Plant genetic engineering for crop improvement

Plant genetic engineering has long since left its experimental stage: transgenic plants with resistance to viruses, bacteria, fungi, various pests and abiotic stresses have already been released in their hundreds. Transgenic plants can produce better fruits and food of higher quality than wild-types, and can be used as bioreactors for the synthesis of pharmaceutically important compounds. This review portrays some of the achievements in this field of plant molecular biology.The authors are with Plant Molecular Biology, Biozentrum, Frankfurt University, Marie-Curie-Strasse 9, D-60439 Frankfurt, Germany     

Plant protoplasts as genetic tool: selectable markers for developmental studies.

Protoplasts have usually been presented as a methodological tool. Even as such, they make possible an impressive array of applications in plant biology. Here we report on the use of protoplast-derived selectable markers in the study of several disturbed genetic systems with obvious effects on plant development: (1) auxotrophic mutants and the control of amino acid biosynthesis and transport in vegetative and reproductive tissues; (2) introgression of alien genetic information across phylogenetic boundaries by protoplast fusion, a consequence of controlled dedifferentiation-redifferentiation processes and attenuated incompatibility reactions in cultured cells; (3) expression (in)stability of foreign genes in transgenic plants during successive meiotic generations and in crosses between independent transformants.     

Plant genetic engineering to improve biomass characteristics for biofuels

Currently, most ethanol produced in the United States is derived from maize kernel, at levels in excess of four billion gallons per year. Plant lignocellulosic biomass is renewable, cheap and globally available at 10-50 billion tons per year. At present, plant biomass is converted to fermentable sugars for the production of biofuels using pretreatment processes that disrupt the lignocellulose and remove the lignin, thus allowing the access of microbial enzymes for cellulose deconstruction. Both the pretreatments and the production of enzymes in microbial tanks are expensive. Recent advances in plant genetic engineering could reduce biomass conversion costs by developing crop varieties with less lignin, crops that self-produce cellulase enzymes for cellulose degradation and ligninase enzymes for lignin degradation, or plants that have increased cellulose or an overall biomass yield.     

Plant regeneration fromArabidopsis thaliana protoplasts

Summary Arabidopsis thaliana protoplasts, isolated from a cell suspension, regenerated cell walls and then exhibited sustained cell divisions. Within 10 days after isolation as many as 40% of the protoplast-derived cells divided. Protoplast-derived calli exhibited a wide range of developmental responses, including apparent embryogenesis. The cell suspension has been cryopreserved.     

Plant regeneration from Carica protoplasts

Summary Rapidly proliferating and highly regenerable suspension cultures of somatic embryos of Carica papaya x C. cauliflora were used for protoplast isolation. On average, protoplast yield was 1.5×10⁶/g fresh weight of somatic embryos. Protoplasts were first cultured in liquid KM8P-S medium for 2 weeks and then plated in the same medium solidified with 1% agarose. About 1.4% of the protoplasts developed directly into somatic embryos. Protoplast-derived somatic embryos proliferated rapidly through direct embryogenesis on modified MS medium supplemented with 1 mg/1 ABA, and developed into plantlets upon transfer to MS medium devoid of plant growth regulators. The plantlets were successfully transplanted to soil.Abbreviations MS Murashige and Skoog medium (1962) - KM8P Kao and Michayluk medium (1975) - NAA -naphthaleneacetic acid - BAP 6-benzylaminopurine - ABA abscisic acid - 2,4-D 2,4-dichlorophenoxyacetic acid - FDA fluorescein diacetate - CPW Frearson et al. medium (1973)     

Plant artificial chromosome technology and its potential application in genetic engineering

Genetic engineering with just a few genes has changed agriculture in the last 20 years. The most frequently used transgenes are the herbicide resistance genes for efficient weed control and the Bt toxin genes for insect resistance. The adoption of the first‐generation genetically engineered crops has been very successful in improving farming practices, reducing the application of pesticides that are harmful to both human health and the environment, and producing more profit for farmers. However, there is more potential for genetic engineering to be realized by technical advances. The recent development of plant artificial chromosome technology provides a super vector platform, which allows the management of a large number of genes for the next generation of genetic engineering. With the development of other tools such as gene assembly, genome editing, gene targeting and chromosome delivery systems, it should become possible to engineer crops with multiple genes to produce more agricultural products with less input of natural resources to meet future demands.     

Plant protoplasts: status and biotechnological perspectives

Plant protoplasts ("naked" cells) provide a unique single cell system to underpin several aspects of modern biotechnology. Major advances in genomics, proteomics, and metabolomics have stimulated renewed interest in these osmotically fragile wall-less cells. Reliable procedures are available to isolate and culture protoplasts from a range of plants, including both monocotyledonous and dicotyledonous crops. Several parameters, particularly the source tissue, culture medium, and environmental factors, influence the ability of protoplasts and protoplast-derived cells to express their totipotency and to develop into fertile plants. Importantly, novel approaches to maximise the efficiency of protoplast-to-plant systems include techniques already well established for animal and microbial cells, such as electrostimulation and exposure of protoplasts to surfactants and respiratory gas carriers, especially perfluorochemicals and hemoglobin. However, despite at least four decades of concerted effort and technology transfer between laboratories worldwide, many species still remain recalcitrant in culture. Nevertheless, isolated protoplasts are unique to a range of experimental procedures. In the context of plant genetic manipulation, somatic hybridisation by protoplast fusion enables nuclear and cytoplasmic genomes to be combined, fully or partially, at the interspecific and intergeneric levels to circumvent naturally occurring sexual incompatibility barriers. Uptake of isolated DNA into protoplasts provides the basis for transient and stable nuclear transformation, and also organelle transformation to generate transplastomic plants. Isolated protoplasts are also exploited in numerous miscellaneous studies involving membrane function, cell structure, synthesis of pharmaceutical products, and toxicological assessments. This review focuses upon the most recent developments in protoplast-based technologies.     

Plant protein improvement by genetic engineering: use of synthetic genes

Methods now exist to construct genes coding for synthetic proteins enriched in essential amino acid content. The production of these synthetic proteins in potato tubers can improve the nutritive value of the potato and increase its importance as a basic food crop.     

Plant mutant tubulin genes as marker selective genes for genetic engineering

The approaches for new marker genes usage in selection of transformed plant cells, which are based on using mutant tubulin genes from natural plant biotypes and, in perspective, from induced plant mutants have been considered. The results of investigations of plant (biotypes, mutants) resistance to herbicides with antimicrotubular mode of action on molecular and cellular levels have been summarized. The reports dealing with study the transferring and the expression of mutant tubulin genes conferring resistance to amiprophosmethyl (phosphorothioamidate herbicide) and to trifluralin (dinitroaniline herbicide) from corresponding N. plumbaginifolia mutants into related and remote plant species by somatic hybridisation methods have been analyzed. The results of experiments on monocotyledonous and dicotyledonous. plant transformation by mutant alpha-tubulin gene conferring resistance to dinitroanilines are described to test the possibility of its using as a marker gene with obtaining, at the same time, a dinitroaniline-resistant plants.     

Plant genetic engineering for biofuel production: towards affordable cellulosic ethanol

Biofuels provide a potential route to avoiding the global political instability and environmental issues that arise from reliance on petroleum. Currently, most biofuel is in the form of ethanol generated from starch or sugar, but this can meet only a limited fraction of global fuel requirements. Conversion of cellulosic biomass, which is both abundant and renewable, is a promising alternative. However, the cellulases and pretreatment processes involved are very expensive. Genetically engineering plants to produce cellulases and hemicellulases, and to reduce the need for pretreatment processes through lignin modification, are promising paths to solving this problem, together with other strategies, such as increasing plant polysaccharide content and overall biomass.     

Plant regeneration from protoplasts of Felicia and Brachycome

Protoplasts were isolated from leaves of axenic shoot cultures of Felicia bergeriana (Kingfisher Daisy) and Brachycome iberidifolia (Swan River Daisy) and from callus cultures of Felicia. Plants were regenerated from all three sources and since both species are of ornamental value (blue flowered) the establishment of plant regeneration provides a basis for their incorporation in somatic hybridisation programmes involving important ornamentals such as Chrysanthemum.Abbreviations BAP 6-benzylaminopurine - IAA indole-3-acetic acid - NAA naphthaleneacetic acid - KIN 6-furfurylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid - GA₃ gibberellic acid - MS Murashige and Skoog (1962) - FDA fluorescein diacetate - f. wt. fresh weight     

Plant regeneration from protoplasts of Dimorphotheca and Rudbeckia

Protoplasts were isolated from leaves, shoots, cotyledons, ray florets and callus cultures of Dimorphotheca aurantiaca (syn. D. sinuata) (Cape Marigold, Star of the Veldt) and Rudbeckia hirta, R. laciniata and R. purpurea; species of ornamental value. For Dimorphotheca, plants were regenerated from protoplasts of all sources apart from the ray floret, whilst for the Rudbeckia species, although protoplast division was induced in most cases, only leaf mesophyll protoplasts of R. hirta c.v. Marmalade gave plants. The establishment of plant regeneration for these ornamental species, from protoplasts, now provides a basis for their somatic hybridisation.Abbreviations BAP 6-benzylaminopurine - IAA indole-3-acetic acid - NAA naphthaleneacetic acid - K kinetin - GA₃ gibberellic acid - MS Murashige and Skoog (1962) - f.wt. fresh weight     

Plant regeneration from protoplasts of Gentiana by embedding protoplasts in gellan gum

A protoplast-to-plant system was developed in Gentiana using a gellan gum-embedding culture. Viable protoplasts could be routinely isolated from in vitro-grown plantlets, and they were embedded in 0.2% gellan gum-solidified B5 medium containing 2 mg l^-1 NAA, 0.1 mg l^-1 TDZ, 0.1 M sucrose and 0.4 M mannitol. Weekly addition of fresh liquid medium was essential for preventing cell browning. Colony growth was promoted by lowering mannitol concentration of the culture media after one month, and visible colonies were produced after 2 months of culture. Shoot regeneration from protoplast-derived calluses was stimulated by 1 to 10 mg l^-1 TDZ in combination with 0.1 mg l^-1 NAA. Protoplast-derived plants were recovered following rooting of the shoots in plant growth regulator-free medium and they were successfully transferred to soil.Abbreviations BA benzylaminopurine - FDA fluorescein diacetate - FW fresh weight - MES 2-N-morpholinoethane sulfonic acid - NAA -naphthaleneacetic acid - TDZ N-1,2,3-thiadiazol-5-yl-N-phenylurea (also called thidiazuron)     

Plant regeneration from root protoplasts of Brassica

Protoplasts isolated enzymatically from roots of Brassica alba (White Mustard), B. campestris (Turnip), B. napus (Rape) and B. oleracea (Cabbage), divided to form callus. Plant regeneration was obtained from protoplast derived tissues of B. napus and B. oleracea, but only rhizogenesis was observed with B. campestris. Tissues of B. alba remained undifferentiated. The suitability of root protoplasts for genetic manipulations in the genus Brassica is discussed.     

Plant regeneration from protoplasts of Capsicum annuum

Leaf protoplasts were isolated from axenic shoot cultures of four varieties of Capsicum annuum (Americano, Dulce Italiano Florida Gynat and Nigrum) and a wild species C. chinense. Protoplasts of both species, cultured in KM8P medium and using agarose bead culture, entered division with the exception of the variety Nigrum. Cell colonies formed callus in agar-solified MS medium supplemented with zeatin and for C. annuum v. Dulce Italiano shoots were regenerated when protoplast-derived calli were transferred to MS medium with 6-BAP. Excised shoots were rooted on MS medium which lacked phytohormones.Abbreviations 6-BAP 6-benzylamino purine - MS Murashige and Skoog (1962) - KM8P Kao and Michayluk (1975) - SDS sodium dodecyl sulphate     

Plant regeneration from leaf protoplasts of apple

Protoplasts were isolated from young leaves or etiolated shoot apices. For initiation of divisions the protoplasts were embedded in sodium alginate and cultivated in MS or MI medium supplemented with 2.2 M BA, 2.6 M NAA and 2.2 M 2,4-dichlorophenoxyacetic acid. The protoplasts of all seven lines tested developed to protocalluses at high frequencies. No genotypic differences were observed. When BA was used in combination with NAA in the regeneration experiments, only a few protocalluses (highest frequency 3%) exhibited shoot organogenesis. When BA was replaced with thidiazuron, the percentage of protocalluses that developed shoots increased in two of three tested lines to 7% and 56%, respectively. Shoot development was achieved under light conditions. The shoots were then rooted and transferred into soil.Abbreviations ABA abscisic acid - BA 6-benzyladenine - 2,4-d 2,4-dichlorophenoxyacetic acid - FW fresh weight - GA₃ gibberellic acid - IBA indole-3-butyric acid - MES 2-N-morpholinoethane sulphonic acid - NAA -naphthaleneacetic acid