Showing papers in "In Vitro Cellular & Developmental Biology – Plant in 2002"

Secondary metabolism of hairy root cultures in bioreactors

Abstract: In vitro cultures are being considered as an alternative to agricultural processes for producing valuable secondary metabolites. Most efforts that use differentiated cultures instead of cell suspension cultures have focused on transformed (hairy) roots. Bioreactors used to culture hairy roots can be roughly divided into three types: liquid-phase, gas-phase, or hybrid reactors that are a combination of both. The growth and productivity of hairy root cultures are reviewed with an emphasis on successful bioreactors and important culture considerations. The latter include strain selection, production of product in relation to growth phase, media composition, the gas regime, use of elicitors, the role of light, and apparent product loss. Together with genetic engineering and process optimization, proper reactor design plays a key role in the development of successful large scale production of secondary metabolites from plant cultures.

Mineral nutrition and plant morphogenesis

Abstract: Plant morphogenesis in vitro can be achieved via two pathways, somatic embryogenesis or organogenesis. Relationships between the culture medium and explant leading to morphogenesis are complex and, despite extensive study, remain poorly understood. Primarily the composition and ratio of plant growth regulators are manipulated to optimize the quality and numbers of embryos or organs initiated. However, many species and varieties do not respond to this classical approach and require further optimization by the variation of other chemical or physical factors. Mineral nutrients form a significant component of culture media but are often overlooked as possible morphogenic elicitors. The combination of minerals for a particular plant species and developmental pathway are usually determined by the empirical manipulation of one or a combination of existing published formulations. Often only one medium type is used for the duration of culture even though this formulation may not be optimal for the different stages of explant growth and development. Furthermore, mineral studies have often focused on growth rather than morphogenesis with very little known of the relationships between mineral uptake and morphogenesis. This article examines the present knowledge of the main effects that mineral nutrients have on plant morphogenesis in vitro. In particular, the dynamics of nitrogen, phosphorus, and calcium supply during development are discussed.

Rooting of microcuttings: Theory and practice

Abstract: Poor adventitious root formation is a major obstacle in micropropagation and in conventional propagation. This paper reviews recent progress in the understanding of adventitious root formation as a developmental process focusing on the role of plant hormones and on the effect of rooting conditions on plant performance. Since the discovery of the rhizogenic effect of auxin ca. 70 yr ago, no new broadly applicable rooting treatments have been developed. Recent research, though, may lead to new rooting procedures. Application of wounding-related compounds may be effective in difficult-to-root crops. Furthermore, by adapting conditions during the propagation phase, microcuttings with an enhanced capability to root may be produced. These conditions include elongation of stems (by etiolation or double-layer culture) and repeated subculture (rejuvenation; i.e. transition from adult to juvenile). Data are presented that show that during tissue culture maturation (transition from juvenile to adult) also occurs. The conditions during the in vitro rooting treatment may have a tremendous effect on performance after transfer ex vitro. In particular, accumulation of ethylene during in vitro rooting may have a devastating effect. Addition of stress-protecting compounds during propagation or rooting in vitro may enhance the performance ex vitro.

Feeding a world of 10 billion people: The miracle ahead

Abstract: (1997). Feeding a World of 10 Billion People: The Miracle Ahead. Biotechnology & Biotechnological Equipment: Vol. 11, No. 3-4, pp. 3-13.

Efficiency, genotypic variability, and cellular origin of primary and secondary somatic embryogenesis of Theobroma cacao L.

Abstract: Summary The development of efficient tissue culture systems for cacao holds the potential to contribute to the improvement of this tropical crop by providing a rapid and efficient vegetative propagation system for multiplication of elite genotypes. It may also find application in facilitation of germplasm movement across quarantine borders, enhancement of germplasm conservation via cryo-preservation, and development of genetic transformation systems. Somatic embryogenesis using floral tissue explants was previously the only tissue culture procedure for regeneration of cacao. We report the development of a secondary embryogenesis system utilizing primary somatic embryo cotyledon explants, which results in up to a 30-fold increase in somatic embryo production compared to primary somatic embryogenesis. The influence of genotype on the efficiency of the system was evaluated. To understand the cellular origins and developmental pathways operative in this system, we investigated the morphological changes occurring over time using light and scanning electron microscopy. While primary embryos arise from clusters of cells forming embryonic nodules, secondary embryos arise predominantly from the division of single cells, in a pathway reminiscent of zygotic embryogenesis. These results have important significance to the application of tissue culture to cacao improvement programs.

Maturation of somatic embryos in conifers: Morphogenesis, physiology, biochemistry, and molecular biology

Abstract: In the past 15 years tremendons progress has been made towards the development of systems for the induction and development of somatic embryos of coniferous species. Since the first report in 1985, several species have been induced to produce somatic embryos. This has been rendered possible by the development of rational media and improvement of culture conditions, which have resulted in increased embryo quality and higher conversion frequency. Understanding the physiological and biochemical events occurring during in vivo embryogenesis has been fundamental in the design of new protocols for improving the somatic embryogenic process. Specifically, the inclusions of abscisic acid (ABA) and osmotic agents, such as polyethylene glycol (PEG), have been shown to be necessary for the functional development of somatic embryos. In the past few years, physiological and biochemical investigations have been useful in increasing our knowledge on the mode of action of ABA and PEG during embryo development. In comparison with the flowering plants, our understanding on the molecular mechanisms regulating the embryogenic process in coniferous species is still very limited. The application of new molecular techniques is therefore fundamental towards this end. The emphasis of this review is on recent information dealing with the maturation of conifer somatic embryos.

Melatonin: A potential regulator of plant growth and development?

Abstract: Recent research has reported the presence of melatonin (N-acetyl-5-methoxytryptamine), a mammalian indoleamine neurohormone, in higher plants, indicating that melatonin may be an important metabolic regulator that has been highly conserved across biological kingdoms. Melatonin is synthesized from tryptophan in the mammalian pineal gland and a similar biosynthetic pathway was recently described in St. John's wort shoot tissues, wherein radiolabel from tryptophan was recovered in serotonin and melatonin as well as indoleacetic acid. There is growing information describing melatonin control of physiological processes in mammals, yeast, and bacteria, including diurnal responses, detoxification of free radicals, and environmental adaptations. However, at the current time, there is no known specific role for melatonin in plant physiology. Alterations in melatonin concentrations in plant tissues have been shown to affect root development, mitosis, and mitotic spindle formation. The recent advancements in melatonin research in plants and some directions for important areas of future research are reviewed in this article.

Rapid propagation of Phalaenopsis from floral stalk-derived leaves

Abstract: An efficient and rapid in vitro method was developed for regeneration of Phalaenopsis using leaf segments derived in vitro from flower stalk nodes. Leaf segments of four cultivars Tinny Sunshine ‘Annie’, ‘Taisuco Hatarot’, Teipei Gold ‘Golden Star’, Tinny Galaxy ‘Annie’ cultured on Murashige and Skoog medium supplemented with N6-benzyladenine (BA; 88,8 μM) and α-naphthaleneacetic acid (NAA; 5,4 μM) produced an average of 10–13 protocorm-like bodies (PLBs) after 12 wk. PLB proliferation was achieved on a modified Hyponex medium (1 gl−1 6.5N−4.5P−19K+20N−20P−20K+2gl−1 peplone +3% (w/v) potato homogenate +0.05% activated 1 gl−1 charcoal) and an optimal number of 13–18 PLBs developed from single PLB sections of different cultivars. Plantlet development was also achieved on a modified Hyponex medium. By repeated subculture of PLBs on a proliferation medium, and culturing them in the plantlet regeneration medium, plantlets could be produced continuously. Approximately 6 mo, were required from the initiation of culture to the production of plantlets for transplant to community pots.

Auxin and sugar effects on callus induction and plant regeneration frequencies from mature embryos of wheat (Triticum aestivum L.)

Abstract: Genetic engineering of cereals currently depends on the use of tissue culture and plant regeneration systems. In wheat (Triticum aestivum L.), immature embryos are the most widely used explant to initiate cultures, but they are inconvenient due to their temporal availability and production requirements. Mature embryos are easily stored and are readily available as mature seeds. However, plant regeneration frequencies from cultures derived from mature embryos are generally low. This research was undertaken to improve callus induction and plant regeneration from wheat mature embryos of cultivar ‘Bobwhite’. The effects of four auxins [2,4-dichlorophenoxyacetic acid (2,4-D): 3,6-dichloro-o-anisic acid (dicamba); 4-amino-3,5,6-trichloropicolinic acid (picloram): and 2-(2-methyl-4-chlorophenoxy) propionic acid (2-MCPP)], and the effect of maltose vs. sucrose under filter sterilized and autoclaved conditions were evaluated. All auxin treatments resulted in callus induction except 2 MCPP. A highly significant effect of auxin type on both callus and plantlet production was detected, though interactions were observed. The effect of sugar type was dependent on the type of auxin used. Substitution of sucrose by maltose enhanced the regenration ability of callus from embryos cultured on media containing 2,4-D and picloram, but caused an opposite effect on media containing dicamba. Picloram significantly enhanced callus growth, however, embryogenic response and plant regenerability were low. Relative to 2.4-D, dicamba (18μM) resulted in a twofold increase in the number of plants regenerated per embryo and reduced the amount of time required for plant regeneration by 3–4 wk.

Control of In vitro contamination of explants from greenhouse- and field-grown trees

Abstract: Controlling fungal and bacterial contamination of woody plant material can be extremely difficult. Isothiazolone biocides and sodium dichloroisocyanurate have been used singly and in combination to reduce microbial contamination in bud explants derived from greenhouse- and field-grown citrus trees. Explants from greenhouse-grown trees were effectively disinfested (<5% vs. 85% contamination) using a ‘standard’ disinfestation (SD) procedure followed by culture on medium containing 5 ml l−1 Plant Preservative Mixture, or by the SD procedure but substituting 300 ppm sodium dichloroisocyanurate for 48 h for the treatment with 1.05% NaOCl in the SD procedure. Disinfestation of explants from field-grown trees was less effective than explants from the greenhouse, but was improved (10% vs. 47% contamination) by using a combination of the SD procedure with 1.05% NaOCl, or 100 or 300 ppm sodium dichloroisocyanurate followed by culture onto medium containing 5 ml l−1 Plant Preservative Mixture.

Development of an edible subunit vaccine in corn against enterotoxigenic strains of Escherichia coli

Abstract: Advances in the development of subunit vaccines and in the production of foreign proteins in plants together offer the prospect of stable and inexpensive vaccine delivery systems. Various bacterial and viral proteins stably produced in plants have been shown to elicit immune responses in feeding trials. We have extended this approach by using Zea mays as the plant production system. Corn has several advantages as a vaccine delivery vehicle, most notably established technologies to generate transgenic plants, to optimize traits through breeding and to process the seed into a palatable form. Here we report on the production in corn seed of the GM1 receptor binding (B) subunit of the heat-labile toxin (Lt) from enterotoxigenic strains of Escherichia coli. Versions of the Lt-B gene were synthesized to give optimum codon usage for corn and to target the protein to either the cell surface or the cytoplasm. These synthetic genes were fused to a strong promoter and transformed into corn. Lt-B was highly expressed in corn seed at up to 1.8% of the total soluble protein and this was further increased approximately five-fold through plant breeding. As in E. coli. Lt-B produced in corn forms a functional pentamer that can bind to the GM1 receptor. Furthermore, Lt-B pentamer stored in corn seed is much more resistant to heat than is the pure protein, allowing the transgenic corn to be readily processed into an edible form. This work demonstrates the potential of using products derived from transgenic corn seed as delivery vehicles for subunit vaccines.

Growth, proline accumulation and ion content in sodium chloride-stressed callus of date palm

Abstract: Growth and physiological responses of date palm. Phoenix dactylifera L. cv. Barhee, callus to salinity stress were examined. Callus induced from shoot tips of offshoots was cultured on Murashige and Skoog medium supplemented with NaCl at concentrations ranging from 0 to 225 mM, in consective increments of 25 mM. Data obtained after 6 wk of exposure to salt have shown a significant increase in callus proliferation in response to 25 mM NaCl the lowest level tested, beyond which callus weight decreased. At 125 mM NaCl and higher, callus growth was nearly completely inhibited. Physiological studies on callus exposed to salt stress have shown an increase in proline accumulation in response to increased salinity. Proline accumulation was correlated to callus growth inhibition. Furthermore, increasing the concentration of NaCl in the culture medium generally resulted in a steady increase in Na+ and reduction in K+ concentrations. However, at 25 mM NaCl, the only level at which callus growth was significantly enhanced, an increase in K+ content was noted, in comparison to the NaCl free control. In response to increasing external NaCl level, the Na+/K+ ratio increased The Na+/K+ ratio was positively correlated to proline accumulation and hence callus growth inhibition. This study provides, an understanding of the response of date palm callus to salinity, which is important for future studies aimed at developing strategies for selecting and characterizing somaclonal variants tolerant to salt stress.

Plant tissue culture. Biotechnology. Milestones

Abstract: 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.

Biotechnological applications for the improvement of coffee (coffea arabica l.)

Abstract: The important advances in coffee biotechnological techniques which have been made particularly during the last 10yr could benefit the coffee breeder in practice and open new perspectives for the development of new varieties. The molecular phylogeny of Coffea species has been established using DNA sequence data. The molecular markers have revealed an extremely reduced genetic diversity in Coffea arabica L. in comparison to C. canephora. However, wild accessions collected in the Ethiopian highlands appeared to constitute a valuable gene reservoir. A complete genetic linkage map of C. canephora was reported and additional ones are being constructed, particularly on C. arabica. The integration of Molecular Assisted Selection in coffee breeding promises to drastically increase the efficiency of breeding programs. Economically important genes of the caffeine biosynthetic pathway or genes encoding for seed storage proteins have been isolated. The high performance already achieved in the in vitro propagation process by somatic embryogenesis offers the possibility to mass propagate superior hybrids in different countries of both C. arabica (selected F1 hybrids) and C. canephora (rootstock variety). Pilot productions by somatic embryogenesis currently permit preparation for commercial application. Somaclonal variation was observed. The percentage of the off-types can vary between 3 and 10% depending on the genotype. Seed cryopreservation enables a routine use for long-term conservation of coffee genetic resources. Transgenic plants have been obtained for the C. arabica and C. canephora cultivated species through Agrobacterium-mediated transformation which constitutes the technique now currently used to transfer directly genes in coffee plants.

Shoot apical meristem: In vitro regeneration and morphogenesis in wheat (Triticum aestivum L.)

Abstract: We report a less genotype-dependent in vitro regeneration system capable of producing multiple shoot clumps and whole plants in four different wheat genotypes. Shool apical meristems from 7-d-old-seedlings produced axillary and adventitious shoots and somatic embryos on media containing N6-benzyladenine (BA) and 2,4-dichlorophenoxyacetic acid (2,4-D). All four genotypes responded positively to shoot multiplication depending upon media composition. Scanning electron microscopies of cultures showed a proliferating budding state that gave rise to adventitious shoots and somatic embryos on further multiplication. The percentage of relative shoot apical meristem multiplication was 80–90%, and the average number of shoot meristems per multiplied shoot was 40–50 in all genotypes. Among different concentrations of phytohormones, 2 and 4 mgl−1 BA (8.8 and 17.7 μM) in combination with 0.5 mg l−1 2,4-D (2.26 μM) gave the best results. Actively multiplying shoot clumps were recovered with high frequency among 3-mo.-old cultures. These shoot clumps regenerated normally and produced fertile plants containing viable seeds. This in vitro system might prove useful for the production of transgenic plants of wheat in a relatively genotype-independent manner.

In vitro flower induction in roses

Abstract: Vegetatively propagated plantlets of six rose cultivars were induced to flower in vitro on media containing full-strength Murashige and Skoog (MS) inorganic salts, Gamborg's B5 organic elements with 400 mg l−1 myo-inositol, and different phytohormone combinations of 6-benzyladenine (BA) with α-naphthaleneacetic acid (NAA); thidiazuron (TDZ) with NAA; and zeatin (ZT) with NAA. The most efficient flower bud induction (49.1% and 44.1%) was obtained on media supplemented with 0.5 mg l−1 (2.27 μM) TDZ and 0.1 mg l−1 (0.54 μM) NAA or 0.5 mg l−1 (2.28 μM) ZT and 0.1 mg l−1 (0.54 μM) NAA for cultivar Orange Parade. Scanning electron microscopy (SEM) showed that in vitro flower bud induction occurred mostly between 15 and 30 d in induction medium through the normal flower development processes. With TDZ and ZT as the best choice for flower induction in all six cultivars tested, different rose cultivars varied in their responses to phytohormone treatments. Our study also revealed that the total time from original culture and subculture time before flower induction were two very important factors for in vitro flower induction. Plantlets 156–561 d from original culture and subcultured for 45 d were the best for flower induction.

In vitro screening for increased drought tolerance in rice

Abstract: In vitro screening at the cellular level was performed with mature seed-derived callus from five rice varieties, viz. IR 18351-229-3, IR 3185-6-3-3-2, SR 26-B, Nona Bokra, and C 14-8 of diverse geographical origin and with differential drought resistance at the in planta level. Callus was induced from mature seeds on Murashige and Skoog medium supplemented with 2.0 mgl−1 (9 μM) of 2,4-dichlorophenoxyacetic acid (2,4-D) and 5.0, 10.0, and 15.0 gl−1 of high molecular weight polyethylene glycol (PEG, 6000) as stressing agent to create chemical drought. Simultaneous efforts were also made to assess the effects of chemical drought in altering morphogenetic response in different varieties under in vitro culture. Seed germination was almost unaffected in SR 26-B and C 14-8, unlike in other varieties where germination was seriously affected. In general, seed germination was found to be decreased in three genotypes, viz. IR 18351-229-3, IR 3185-6-3-3-2, and Nona Bokra, with increased PEG concentrations. All genotypes displayed callus induction percentage in decreasing order with increased PEG concentrations supplemented in the callus induction medium (CIM), except SR 26-B and Nona Bokra. Callus induction was found to be more on CIM fortified with 5.0 gl−1 PEG. In general, embryogenic callus induction and plantlet regeneration was found to be indirectly proportional to increased PEG concentrations used in CIM. Considering all characters, C 14-8 was found to be most appropriate in developing drought-tolerant lines under in vitro culture conditions followed by SR 26-B and Nona Bokra. A number of putative drought-tolerant plants were developed in C 14-8, SR 26-B, Nona Bokra, and IR 18351-29-3, and forwarded for field evaluation. In the majority of the progenies, a monogenic inheritance pattern for the drought tolerance character was observed.

Occurrence of chromosomal variations and plant regeneration from long-term-cultured citrus callus

Abstract: Embryogenic callus of Anliucheng sweet orange (Citrus sinensis Osbeck) is theoretically diploid. However, significant chromosomal variations occurred when the calluses were subcultured and preserved for a long time. Cytological observation revealed a variety of mitotic irregularities underlying the occurrence of chromosomal variations. Despite the ubiquitous existence of chromosomal variations, long-term-cultured calluses were still capable of producing somatic embryos and plants. Interestingly, chromosomal variants were selected against when somatic embryos and plants regenerated from the embryogenic callus. Randomly amplified polymorphic DNA (RAPD) analysis was also carried out to detect DNA sequence variation in regenerated plants derived from the embryogenic callus. No difference in banding patterns was detected. It was clear that the plant regeneration from long-term-cultured callus was inclined to select against somaclonal variations.

Rapid clonal propagation of nothapodytes foetida (wight) sleumer - a threatened medicinal tree

Abstract: Nothapodytes foetida (Wight) is a small evergreen tree and the extract from this tree is used to make the antileukaemia and antitumoral compound camptothecin. Due to exploitation of this resource, efficient methods for rapid propagation of N. foetida are highly desirable. Multiple shoots were induced on hypocotyl segments of 20–25-d-old seedlings of N. foetida cultured on Murashige and Skoog (MS) medium supplemented with different concentrations and combinations of cytokinins. The highest shoot multiplication was achieved on MS medium containing thidiazuron (TDZ) at the concentration of 2.2 μM. Inhibition of shoot elongation by TDZ was overcome by transferring shoot cultures to medium containing 2.2 μM benzylaminopurine which produced healthy shoots after three additional subcultures. The production of shoots was further promoted by repeated subculturing of original explants on fresh multiplication medium after each harvesting of the newly formed shoots. In vitro rooting was best induced (87%) in shoots excised from proliferated shoot cultures on one-fourth MS medium augmented with 5.7 μM indole-3-acetic acid and 2.4 μM indolebutryic acid (IBA). In vitro-developed shoots were also rooted ex vitro by dipping in 49 μM IBA for 10 min. In vitro- and ex vitro-rooted plants were successfully acclimatized and established in greenhouse conditions.

Micropropagation of pitaya (Hylocereus undatus britton et rose)

Abstract: A procedure for micropropagation of pitaya using thidiazuron (TDZ) and naphthaleneacetic acid (NAA) is described. Explants were excised from young joints of mature plants and cultured on Murashige and Skoog medium (MS) containing 0.5 μM NAA and 0.5 μM TDZ. Shoots produced from these first explants were cut up to produce secondary explants, either by decapitation or by longitudinal division into three parts. The decapitated and longitudinal explants were cultured on MS supplemented with 0.5 μM NAA and either 0.01, 0.09, 0.5, or 0.9 μM TDZ. Decapitated explants produced more shoots at higher frequency that the longitudinal explants. For both types of secondary explants, most shoots were developed from the distal parts. Shoots produced from secondary explants were rooted in MS and then transferred to soil where they produced normal plants.

High polyphenol oxidase activity and low titratable acidity in browning bamboo tissue culture

Abstract: Tissue browning that frequently results in the early death of bamboo shoots in vitro correlated directly with polyphenol oxidase (PPO, EC 1.10.3.1) activity and inversely with titratable acidity. It was unrelated to the level of endogenous phenols. During the course of culture, timing of PPO activity paralleled that of explant browning. Browning was highest among shoots cultured in a medium of pH 8, which was consistent with the pH optinum of the bamboo enzyme. The pH optimum was first determined with the crude enzyme, then verified with two purified isozymes. Stability of the bamboo PPO was also highest at pH 10. PPO activities of the severely browning Dendrocalamus latiflorus, the moderately browning Phyllostachys nigra, and the relatively non-browning Bambusa oldhamii were inhibited strongly by ascorbic acid, cysteine, sodium diethyldithiocarbamate, and sodium sulfite. But characterization of bamboo PPO according to enzyme inhibitors was not possible because enzyme extracts of the three species gave varied responses to the traditional substances. Nutrient medium addenda of some PPO inhibitors, namely ascorbic acid, cysteine, kojic acid, and thiourea, mainly enhanced browning. However, ferulic acid at 3 mM and lower concentrations reduced the number of brown shoots per culture, although not the percentage of cultures that browned. Polyvinylpyrrolidone failed completely to suppress browning. The two purified isozymes showed different temperature optima for PPO activity: 60°C and 65°C. The purified isozymes displayed a substrate preference for dopamine, or a cathecol oxidase characteristics.

Efficient production of protocorm-like bodies and plant regeneration from flower stalk explants of the sympodial orchid Epidendrum radicans

Abstract: A simple and efficient micropropagation method was established for direct protocorm-like body (PLB) formation and plant regeneration from flower stalk internodes of a sympodial orchid, Epidendrum radicans. Small transparent tissues formed on surfaces and cut ends of flower stalk internodes on a modified half-strength Murashige and Skoog basal medium with or without thidiazuron (TDZ) after 1–2 wk of culture. In the light, the transparent tissues enlarged and turned into organized calluses on most of the explants. However, PLBs formed only on a medium supplemened with 0.45 μM TDZ within 2 mo. of culture. Sucrose, NH4NO3, and KNO3 were used in media to test their effects on PLB proliferation and shooting. The best response on number of PLBs per tube was 23.6 at 40 gl−1 sucrose, 825 mgl−1 NH4NO3, and 950 mgl−1 KNO3, and the highest number of PLBs with shoots was found at 10 gl−1 sucrose, 825 mgl−1 NH4NO3, and 950 mgl−1 KNO3. Homogenized PLB tissues produced by blending were used to test the effects of four cytokinins [TDZ, N6-benzyladenine (BA), zeatin-riboside, and kinetin] on PLB proliferation and shoot formation. The best responses on number of PLBs per tube, proliferation rate, and number of PLBs with shoots per tube were obtained at 4.44 μM BA, 0.28 μM zeatin-riboside, and 1.39 μM kinetin, respectively. Normal plantlets converted from PLBs on the same TDZ-containing medium after 1 mo. of culture. The optimized procedure required about 12–13 wk from the initiation of PLBs to plantlet formation. The regenerated plants grew well with an almost 100% survival rate when acclimatized in a greenhouse.

The mevalonate-independent pathway is expressed in transformed roots of Artemisia annua and regulated by light and culture age

Abstract: Artemisia annua produces a large number of unique terpenoids, making it of particular interest as a source of phytochemicals and a useful model plant for studying terpenoid metabolism. The ability to engineer fast-growing in vitro cultures to produce terpenoids in high yield would be a dramatic step towards commercial use. Two distinct pathways have been characterized in higher plants leading to the biosynthesis of isopentenyl diphosphate, the common precursor to all terpenes: the cytosolic mevalonate pathway and the plastid-localized mevalonate-independent pathway. While transformed roots of A. annua have been demonstrated to be superior to whole plants in terms of yield of the sesquiterpene artemisinin, they appear to lack functional chloroplasts, bringing into question the presence of a functional mevalonate-independent pathway. Using a cDNA library made from these roots, we isolated two clones encoding deoxy-d-xylulose-5-phosphate synthase (DXPS) and deoxy-d-xylulose-5-phosphate reductoisomerase (DXPR). The biochemical function of both enzymes was confirmed by complementing E. coli dxps- and dxpr-mutants. Northern blot analysis showed that the transformed root cultures expressed these genes at different levels during the culture cycle. In addition, cultures grown in continuous light showed substantial increases in DXPS transcript levels compared to dark-grown cultures. These results represent an important step towards demonstrating the presence of the plastid-localized terpenoid biosynthetic pathway in these easily engineered in vitro cultures.

Production of fertile transgenic lentil ( Lens culinaris Medik) plants using particle bombardment

Abstract: A reproducible system for gene transfer in lentil through particle bombardment is presented. Lentil cotyledonary nodes excised from germinated seedlings were bombarded with a plasmid containing a mutant acetolactate synthase gene (ALS) from tobacco conferring resistance to sulfonylurea herbicides. Putative transgenic shoots regenerated on Murashige and Skoog medium supplemented with 6-benzylaminopurine (BA) and chlorsulfuron (5 nM for first 4 wk followed by 2.5 nM for the remainder of the culture period) were micrografted and successfully transferred to soil. T0 and selfed progeny plants were screened using metsulfuron herbicide leaflet painting. The non-transformed escapes died and transformed plants survived the test. The surviving plants were phenotypically normal and produced viable seeds. The presence and stable transmission of the transgene into genomic DNA of screened T1 transformants was confirmed by PCR and Southern hybridization. This method for producing transformed plants will allow new opportunities for lentil breeding to produce improved cultivars.

Positive selectable marker genes for routine plant transformation

Abstract: Plant genetic transformation technologies rely upon the selection and recovery of transformed cells. Selectable marker genes used so far have been either antibiotic resistance genes or herbicide tolerance genes. There is a need to apply alternative principles of selection, as more transgenic traits have to be incorporated into a transgenic crop and because of concern that the use of conventional marker genes may pose a threat to humans and the environment. New classes of marker genes are now available, conferring metabolic advantage of the transgenic cells over the non-transformed cells. The new selection systems, as described in this review, are being used with success and superior performance over the traditional marker systems.

Recent advances in wheat transformation

Abstract: Since the first report of wheat transformation in the early 1990s, genetic engineering of wheat has evolved rapidly. Several laboratories worldwide have reported the production of fertile transgenic wheat plants using a variety of methods. While there are several innovative and promising approaches for wheat transformation using different explants as targets for transformation, different methods of transformation, and different selection schemes, the most common approach to wheat transformation is the bombardment of tissue derived from immature embryos followed by selection based on resistance to the bar gene. Even with all these successful reports, hurdles still exist for this recalcitrant crop. Of these hurdles, low transformation rates, tools for transgene expression, and transgene silencing in subsequent generations are probably the most critical. This review will provide an overview of wheat transformation in the past decade, addressing both positive and negative factors that effect transformation while highlighting the successes of the past and prospects for the future.

Somatic embryogenesis in leaf callus from a mature Quercus suber L. Tree

Abstract: Somatic embryos were obtained from a 60-yr-old Quercus suber L. tree. Leaf explants were cultivated on Murashige and Skoog medium with 30 gl−1 sucrose, 3 gl−1 gelrite, pH adjusted to 5.8, and different growth regulator combinations. Callus induction took place at 24±1°C in the dark during the first 3 wk. After 3 mo, calluses that showed embryogenic structures were transferred to the same medium without growth regulators. Somatic embryogenesis was only observed in calluses induced on E3 medium (supplemented with 4.5 μM 2,4-dichlorophenoxyacetic acid and 9.0 μM zeatin). On average, 7.5% of the initial explants formed embryogenic calluses in this medium. Somatic embryo proliferation was high due to secondary embryogenesis. On average, 10% of the somatic embryos germinated and 40% of these germinated embryos converted into plants. Plants were elongated on the same medium without growth regulators and acclimated to greenhouse conditions.

Factors affecting growth of cell suspension cultures of hypericum perforatum L. (St. John's wort) and production of hypericin

Abstract: Use of Hypericum perforatum L., commonly known as St. John's wort, has increased recently due to the pharmaceutical potential of hypericin, found in its leaves. Hypericin has been reported to effect a natural treatment for mild and moderate depression by increasing the concentration of neurotransmitters in the central nervous system. We have developed a novel cell culture system for in vitro growth and production of this species, suggesting a possible technology for large-scale production of hypericin. Leaf explants grown in Murashige and Skoog salts supplemented with 2,4-dichlorophenoxyacetic acid (0.90 μM) and kinetin (0.11 μM) gave maximum percentage callus formation compared to other medium treatments evaluated. Hypericin localization in cell phase and leaves was found to vary, with cell phase accumulating hypericin in special organelles and leaves accumulating it in vacuoles. Light and dark conditions, with cell aggregate size, played important roles in growth and hypericin production in cell suspension cultures.

Evaluation of genetic stability in cryopreserved prunus

Abstract: The evaluation of the genetic stability of Prunus Ferlenain plants regenerated from cryopreserved apices was investigated. The analysis of plants recovered from frozen material was performed at the phenotypic (developmental competence), cytological (chromosomal preparations) and molecular level [random amplified polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP)]. No genetic change was detected among the plantlets regenerated from frozen apices in comparison to the non-frozen material, including leaves of the mother tree kept in an orchard and vitroplantlets regenerated from non-frozen apices. This result suggested that the procedure used for Prunus cryopreservation could be used for long-term conservation. The relevance of each strategy for the genetic stability evaluation of the cryopreserved material is discussed.

In vitro propagation of Pelecyphora aselliformis Ehrenberg and P. strobiliformis Werdermann (cactaceae)

Abstract: Development of efficient in vitro propagation, systems for Pelecyphora aselliformis Ehrenberg and P. strobiliformis Werdermann, two endangered Mexican species of cacti, are described. Multiple shoot formation from areoles of in vitro-germinated plantlets was achived in two types of explants (apical and transversal) cultured in Murashige and Skoog (MS) basal media supplemented with 30 or 50 gl−1 sucrose, 10 gl−1 agar and various treatments with cytokins. Shoot production in these proliferation media was evaluated after one (60 d) and three (180 d) culture cycles. In P. asellifornis 13.7 shoots per explant were produced after the first cycle using apical explants in medium with 8.8 μM 6-benzylaminopurine (BA) and 30 gl−1 sucrose. In P. strobiliformis the highest proliferation rate (12.4 shoots per explant) was reached using 8.8 μM Ba and 50 gl−1 sucrose with shoot transverse segments as explants. After the third proliferation cycle, 128.1 and 136.3 shoots per explant were obtained in P. aselliformis and P. strobiliformis, respectively. The shoots were clongated in MS basal medium with 3 gl−1 activated charcoal and rooted in MS basal media indoleacetic acid (2.85 or 5.71 μM) or indolebutyric acid (2.46 or 4.90 μM). On averge, rooting efficiency was 89% for P. aselliformis and 87% for P. strobiliformis. The survival frequency, of the plants once transferred, to soil was on average 88%.