Differentiation of isolated wheat zygotes into embryos and normal plants

Efficient and reproducible embryo development has been obtained from fertilized wheat (Triticum aestivum L.) egg cells isolated 3–6 h after hand-pollination of emasculated spikes. It is possible to routinely isolate viable zygotes from about 75% of the excised ovaries from cultivars of both winter and spring types. Co-culture with barley microspores which had been stimulated to sporophytic development resulted in embryonic development of the cultivated wheat zygotes. Within 23 h of pollination; the zygotes underwent their first cell division. They proceeded to develop into club-shaped embryos, most of which turned subsequently to dorsiventral differentiation. The morphological patterns of in-vitro-grown embryos were in accordance with those of normal zygotic embryos growing in planta. The formation of twin or multiple embryos originating from a single zygote was dependent on genotype and exogeneously supplied auxin. Upon transfer onto a suitable solidified medium, zygote-derived embryos usually germinated and developed into plants. After optimizing the feeder system, the nutrient medium and the concentration of 2,4-dichloro phenoxyacetic acid (2,4-D), more than 80 and 90% of the zygotes eventually developed into plants in genotypes Florida and Veery #5, respectively. All regenerated plants were morphologically normal and fertile. The in-vitro development from isolated zygotes of a higher-plant species into typically patterned zygotic embryos is shown here for the first time. Since the entire process, including early zygotic development, is now freely accessible to observation and micromanipulation, the method presented opens up new approaches in fundamental as well as applied fields of reproductive biology. Received: 4 September 1997 / Accepted: 28 November 1997     

Morphological characterisation of wheat (T. aestivum L.) egg cell protoplasts isolated from immature and overaged caryopses

 The morphological features and fine structure of wheat egg cell protoplasts isolated from premature (3 days prior to anthesis) and overaged (12 days after anthesis) caryopses were compared. Except for shape, the young egg cell protoplast showed the same morphological characteristics as the egg cell in planta at the time of anthesis. Young and adult egg cell protoplasts were spherical in shape. Polarity could not be identified exactly with the methods used. During aging, the egg cell increased considerably in volume. The adult egg showed the typical features (membrane blebbing, autophagous vacuoles) of programmed cell death. It appears that after a long life-span (about18 days) cells of the female gametophyte undergo apoptosis. Received: 19 August 1998 / Revision accepted 2 November 1998     

Fertilization-induced changes in the microtubular architecture of the maize egg cell and zygote—an immunocytochemical approach adapted to single cells

By using single cell micromanipulation techniques, we developed an immunocytochemical procedure to examine subcellular protein localization in isolated and cultured cells. Localization of microtubules was examined in isolated single egg cells and developing zygotes of maize with anti--tubulin antibodies. In egg cells, a few cortical microtubules were detected but well organized microtubules were rarely observed. In contrast, distinct cortical microtubules and strands of cytoplasmic microtubules radiating from the nucleus to the cell periphery were observed in developing zygotes. Solely cortical microtubules were observed in zygotes up to 7 h after in vitro fertilization. After this time, radiating microtubules additionally appeared, and persisted during zygote development. These results indicate early and pronounced fertilization-induced changes in microtubular organization in the fertilized egg cell of maize.     

Stably transformed callus of wheat by electroporation-induced direct gene transfer

Fertile plants of wheat have been regenerated from protoplasts in several laboratories. The objective of this study was to develop a transformation system using protoplasts as target cells. Protoplasts were isolated from cell suspensions initiated from an anther-derived callus. The protoplasts were transformed by electroporation using pBARGUS or pBAS, both carrying the Basta resistance (BAR) gene. A total of 2,761 calli were produced from electroporation transformed protoplasts in 3 independent experiments. Six calli survived selective culture on 10 mg/l phosphinothricin (PPT), a concentration that completely inhibited the growth of non-transformed wheat callus. Five PPT resistant calli showed phosphinothricin acetyltransferase (PAT) activity, whereas the sixth probably was a mutant. The transformed wheat calli could tolerate PPT concentrations up to 2,560 mg/l. Southern blot analyses confirmed the integration of the BAR gene in wheat genomes. The integrated DNA sequence may have partially methylated and tandemly repeated at least once. These results demonstrate the production of stably transformed wheat calli by electroporation-mediated direct gene transfer into protoplasts.     

Decomposition and nitrogen dynamics of wheat residues and impact on wheat growth stages

N mineralisation and immobilisation were quantified in field conditions in the presence or in the absence of wheat residues. The incubation study was conducted in cylinders placed in microplots (no plants were grown in cylinders), and the rest of each microplot was sowed with the wheat crop (Triticum durum var. Massa). N mineralisation and immobilisation depend on the presence or the absence of wheat residues. In absence of residues, a linear model of regression was developed to follow the clear nitrogen mineralisation at different soil levels. Nitrogen mineralisation (mg kg-1), during the five months of wheat development, showed the following decreasing order: 0-15 cm (132.6) > 15-30 cm (120.6) > 30-45 cm (91.3). The mineralisation rate was 24.1, 22.9 and 18.9 mg kg-1 d-1 for 0-15, 15-30 and 30-45 cm levels, respectively. The supply of wheat residues resulted in a five months N immobilisation process. At level 0-15 cm the immobilisation (mg kg-1) showed the following decreasing order: (61.6) > (46.4) > (30.0) for the supply of wheat residues at seeding time, and 15 and 30 d before seeding respectively. At the other levels, the same decreasing order was recorded. The supply of 8 t ha-1 of wheat residues at seeding time, and 15 or 30 d before seeding, decreased the dry matter yield and N accumulation in wheat crop. In consequence, there was no synchronism between the nitrogen liberated by wheat residues decomposition and the wheat growth.     

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.     

Regeneration of Fertile Barley Plants from Mechanically Isolated Protoplasts of the Fertilized Egg Cell

A simple procedure is described for the mechanical isolation of protoplasts of unfertilized and fertilized barley egg cells from dissected ovules. Viable protoplasts were isolated from ~75% of the dissected ovules. Unfertilized protoplasts did not divide, whereas almost all fertilized protoplasts developed into microcalli. These degenerated when grown in medium only. When cocultivated with barley microspores undergoing microspore embryogenesis, the protoplasts of the fertilized egg cells developed into embryo-like structures that gave rise to fully fertile plants. On average, 75% of cocultivated protoplasts of fertilized egg cells developed into embryo-like structures. Fully fertile plants were regenerated from ~50% of the embryo-like structures. The isolation-regeneration techniques may be largely genotype independent, because similar frequencies were obtained in two different barley varieties with very different performance in anther and microspore culture. Protoplasts of unfertilized and fertilized eggs of wheat were isolated by the same procedure, and a fully fertile wheat plant was regenerated by cocultivation with barley microspores.     

Tobacco zygotic embryogenesis in vitro: the original cell wall of the zygote is essential for maintenance of cell polarity, the apical-basal axis and typical suspensor formation

We have developed a reliable in vitro zygotic embryogenesis system in tobacco. A single zygote of a dicotyledonous plant was able to develop into a fertile plant via direct embryogenesis with the aid of a co-culture system in which fertilized ovules were employed as feeders. The results confirmed that a tobacco zygote could divide in vitro following the basic embryogenic pattern of the Solanad type. The zygote cell wall and directional expansion are two critical points in maintaining apical-basal polarity and determining the developmental fate of the zygote. Only those isolated zygotes with an almost intact original cell wall could continue limited directional expansion in vitro, and only these directionally expanded zygotes could divide into typical apical and basal cells and finally develop into a typical embryo with a suspensor. In contrast, isolated zygote protoplasts deprived of cell walls could enlarge but could not directionally elongate, as in vivo zygotes do before cell division, even when the cell wall was regenerated during in vitro culture. The zygote protoplasts could also undergo asymmetrical division to form one smaller and one larger daughter cell, which could develop into an embryonic callus or a globular embryo without a suspensor. Even cell walls that hung loosely around the protoplasts appeared to function, and were closely correlated with the orientation of the first zygotic division and the apical-basal axis, further indicating the essential role of the original zygotic cell wall in maintaining apical-basal polarity and cell-division orientation, as well as subsequent cell differentiation during early embryo development in vitro.     

Fluorophore-conjugated lectin labeling of the cell surface of isolated male and female gametes,central cells and synergids before and after fertilization in maize

Three fluorescein isothiocyanate (FITC)-conjugated lectins, Canavalia ensiformis agglutinin (Con A), Triticum vulgaris agglutinin (WGA) and Phaseolus vulgaris erythroagglutinin (PHA-E), were used as probes to localize sugar moieties of glycoconjugates on the cell surface of isolated maize sperm, egg, central, antipodal cells, synergids, and in vitro- and in vivo-fertilized zygotes. Fluorescence signals on the surface of the cells were due to specific binding. Calcium was necessary for WGA and PHA-E binding and enhanced Con A labeling. Differences in glycoconjugate composition of the membranes of gametes and other embryo sac component cells were found. FITC-Con A strongly labeled egg and central cells, but labeled sperm only weakly. FITC-WGA binding sites were detected on egg, but not sperm cells. Con A and WGA binding sites were equally distributed around egg and central cell protoplasts. FITC-PHA-E binding sites were not found on sperm and egg cells before fertilization. Binding sites of these lectins were located on synergids, especially on their filiform apparatus. Interestingly, WGA binding to egg cells was enhanced after fertilization, whereas PHA-E binding to egg cell membranes could only be detected after fertilization. These results suggest the occurrence of fertilization-induced changes in glycoconjugate composition of the maize egg cell membrane. An increase in the number of WGA and PHA-E binding sites was also observed on newly formed cell walls of cultured two-celled embryos derived from in vitro-produced zygotes.     

Dynamics of Nuclear DNA Quantities during Zygote Development in Barley

Quantities of DNA were estimated in the nuclei of mechanically isolated egg and zygote protoplasts in two cultivars of barley using 4[prime],6-diamidino-2-phenylindole staining and microfluorometry. Unlike many previous studies on DNA amounts within the sex cells of flowering plants, we obtained consistent and unambiguous results indicating that the egg and sperm nuclei are at the 1C DNA level (basic haploid amount) at the time of karyogamy. Karyogamy was initiated within 60 min postpollination, and the male chromatin became completely integrated into the egg nucleus within 6 to 7 hr postpollination (hpp). Zygotic nuclear DNA levels began to increase at ~9 to 12 hpp in cultivar Alexis and at 12 to 15 hpp in cultivar Igri. The 4C DNA complement was reached in most zygotes by 22 to 26 hpp in cultivar Alexis and by 23 to 29 hpp in cultivar Igri. These data are fundamental to a better understanding of fertilization and zygote maturation in flowering plants. They are also relevant to studies in which the timing of zygotic DNA replication is of interest, such as ongoing investigations on genetic transformations in barley using the microinjection technique.     

Fate of plasmid DNA in transformation of Bacillus subtilis protoplasts

Summary Polyethylene glycol-treated protoplasts of B. subtilis can be transformed by plasmid DNA at very high frequencies (Chang and Cohen 1979). From analysis of plasmid mediated transformation of transformation-deficient mutants it appeared that mutants, reduced in the transformation by plasmid DNA in the competent state, were plasmid transformation-proficient when transformed as protoplasts. By means of CsCl-gradient centrifugation of re-extracted plasmid DNA it could be demonstrated that plasmid DNA enters the protoplasts in the double-stranded form. In addition, sucrose gradient centrifugation of the re-extracted plasmid DNA showed that the entered DNA is predominantly present as covalently closed circular DNA. The efficiency of plasmid transformation in protoplasts was found to be close to one (each plasmid molecule having entered into the protoplasts gives rise to a transformed cell). This is in good agreement with the observation that little, if any, damage is done to this DNA during or after entry into protoplasts.     

Visualisation of transgene expression at the single protoplast level

Protoplasts are currently used to study the expression of genes following transformation. Expression is followed on a population of protoplasts after total protein extraction by conventional western blotting or measure of the enzymatic activity of the transgenic protein. We describe here a new method, called protoplast printing, allowing easy detection of the fraction of cells expressing a certain protein within a population of protoplasts. It consists of immobilization of the protoplast proteins on a nitrocellulose filter, so as to retain the outlines of the cell, followed by immunological detection of the protein of interest. The only special requirement is an antibody specific for the protein. We have studied the expression of the BNYVV coat protein after electroporation of Chenopodium quinoa protoplasts with viral RNAs, and the expression of the NPT II gene in protoplasts isolated from transgenic tobacco plants as well as after direct transfer of plasmid DNA into tobacco protoplasts. In both cases — infection with viral RNAs and transformation with plasmid DNA — expressing and non-expressing cells can be distinguished as early as 12h after transfer of the transgenes.Abbreviations BCIP 5-bromo-4-chloro-3-indolylphosphate - BNYVV beet necrotic yellow vein virus - CaMV Cauliflower Mosaic Virus - NBT nitroblue tetrazolium chloride - NPT II Neomycin phospho transferase     

Transient expression of fluorescent fusion proteins in protoplasts of suspension cultured cells

Transient expression of fluorescent fusion proteins in plant cells has dramatically facilitated our study of newly identified genes and proteins. This protocol details an in vivo transient expression system to study the subcellular localization and dynamic associations of plant proteins using protoplasts freshly prepared from Arabidopsis or tobacco BY-2 suspension cultured cells. The method relies on the transformation of DNA constructs into protoplasts via electroporation. The whole protocol is comprised of three major stages: protoplast generation and purification, transformation of DNA into protoplasts via electroporation and incubation of protoplasts for protein analysis. Similar to stably transformed cell lines, transformed protoplasts are compatible with protein localization studies, pharmaceutical drug treatment and western blot analysis. This protocol can be completed within 11-24 h from protoplast production to protein detection.     

花粉管通道法转基因技术的细胞胚胎学机理探讨

本文从细胞胚胎学出发,从理论上对花粉管通道、花粉管通道法的转化机理进行了研究。认为,外源DNA进入胚囊的途径,即外源DNA沿着连接柱头与胚囊的花粉管外界面渗入胚囊;外源DNA转化的受体应为合子;外源DNA转化的时期应限定在精卵融合至合子分裂前这一段时期,此时合子细胞壁尚未封闭;外源DNA转化受体的机制可能是外源DNA与处于原生质体状态的合子的随机融合。强调在应用此方法时,应对植物雌蕊结构以及受精经历的时间有全面了解,并列出了一些重要植物授粉后受精过程各阶段的时间,对外源DNA导入部位和方法提出了建议,并分析了花粉管通道法转基因技术转化率较低的原因。     

Polyspermy in angiosperms: Its contribution to polyploid formation and speciation

Polyploidization has played a major role in the long‐term diversification and evolutionary success of angiosperms. Triploid formation among diploid plants, which is generally considered to be achieved by fertilization of an unreduced gamete with a reduced one, has been accepted as a means of polyploid production. In addition, it has been supposed that polyspermy also contributes to the triploid formation in maize, wheat, and some orchids; however, such a mechanism has been considered uncommon because reproducing the polyspermic situation and unambiguously investigating developmental profiles of polyspermic zygotes are difficult. To overcome these problems, rice polyspermic zygotes have been successfully produced by electrofusion of an egg cell with two sperm cells, and their developmental profiles have been monitored. The triploid zygotes progress through karyogamy and divide into two‐celled embryos via a typical bipolar mitotic division; the two‐celled embryos further develop into triploid plants, indicating that polyspermic plant zygotes, unlike those of animals, can develop normally. Furthermore, progenies consisting of triparental genetic materials have been successfully obtained in Arabidopsis through the pollination of two different kinds of male parents with a female parent. These different pieces of evidence for development and emergence of polyspermic zygotes in vitro and in planta suggest that polyspermy is a key event in polyploidization and species diversification.     

Zygote implantation to cultured ovules leads to direct embryogenesis and plant regeneration of wheat

Direct embryogenesis and plant regeneration were obtained by implantation of individual wheat ( Triticum aestivum L.) zygotes into cultured ovules of wheat or barley. The zygotes were isolated mechanically from emasculated spikes, 3–9 h after hand-pollination. In 13 independent experiments, a total of 186 zygotes were implanted into excised ovules obtained from emasculated spikes which had been treated previously with 2,4-dichlorophenoxyacetic acid to induce parthenocarpic, embryoless ovary development. On average, 17.2% of the implanted zygotes gave rise to dorsiventrally differentiated embryos. The embryos resembled those growing in planta with no obvious deviation from the zygotic embryogenesis pathway. In contrast to previously described regeneration systems from individual zygotes of higher plants, this is the first study in which direct embryo formation is reproducibly obtained without intermediate tissue dedifferentiation. Most embryos germinated when transferred to regeneration medium, and later formed phenotypically normal, fully fertile plants. Regenerants were confirmed to be derived from the implanted zygotes by means of AFLP and/or morphological analyses. Although zygote implantation has long been established as a useful method in sexual animal reproduction, an equivalent technique for plants is described here for the first time. Since the zygotes enter the embryogenic pathway directly, the genome is presumably as stable as during embryogenesis in planta . With this new approach, isolated wheat zygotes are accessible to micromanipulation without affecting their subsequent embryonic development.     

Optimum Conditions for Electric Pulse-mediated Gene Transfer to Bacillus subtilis Cells

It was found that plasmid DNA (pUB 110) can be introduced into not only protoplasts but also intact cells of Bacillus subtilis by electric field pulses. The transformation of, B. subtilis using protoplasts results in an efficiency of 2.5 × 10⁴ transformants per μg of DNA, with a single pulse of 50 jisec with an initial electric field strength of 7kV/cm. Even transformation of intact B. subtilis cells results in a maximum efficiency of 1.5 × 10³ transformants per μg DNA, with a single pulse of 400 μsec with an initial electric field strength of 16kV/cm. The cell survival of protoplasts and intact cells was approximately 100% and 30%, respectively, under the conditions found to be optimal for the transformation process. Plasmid DNA isolated from pUB 110 containing transformants was indistinguishable from authentic preparations of pBU 110 on gel electrophoretic analysis.     

Advances in cereal protoplast research

Beginning in 1986, plants have been regenerated from protoplasts of all of the important cereal species, including wheat, rice, maize, and barley, and grasses such as sugarcane. In addition, somatic hybrids/cybrids as well as transgenic plants with introduced useful agronomic traits have been obtained in several instances. This rapid and impressive progress in the genetic manipulation of cereals has been made possible by two critical technical advances during the past decade: the establishment of embryogenic suspension cultures as a source of totipotent protoplasts and the direct delivery of DNA into protoplasts for genetic transformation.