reactions of cell lines were determined after exposure to various concentrations (25–100%, v/v) of the filtrates. Cell lines have been selected for resistance to the toxin(s) produced byC. personatum. Selected cell lines were used for plant regeneration on regeneration media containingC. personatum culture filtrates. Plant regeneration frequency was found to be low in long-term cultures, whereas it was high in short-term cultures. The selfed progeny of the plants regenerated from the resistant cell lines showed resistance to the pathogen in the field. Six out of 82 plants exhibited enhanced resistance in the R₂ generation. The culture filtrate stimulated callus proliferation as well as plant regeneration at lower concentrations, a response that could prove to be very useful for obtaining disease resistant plants throughin vitro selection.     

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 transformation of wheat: progress during the 1990s into the Millennium

Wheat transformation technology has progressed rapidly during the past decade. Initially, procedures developed for protoplast isolation and culture, electroporation- and polyethylene glycol (PEG)-induced DNA transfer enabled foreign genes to be introduced into wheat cells. The development of biolistic (microprojectile) bombardment procedures led to a more efficient approach for direct gene transfer. More recently, Agrobacterium-mediated gene delivery procedures, initially developed for the transformation of rice, have also been used to generate transgenic wheat plants. This review summarises the considerable progress in wheat transformation achieved during the last decade. An increase in food production is essential in order to sustain the increasing world population. This could be achieved by the development of higher yielding varieties with improved nutritional quality and tolerance to biotic and abiotic stresses. Although conventional breeding will continue to play a major role in increasing crop yield, laboratory-based techniques, such as genetic transformation to introduce novel genes into crop plants, will be essential in complementing existing breeding technologies. A decade ago, cereals were considered recalcitrant to transformation. Since then, a significant research effort has been focused on cereals because of their agronomic status, leading to improved genetic transformation procedures (Bommineni and Jauhar 1997). Initially, the genetic transformation of cereals relied on the introduction of DNA into protoplasts and the subsequent production of callus from which fertile plants were regenerated. More recently, major advances have been accomplished in the regeneration of fertile plants from a range of source tissues, providing an essential foundation for the generation of transgenic plants. This review summarises procedures, vectors and target tissues used for transformation, high-lights the limitations of current approaches and discusses future trends. The citation of references is limited, where possible, to the most relevant or recent reports.     

Transformation of different barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) cultivars by <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> infection of in vitro cultured ovules

Most cultivars of higher plants display poor regeneration capacity of explants due to yet unknown genotypic determined mechanisms. This implies that technologies such as transformation often are restricted to model cultivars with good tissue characteristics. In the present paper, we add further evidence to our previous hypothesis that regeneration from young barley embryos derived from in vitro-cultured ovules is genotype independent. We investigated the ovule culture ability of four cultivars Femina, Salome, Corniche and Alexis, known to have poor response in other types of tissue culture, and compared that to the data for the model cultivar, Golden Promise. Subsequently, we analyzed the transformation efficiencies of the four cultivars using the protocol for Agrobacterium infection of ovules, previously developed for Golden Promise. Agrobacterium tumefaciens strain AGL0, carrying the binary vector pVec8-GFP harboring a hygromycin resistance gene and the green fluorescence protein (GFP) gene, was used for transformation. The results strongly indicate that the tissue culture response level in ovule culture is genotype independent. However, we did observe differences between cultivars with respect to frequencies of GFP-expressing embryos and frequencies of regeneration from the GFP-expressing embryos under hygromycin selection. The final frequencies of transformed plants per ovule were lower for the four cultivars than that for Golden Promise but the differences were not statistically significant. We conclude that ovule culture transformation can be used successfully to transform cultivars other than Golden Promise. Similar to that observed for Golden Promise, the ovule culture technique allows for the rapid and direct generation of high quality transgenic plants.     

Micropropagation of endangered endemic Brazilian bromeliad Cryptanthus sinuosus (L.B. Smith) for in vitro preservation

An efficient liquid culture system for plant regeneration from leaflessstem–root axes of Cryptanthus sinuosus L. B. Smith(Bromeliaceae) was established. High regeneration rates (93%) were achieved inMurashige and Skoog's medium without growth regulators. Whole plants wereobtained in a single-step procedure, resulting in the production of 25.3± 3.6 plants/explant after 6 months of culture. Incubationof plant material at 35 ± 3 °C resulted in an increaseof 60% in the regeneration efficiency compared with tissues incubated at 28± 2 °C. Moreover, after 5–6 sub-cultures in thesame medium, the axes originated bud clusters that could be continuouslymultiplied and gave rise to 19.4 ± 3.2 whole plants per gram of freshmatter. It was estimated that the liquid culture system described is potentiallyable to produce about 4500 plants/explant/year. Rates of 98% acclimatizationwere achieved. The use of plants produced following this method for populationreinforcement and for in vitro preservation programs ofendangered populations is suggested.     

Plant transformation technology

Plant transformation has its roots in the research on Agrobacterium that was being undertaken in the early 1980s. The last two decades have seen significant developments in plant transformation technology, such that a large number of transgenic crop plants have now been released for commercial production. Advances in the technology have been due to development of a range of Agrobacterium-mediated and direct DNA delivery techniques, along with appropriate tissue culture techniques for regenerating whole plants from plant cells or tissues in a large number of species. In addition, parallel developments in molecular biology have greatly extended the range of investigations to which plant transformation technology can be applied. Research in plant transformation is concentrating now not so much on the introduction of DNA into plant cells, but rather more on the problems associated with stable integration and reliable expression of the DNA once it has been integrated.     

The myth of plant transformation

Technology development is innovative to many aspects of basic and applied plant transgenic science. Plant genetic engineering has opened new avenues to modify crops, and provided new solutions to solve specific needs. Development of procedures in cell biology to regenerate plants from single cells or organized tissue, and the discovery of novel techniques to transfer genes to plant cells provided the prerequisite for the practical use of genetic engineering in crop modification and improvement. Plant transformation technology has become an adaptable platform for cultivar improvement as well as for studying gene function in plants. This success represents the climax of years of efforts in tissue culture improvement, in transformation techniques and in genetic engineering. Plant transformation vectors and methodologies have been improved to increase the efficiency of transformation and to achieve stable expression of transgenes in plants. This review provides a comprehensive discussion of important issues related to plant transformation as well as advances made in transformation techniques during three decades.     

Melon Fruits: Genetic Diversity,Physiology, and Biotechnology Features

Among Cucurbitaceae, Cucumis melo is one of the most important cultivated cucurbits. They are grown primarily for their fruit, which generally have a sweet aromatic flavor, with great diversity and size (50 g to 15 kg), flesh color (orange, green, white, and pink), rind color (green, yellow, white, orange, red, and gray), form (round, flat, and elongated), and dimension (4 to 200 cm). C. melo can be broken down into seven distinct types based on the previously discussed variations in the species. The melon fruits can be either climacteric or nonclimacteric, and as such, fruit can adhere to the stem or have an abscission layer where they will fall from the plant naturally at maturity. Traditional plant breeding of melons has been done for 100 years wherein plants were primarily developed as open-pollinated cultivars. More recently, in the past 30 years, melon improvement has been done by more traditional hybridization techniques. An improvement in germplasm is relatively slow and is limited by a restricted gene pool. Strong sexual incompatibility at the interspecific and intergeneric levels has restricted rapid development of new cultivars with high levels of disease resistance, insect resistance, flavor, and sweetness. In order to increase the rate and diversity of new traits in melon it would be advantageous to introduce new genes needed to enhance both melon productivity and melon fruit quality. This requires plant tissue and plant transformation techniques to introduce new or foreign genes into C. melo germplasm. In order to achieve a successful commercial application from biotechnology, a competent plant regeneration system of in vitro cultures for melon is required. More than 40 in vitro melon regeneration programs have been reported; however, regeneration of the various melon types has been highly variable and in some cases impossible. The reasons for this are still unknown, but this plays a heavy negative role on trying to use plant transformation technology to improve melon germplasm. In vitro manipulation of melon is difficult; genotypic responses to the culture method (i.e., organogenesis, somatic embryogenesis, etc.) as well as conditions for environmental and hormonal requirements for plant growth and regeneration continue to be poorly understood for developing simple in vitro procedures to culture and transform all C. melo genotypes. In many cases, this has to be done on an individual line basis. The present paper describes the various research findings related to successful approaches to plant regeneration and transgenic transformation of C. melo. It also describes potential improvement of melon to improve fruit quality characteristics and postharvest handling. Despite more than 140 transgenic melon field trials in the United States in 1996, there are still no commercial transgenic melon cultivars on the market. This may be a combination of technical or performance factors, intellectual property rights concerns, and, most likely, a lack of public acceptance. Regardless, the future for improvement of melon germplasm is bright when considering the knowledge base for both techniques and gene pools potentially useable for melon improvement.     

<Emphasis Type="Italic">In vitro</Emphasis> propagation of some important chinese medicinal plants and their sustainable usage

Summary Medicinal plants are valuable sources of medicinal and many other pharmaceutical products. The conventional propagation method is the principal means of propagation and takes a long time for multiplication because of a low rate of fruit set, and/or poor germination and also sometimes clonal uniformity is not maintained through seeds. The plants used in the phyto-pharmaceutical preparations are obtained mainly from the natural growing areas. With the increase in the demand for the erude drugs, the plants are being overexploited, threatening the survival of many rate species. Also, many medicinal plant species are disappearing at an alarming rate due to rapid agricultural and urban development, uncontrolled deforestation, and indiscriminate collection. Advanced biotechnological methods of culturing plant cells and tissues should provide new means for conserving and rapidly propagating valuable, rare, and endangered medicinal plants. The purpose of the present review is to focus the application of tissue culture technology for in vitro propagation via somatic embryogenesis and organogenesis and the cell suspension culture with suitable examples reported earlier. An overview of tissue culture studies on important Chinese medicinal plants and related species is presented.     

Analysis of single protoplasts and regenerated plants by PCR and RAPD technology

Summary We investigated the use of the polymerase chain reaction (PCR) and the associated random amplification of polymorphic DNA (RAPD) technique in the analysis of DNA and specific genes in plant cells at different stages of regeneration in in vitro cultures. We demonstrate that both procedures can be used to differentiate reproducibly between closely related species as well as to reveal levels of DNA polymorphism in regenerated plants. We also demonstrate that both procedures, using protocols that we have developed, are applicable at all tissue culture stages, from single isolated protoplasts to regenerated plants. Possible explanations for the variation levels detected in regenerated wheat plants are advanced.     

Somatic embryogenesis in sugarcane—An addendum to the invited review ‘sugarcane biotechnology: The challenges and opportunities,’ in vitro cell. Dev. Biol. Plant 41(4):345–363; 2005

Summary Since the 1960s, numerous studies on sugarcane plant regeneration have been reported. Essentially, successful culture and regeneration of plants from protoplasts, cells, callus, and various tissue and organs, have been achieved in this crop. Although plant regeneration from callus cultures had been reported since the 1960s, definitive proof of somatic embryo development was not available until 1983. Since then, considerable progress has been made in understanding and refining somatic embryogenesis and plant regeneration in sugarcane, for which development of an efficient embryogenic system was critical for the application of transgenic technology. Recent research in Australia and South Africa has led to the development of direct somatic embryogenic systems, which may improve transgenesis in sugarcane.     

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.     

Meiotic and isozymic characterization of plants regenerated from euploid and selfed monosomic tall fescue embryos

Summary Tissue culture of tall fescue (Festuca arundinacea Schreb., 2n=6x=42) would be enhanced by improving the callus induction and plant regeneration efficiency, and evaluating the meiotic and isozymic variation induced by culture. Mature embryos were cultured from four lines of Kenhy tall fescue and from the progeny of three selfed monosomics. Evaluation of six media-auxin combinations showed callus initiation was greatest on SH medium with 2.5 mg/l 2,4,5-T or 7.4 mg/l pCPA, while plant regeneration was greatest on SH medium with 0.5 mg/l 2,4-D. Cytological analyses of 27 plants derived from euploid parents showed a high frequency of aneuploidy (15/27). Chromosome numbers of aneuploids ranged from 36 to 41, with one plant having 80 chromosomes and two plants being asynaptic. Two of ten monosomic-derived plants were euploid, five were monosomic, one was monosomic with a fragment and two were double monosomic. Zymograms of the parents and regenerants were obtained for the enzymes ACPH, ADH, GOT, 6-PGD and PGI. Isozyme variation was observed for two groups of plants derived from the same Kenhy embryos. One group of four monosomic-derived plants differed for the enzymes GOT and ACPH, and all four plants had a PGI pattern. different from that of the parental monosomic plant. This indicated loss of a PGI allele, probably as a result of callus culture.Contribution No. 89-3-141 of the Kentucky Agricultural Experiment Station in cooperation with the USDA-ARS. Part of thesis research for senior author's M. S. degree