Production of Agrobacterium-mediated transgenic fertile plants by direct somatic embryogenesis from immature zygotic embryos of Datura innoxia

This work describes a new method to obtain transgenic somatic embryos from Agrobacterium-infected immature zygotic embryos of Datura innoxia. It has several advantages over previous transformation methods such as the absence of a callus phase, an average transformation rate of 76% and a high regeneration frequency. Critical steps for optimal transformation were the embryo stage and a short preculture treatment. The marker gene beta-glucuronidase and light microscopy were used to identify the competent embryogenic cells which, after transformation, passed through the classical stages of embryo development. The transgenes were transmitted to the progeny in a Mendelian fashion. The plants regenerated via direct somatic embryogenesis were cytologically and morphologically uniform. We also observed that: (1) wounding or wound-induced divisions were not required for zygotic embryo transformation; (2) epidermal cells were competent for both transformation and regeneration; and (3) competency for Agrobacterium infection was developmental stage-specific. This new method should facilitate the development of new strategies to routinely transform recalcitrant plant species.

Effect of drought stress on growth and essential oil metabolism in lemongrasses

Two lemongrasses. Cymbopogon nardus. (L.) Rendle var. confertiflorus (Steud.) Bor. and Cymbopogon pendulus (Steud.) Wats, were grown under mild and moderate water stress for 45 and 90 d. The impact of in situ drought stress on plants in terms of relative water content, $pS, concentration of proline, activities of PEP carboxylase and geraniol dehydrogenase, and geraniol and citral biogenesis, were investigated. The results revealed that the specific exhibited differential responses under mild and moderate stress treatments. In general, plant growth was reduced considerably whilst the level of essential oils was maintained or enhanced. Significant induction in catalytic activity of PKP carboxylase under water stress was one of the consistent metabolic responses of the aromatic grasses. The major oil constituents., geraniol and citral, increased substantially in both the species. Activity of geraniol dehydrogenase was also modulated under moisture stress. The responses varied depending Upon the level and duration of moisture stress. The observations have been analyzed in terms of possible relevance of some of these responses to their drought stress adaptability tolerance.

Factors influencing T-DNA transfer in Agrobacterium-mediated transformation of sugarbeet

Agrobacterium-mediated transformation of sugarbeet (Beta vulgaris L.) was investigated for T-DNA transfer efficiency, using an intron containing β-glucuronidase gene. Preculture and coculture of hypocotyl and cotyledon explants with acetosyringone upon infection was studied. Seven seed lots which included several hundred genotypes, were screened, and were all susceptible to T-DNA transfer but with variable frequencies. Cotyledon explants were more readily transformed than those from hypocotyls. Transformation frequency of hypocotyl explants increased with acetosyringone. Both preculture treatment and acetosyringone improved transformation in cotyledon explants. Callus assayed with fluorometric procedures confirmed that the GUS gene had been transferred into sugarbeet.

Geraniol dehydrogenase: a determinant of essential oil quality in lemongrass1

Geraniol dehydrogenase, the specific enzyme involved in geraniol to citral TRANS (geranial) transformation, activity was monitored in various lemongrass cultivars differing in amounts and relative percentages of citral and geraniol in their essential oils. The enzyme activity had a positive and significant association with citral to geraniol, and geranial to geraniol ratios. The results are suggestive of a strong relationship between the enzyme activity and essential oil quality in lemongrass cultivars.

Normal growth of transgenic tobacco plants in the absence of cytosolic pyruvate kinase

The coding sequence of the cytosolic isozyme of potato tuber pyruvate kinase (PK) was attached to the transit peptide of the small subunit of pea ribulose-1,5-bisphosphate carboxylase oxygenase and placed under the control of the cauliflower mosaic virus 35S promoter. This construct was transformed into Nicotiana tabacum. Unexpectedly, two primary transformants were recovered in which PK activity in leaves was greatly reduced. The reduction in PK activity appeared to result from the complete absence of the cytosolic form of the enzyme (PK(c)). In addition, no PK(c) could be detected on western blots of leaf extracts. Metabolite analyses indicated that the levels of phosphoenolpyruvate are substantially higher in PK(c)-deficient leaves than in wild-type leaves, consistent with a block in glycolysis at the step catalyzed by PK. PK(c) deficiency in the leaves does not appear to adversely affect plant growth. Analysis of progeny indicates that PK(c) deficiency is a heritable trait. The leaves of PK(c)-deficient transformants have normal rates of photosynthetic O(2) evolution and respiratory O(2) consumption, indicating that these plants are using alternative pathways to bypass PK.

Characterization of competent cells and early events of Agrobacterium-mediated genetic transformation in Arabidopsis thaliana

The insertion of foreign DNA in plants occurs through a complex interaction between Agrobacteria and host plant cells. The marker gene β-glucuronidase of Escherichia coli and cytological methods were used to characterize competent cells for Agrobacterium-mediated transformation, to study early cellular events of transformation, and to identify the potential host-cell barriers that limit transformation in Arabidopsis thaliana L. Heynh. In cotyledon and leaf explants, competent cells were mesophyll cells that were dedifferentiating, a process induced by wounding and-or phytohormones. The cells were located either at the cut surface or within the explant after phytohormone pretreatment. In root explants, competent cells were present in dedifferentiating pericycle, and were produced only after phytohormone pretreatment. Irrespective of their origin, the competent cells were small, isodiametric with thin primary cell walls, small and multiple vacuoles, prominent nuclei and dense cytoplasm. In both cotyledon and root explants, histological enumeration and β-glucuronidase assays showed that the number of putatively competent cells was increased by preculture treatment, indicating that cell activation and cell division following wounding were insufficient for transformation without phytohormone treatment. Exposure of explants for 48 h to A. tumefaciens produced no characteristic stress response nor any gradual loss of viability nor cell death. However, in the competent cell, association between the polysaccharide of the host cell wall and that of the bacterial filament was frequently observed, indicating that transformation required polysaccharide-to-polysaccharide contact. Flow cytofluorometry and histological analysis showed that abundant transformation required not only cell activation (an early state exhibiting an increase in nuclear protein) but also cell proliferation (which in cotyledon tissue occurred at many ploidy levels). Noncompetent cells could be made competent with the appropriate phytohormone treatments before bacterial infection: this should aid analysis of critical steps in transformation procedures and should facilitate developing new strategies to transform recalcitrant plants.

Plant regeneration from sugarbeet (Beta vulgaris L.) hypocotyls cultured in vitro and flow cytometric nuclear DNA analysis of regenerants

A simple and reproducible protocol for regeneration of sugarbeet plants from hypocotyl expiants derived from 21 day-old-seedlings has been developed. Expiants were cultured on MS medium containing 0.3 mg/l N6-Benzylaminopurine, 0.1 mg/l Naphthalene Acetic Acid, 50 mg/l adenine and 0.5% (w/v) fructose, 0.5% (w/v) sucrose and 0.5% (w/v) glucose to induce the formation of organogenic calli (2.3% to 46.5% organogenic efficiency, depending on populations). Shoot formation was induced in callus cultures of more than 1600 genotypes. Physiological age affected culture response and different genotypes had different temperature optima for organogenesis. Following transfer of regenerated plants to the greenhouse, DNA determinations were made to study the stability of ploidy. Differences in ploidy were observed in plants derived from both shortterm and long-term callus cultures; diploid true-to-type regenerants were 96% and 83%, respectively, from shortterm and long-term callus cultures.

Phosphoenolpyruvate carboxylase activity and concentration in the endosperm of developing and germinating castor oil seeds

Monospecific polyclonal antibodies against maize leaf phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31) were utilized to examine the subunit composition and developmental profile of endosperm PEPC in developing and germinating castor oil seeds (Ricinus communis L. cv Baker 296). PEPC from developing endosperm consists of a single type of 100-kilodalton subunit, whereas the enzyme from 2- to 5-day germinated endosperm appears to contain equal proportions of immunologically related 103- and 108-kilodalton subunits. The maximal activity of PEPC in developing endosperms (2.67 micromoles oxaloacetate produced per minute per gram fresh weight) is approximately 20-fold and threefold greater than that of fully mature (dry seed) and germinating endosperms, respectively. The most significant increase in the activity and concentration of endosperm PEPC occurs during the middle cotyledon to full cotyledon stage of seed development; this period coincides with the most active phase of storage oil accumulation by ripening castor oil seeds. The data are compatible with the recent proposal (RG Smith, DA Gauthier, DT Dennis, DH Turpin [1992] Plant Physiol 1233-1238) that PEPC plays a fundamental role in vivo in the cytosolic production of an important substrate (malate) for fatty acid biosynthesis by developing castor oil seed leucoplasts. Immediately following seed imbibition, PEPC activity and concentration increase in parallel, with the greatest levels attained by the third day of germination. It is suggested that during this early phase of seed germination PEPC has a critical function to build up cellular dicarboxylic acid pools required to initiate significant activities of both the tricarboxylic acid and glyoxylate cycles.

Pyruvate-kinase isoenzymes from zygotic and microspore-derived embryos of Brassica napus : Developmental profiles and subunit composition

Polyclonal antibodies against castor-oil seed cytosolic and leucoplastic pyruvate kinases (PKc and PKp, respectively; EC 2.7.1.40) were utilized to examine the subunit compositions and developmental profiles of canola (Brassica napus L. cv. Topas) PKc and PKp over 6 d of seed germination and 35 d of culture of microspore-derived embryos. The PKc from germinating seeds appears to be composed of a single type of 56-kDa subunit, whereas the enzyme from cultured embryos contains equal proportions of immunologically related 57- and 56-kDa subunits. The PKp was immunologically undetectable in germinating seeds, while the enzyme from cultured embryos consisted of immunologically related 64- and 58-kDa subunits in a ratio of about 1∶2, respectively. The large increase in PK activity that occurs between the second and fourth days of seed gemination is based upon de-novo synthesis of PKc. Between 7 and 14 d of culture of microspore-derived embryos, the levels of PKp and PK maximal activity increased approx. 3- and 2.5-fold, respectively. These increases were coincident with an approximately fourfold rise in the in-vivo pyruvate: phosphoenolpyruvate concentration ratio. Conversely, PKc was not only far less abundant relative to PKp, but its level remained constant over 35 d of microspore-embryo culture. Developing non-zygotic (microspore-derived) embryos strongly resembled ripening zygotic (seed) embryos in terms of PK specific activity as well as relative amounts and subunit compositions of PKc and PKp. The results indicate that the synthesis of PK isoenzymes in B. napus seeds is highly regulated and that this regulation follows a preset developmental program.

Genetic transformation of Arabidopsis thaliana zygotic embryos and identification of critical parameters influencing transformation efficiency

An efficient procedure for Agrobacterium-mediated transformation of zygotic embryos derived from three different Arabidopsis thaliana ecotypes has been developed. This procedure yielded an average transformation rate of 76% for ecotype C24, and 15-20% for ecotypes Landsberg-erecta and Columbia. A critical step for optimal transformation was the preculture of embryos on a phytohormone-containing medium. Light and electron microscopical studies showed that, during preculture, procambium cells of embryos became highly susceptible to Agrobacterium infection. Transformed cells developed calli and regenerated shoots within 4-5 weeks of culture. A total of 1500 fertile transgenic plants were regenerated. In regenerated plants the presence of inserted DNA was verified by genomic Southern blot analysis, assays of enzymatic activities of reporter genes (neomycin phosphotransferase II and beta-glucuronidase) as well as by genetic segregation tests. R1 progenies of 45 randomly chosen transformed lines and 150 independent regenerants did not show any somaclonal variations as ascertained by both morphological and cytological criteria. Short duration (7-8 weeks), high efficiency, reproducibility and low frequency of somaclonal variation makes the zygotic embryo transformation particularly well-suited for T-DNA tagging mutagenesis.

Effect of culture conditions on Agrobacterium-mediated transformation in datura

A two step selection procedure is described for high frequency transformation and regeneration of transgenic plants by coculture of leaf discs of Datura innoxia with Agrobacterium tumefaciens carrying binary vectors. Leaf discs were cocultured with disarmed A. tumefaciens vectors pGS Glucl, pGSTRN943, pGV2260 and pBI121, and subcultured on regeneration media containing kanamycin. Kanamycinresistant, putatively "transformed" callus and vegetative buds were isolated, and subcultured on media containing reduced amounts of growth regulators and kanamycin to induce shooting. Rooted shoots produced normal fertile plants. Transformation frequency was related to duration of preculture, co-culture, and the bacterial strain used. With pGS Glue 1, a 3 day co-culture resulted in 70% of leaf discs being transformed. Transformation was confirmed by histochemical test for GUS activity, by the ability of leaf discs to initiate callus and from NPTII test, and Southern blot analysis. Progeny of the transgenic plants showed Mendelian segregation for kanamycin resistance.

Direct organogenesis from internodal segments of in vitro grown shoots of apple cv. Golden delicious

A protocol for direct organogenesis from internodal segments of in vitro grown shoots obtained from mature apple cv. Golden delicious trees is presented. Adventitious buds were initiated on Murashige and Skoog medium (1962) containing various combinations of benzylaminopurine (BAP) and 2,3,5-triiodobenzoic acid (TIBA). Low concentration of BAP (4.4 μM) in combination with TIBA (1 μM) gave the best percentage of regeneration. Three repeated cycles of culture and regeneration produced an increase of adventitious budding up to 23%. Although no auxin was used in the organogenic medium, callus was always obtained. The regenerated shoots were micropropagated and rooted. Cytological studies revealed that proliferating buds originated directly from the superficial layers of the internodal explants without an intermediate callus phase.

Characterization of amyloplastic phosphohexose isomerase from immature wheat (Triticum aestivum L.) endosperm

Phosphohexose isomerase from amyloplasts of immature wheat endosperm was purified 133-fold. The enzyme had a molecular weight of 130 kDa and maximum activity at pH 8.6. It showed normal hyperbolic kinetics for both fructose-6-P and glucose-6-P with Km of 0.12 mM and 0.44 mM, respectively. pH had a great influence on Km for fructose-6-P. Using glucose-6-P as the substrate, the equilibrium was reached at 23% fructose-6-P and 77% glucose-6-P and an equilibrium constant of about 3.0. The delta F calculated from the apparent equilibrium constant was +742 cal.mol-1. The activation energy calculated from the Arrhenius plot was 7450 cal.mol-1. None of the sulphydryl reagents at 2.5 mM concentration inactivated the enzyme. The enzyme was competitively inhibited by 6-phosphogluconate, ribose-5-P and ribulose-5-P with Ki values of 0.18, 0.14, and 0.13 mM, respectively. The probable role of the enzyme in starch biosynthesis in amyloplasts is discussed.

Effect of Leaf Position and Age on the Essential Oil Quantity and Quality in Lemongrass (Cymbopogon flexuosus)1

The amount and composition of the essential oil of CYMBOPOGON FLEXUOSUS (lemongrass) leaves at different positions in the tiller and at different developmental stages were investigated. The results showed that only young leaves are biogenetically active, and that the leafage and leaf position are important factors for the amount and composition of the essential oil. The results obtained also indicated possible interconversions of the essential oil constituents IN VIVO.

Phenotypic and karyotypic status of Beta vulgaris plants regenerated from direct organogenesis in petiole culture

A method for high frequency in vitro regeneration from petiole explants was tested on nine breeding lines of Beta vulgaris L. from the haploid, diploid and tetraploid levels. Regenerants could be obtained without a callus step, from excised petioles derived either from axillary buds sprouted in vitro or from field grown plants, by plating the explants on MS medium supplemented with TIBA (2,3,5-triiodobenzoïc acid) and BAP (6-Benzylaminopurine). The multiple shoots obtained were then rooted in vitro and transferred to soil. In some cases, these adventitious shoots were also used as a petiole explant source for further petiole culture cycles, and the phenotypic characteristics and ploidy status of the regenerants were investigated after one or three petiole culture cycles. Conventional shoot apex culture was used as an in vitro control. Phenotypic variations such as differences in morphology and changes in in vitro growth behaviour, were noticed. Chloroplast and chromosome counts indicated that the alterations in morphogenetic pathway could not be explained by the occurrence of gross cytogenetic abnormalities such as aneuploidy or myxoploidy. Our results suggest that the altered morphology is caused by the presence of the exogenous antiauxin (TIBA) during the in vitro phase. Following transfer to the greenhouse, none of these variations persisted and cytogenetic analyses revealed karyotypic stability in all the plants studied, even after three petiole culture cycles. An assessment of the in vitro petiole culture method as a true-to-type multiplication method for Beta vulgaris is made.

Variations in the Leaf Alkaloid Content of Androgenic Diploid Plants of Datura innoxia

Anther culture of DATURA INNOXIA Mill, has permitted the obtention of spontaneous diploid androgenic plants which produced the tropane alkaloids. The source plants (zygotic diploid) showed no significant variations in the leaf alkaloid content. On the contrary, androgenic diploid plants obtained after the first cycle of androgenesis showed important quantitative and qualitative variations in the leaf alkaloid content. Thus, androgenesis was found to induce a large variation in the accumulation of these secondary metabolites in the leaves. It has also permitted the obtention of tropane alkaloid-overproductive plants, particularly rich in scopolamine. The analyses of zygotic plants obtained from seed germination of the first cycle androgenic plants have shown that this variability is transmissible by simple cross-pollination. The analyses of androgenic diploid plants obtained after the second cycle of androgenesis also showed variations in the leaf alkaloid content. IN VITRO androgenesis, therefore, clearly induced variability in the leaf alkaloid content of the androgenic plants. The role of IN VITRO androgenesis in inducing variability has been discussed.

The tonoplast, a specific marker of embryogenic microspores of Datura cultured in vitro

Microspores of Datura metel L. have a thin tonoplast which, upon culture in vitro, develops a more or less uniform coating or deposit (as early as 12 h). This response was specific for embryogenic microspores, thereby making it possible to distinguish them from the nonembryogenic microspores. Cytochemical tests indicated the presence of tannins in this deposit which persists only until the early globular stage of embryogenesis. Thus tannin-coated tonoplasts can be used as a reliable and specific cytological marker for microspores following the embryogenic pathway in vitro.

Change in the amino-acid content during male gametophyte formation of Datura metel in Situ

Determination of the free and bound aminoacids during microsporogenesis of Datura metel showed that the principal amino-acids were proline, glutamic acid, aspartic acid, threonine-serine and alanine. Of these, only proline showed a consistent increment during pollen development. In contrast, aspartic acid and lysine decreased in the later stages of microsporogenesis. The amounts of other amino-acids did not show any consistent pattern. Four amino-acids, namely proline, glutamic acid and threonine-serine constituted nearly 85% of the free amino-acid pool in the developed anther (stage IV). Proline accumulation, relative to the total free amino-acid pool in mature anthers, was correlated with the water-content. The results were discussed in view of possible relationships between metabolic activity and free and bound amino-acid concentrations.