Growth in vitro of arrested embryos from lethal mutants ofArabidopsis thaliana

Summary Seventeen embryo-lethal mutants ofArabidopsis thaliana with lethal phases ranging from the globular to mature cotyledon stages of development were analyzed by culturing arrested embryos on nutrient media designed to promote either callus formation or the completion of embryo development and the recovery of homozygous mutant plants. Enriched media supplemented with vitamins, amino acids, and nucleosides were used to identify potential auxotrophic mutants. Wild-type embryos produced extensive callus on basal and enriched media supplemented with 2,4-D and kinetin. Numerous roots developed when wildtype callus was grown in the presence of NAA and kinetin. Mutant embryos arrested prior to the heart stage of development formed only a slight amount of callus on basal and enriched media. Arrested embryos from mutants 122G-E and 112A-2A reached a later stage of development and gave the most interesting responses in culture. 122G-E mutant embryos failed to grow on basal media but produced extensive callus and homozygous mutant plants on enriched media. The specific nutrient required for growth of this mutant remains to be determined. Arrested embryos from mutant 112A-2A developed into abnormal plants without roots when placed in culture. Mutant callus also failed to form roots on a variety of root-inducing media. Expression of this mutant gene therefore disrupts development of the root apical meristem during both embryogenesis in vivo and organogenesis in vitro.     

Somatic embryony patterns and plant regeneration inIpomoea batatas poir

Summary Patterns of somatic embryo development from callus were elucidated inIpomoea batatas Poir. (sweet potato). Embryos at three stages of development were able to grow into plants. They included embryos arrested at the late torpedo and cotyledonary stages, and an arrested torpedo embryo that resulted from precocious hypocotyl expansion. Early torpedo-stage embryos rooted on reculture but did not form shoots. A diversity of other embryo stages were also produced which upon reculture formed only adventitious embryos and roots. Morphologic variants with similar growth potential were noted among embryos at similar stages of development. Plasticity in somatic embryo developmental patterns led to different forms that were mature enough to produce plants. This work has been funded in part by an IFAS/Gas Research Institute cooperative grant. Florida Agricultural Experiment Station Journal Series No. 8789.     

Embryo-lethal mutants of Arabidopsis thaliana: analysis of mutants with a wide range of lethal phases

Summary Embryo-lethal mutants of Arabidopsis thaliana were isolated by treating mature seeds with an aqueous solution of ethyl methanesulfonate (EMS), screening the resulting M-1 plants for siliques containing 25% aborted seeds following self-pollination, and verifying the presence of induced mutations in subsequent generations. Thirty-two recessive lethals with a Mendelian pattern of inheritance were examined in detail. Developmental arrest of mutant embryos ranged from the zygotic stage of embryogenesis in mutant 53D-4A to the linear and curled cotyledon stages of development in mutants 112A-2A and 130B-A-2. These lethal phases did not change significantly when plants were grown at 18 °C rather than at 24 °C. Differences between mutant lines were found in the color of arrested embryos and aborted seeds, the percentage and distribution of aborted seeds in heterozygous siliques, the size of arrested embryos, and the extent of abnormal development. Unusual mutant phenotypes included the presence of unusually large suspensors, distorted and fused cotyledons, reduced hypocotyls, and arrested embryos without distinct cotyledons or hypocotyl tissue. The isolation of eight new mutants with a non-random distribution of aborted seeds in heterozygous siliques provides further evidence that many of the genes that control early stages of embryogenesis in plants are also expressed prior to fertilization.     

A RING-H2 zinc-finger protein gene RIE1 is essential for seed development in Arabidopsis

RING zinc-finger proteins play important roles in the regulation of development in a variety of organisms. In the plant kingdom, few genes encoding RING zinc-finger proteins have been documented with visible effects on plant growth and development. A novel gene, RIE1, encoding a RING-H2 zinc-finger protein was identified in Arabidopsis thaliana and is characterized in this paper. RIE1 encodes a predicted protein product of 359 amino acids residues with a molecular mass of 40 kDa, with a RING-H2 zinc-finger motif located at the extreme end of the C-terminus. Characterization of a Dissociation (Ds) insertion line (SGT4559) and a T-DNA insertion line (SRIE1) demonstrated that disruption of RIE1 is embryo-lethal. SGT4559 heterozygous plants produced seeds with embryo development arrested from globular to torpedo stages. Some mutant seeds were rescued by embryo culture, and the mutant (rie1) plants seemed to grow normally compared to wild-type plants, except that the mutants produced only abnormal seeds. However, RIE1 was expressed in different tissues throughout the whole plant as revealed by northern blot analysis and gene fusion assay of RIE1 promoter with the beta-glucuronidase (GUS) gene. Our results indicated that RIE1 plays an essential role in seed development.     

Improved efficiency in apricot breeding: Effects of embryo development and nutrient media on in vitro germination and seedling establishment

Apricot (Prunus armeniaca L.) embryos at three stages of development were cultured on C2d, SBH and WPM media. In vitro culture produced high percentages of germination and seedlings throughout all three developmental stages. Significant media effects were noted for changes in both embryo length and weight during the culture period, as well as number of plants produced. Embryos between 5 and 9 mm (developmental stage I) germinated and developed into plants in a significantly higher percentage than in the other two more mature stages. Therefore, embryo culture can be successfully used as a tool in an apricot breeding program to obtain higher percentages of seedlings from planned hybridization or to overcome a lack of seed germination.     

In silico identification and characterization of putative differentially expressed genes involved in common bean (<Emphasis Type="Italic">Phaseolus vulgaris</Emphasis> L.) seed development

Two genotypes of common bean (Phaseolus vulgaris L.) were studied to determine the structural cause of seed abortion in this species. In the non-abortive control (wild-type, cultivar BAT93), the histological analysis revealed a classical pattern of seed development and showed coordinated differentiation of the embryo proper, suspensor, endosperm tissue and seed coat. In contrast, the ethyl methanesulfonate (EMS) mutant (cultivar BAT93) showed disruption in the normal seed development leading to embryo abortion. Aborted embryos from these degenerate seeds showed abnormalities in suspensor and cotyledons at the globular, heart, torpedo and cotyledon stages. Exploring the feasibility of incorporating the available online bioinformatics databases, we identified 22 genes revealing high homology with genes involved in Arabidopsis thaliana embryo development and expressed in common bean immature seeds. The expression patterns of these genes were confirmed by RT–PCR. All genes were highly expressed in seed tissues. To study the expression profiles of isolated genes during Phaseolus embryogenesis, six selected genes were examined by quantitative RT–PCR analysis on the developing embryos of wild-type and EMS mutant plants. All selected genes were expressed differentially at different stages of embryo development. These results could help to improve understanding of the mechanism of common bean embryogenesis.     

Mapping genes essential for embryo development in Arabidopsis thaliana.

Summary We have previously isolated and characterized over 90 recessive mutants of Arabidopsis thaliana defective in embryo development. These emb mutants have been shown to differ in lethal phase, extent of abnormal development, and response in culture. We demonstrate in this report the value and efficiency of mapping emb genes relative to visible and molecular markers. Sixteen genes essential for embryo development were mapped relative to visible markers by analyzing progeny of selfed F₁ plants. Embryonic lethals are now the most common type of visible marker included on the linkage map of Arabidopsis. Backcrosses were used in several cases to orient genes relative to adjacent markers. Three genes were located to chromosome arms with telotrisomics by screening for a reduction in the percentage of aborted seeds produced by F₁ plants. A restriction fragment length polymorphism (RFLP) mapping strategy that utilizes pooled EMB/EMB F₂ plants was devised to increase the efficiency of mapping embryonic lethals relative to molecular markers. This strategy was tested by demonstrating that the biol locus of Arabidopsis is within 0.5 cM of an existing RFLP marker. Mapping embryonic lethals with both visible and molecular markers may therefore help to identify large numbers of genes with essential functions in Arabidopsis.     

ULTRASTRUCTURE OF ARRESTED EMBRYOS FROM LETHAL MUTANTS OF ARABIDOPSIS THALIANA

The purpose of this study was to examine the extent of cellular differentiation in arrested embryos from lethal mutants of Arabidopsis thaliana. The question to be addressed was whether arrested embryos in heterozygous siliques resembled mature wild-type embryos at the cellular level. Protein bodies were chosen as developmental markers because they appear only during the final stages of embryogenesis. Both the hypocotyl and cotyledons of wild-type embryos contained protein bodies that became filled with storage protein during the cotyledonary stages of development. Some mutant embryos (emb30) contained normal protein bodies and resembled mature wild-type embryos at the cellular level. Other mutant embryos (emb22) contained only immature protein bodies and were therefore blocked in both morphogenesis and cellular differentiation. The formation of protein bodies in emb31 was normal in the hypocotyl but delayed in the cotyledons. In this case the mutant gene appears to disrupt the timing of both morphogenesis and differentiation. This ultrastructural view of arrested embryos has provided additional information on the nature of developmental arrest that should facilitate the classification of embryonic lethals and the identification of mutants with defects in developmental rather than housekeeping functions.     

In vitro culture of embryos of Cucumis spp.: heart-stage embryos have a higher ability of direct plant formation than advanced-stage embryos

Summary The ability of embryos at different developmental stages to form plants in vitro has been studied in cultivated Cucumis sativus L. and in the wild species C. zeyheri 2 x Sond. and C. metuliferus Naud. On MS medium containing 3.5% sucrose, 0.1 mg 1^–1 kinetin (Kn) and 0.01 mg 1^–1 indoleacetic acid (IAA), proembryos (0.03–0.05 mm) and early globular embryos (0.05–0.08 mm) from the wild species developed into plants in low frequencies of 8% and 21%, respectively. These embryos should be surrounded by the embryo sac tissue. On the same medium late globular (0.08–0.1 mm) and early heart-stage embryos (0.1–0.3 mm) developed into plants in moderately high and high frequencies of 48% and 83%, respectively. The presence of the embryo sac at these stages was still beneficial, but no longer a prerequisite. Late heart-stage embryos (0.3–0.8 mm) also showed high frequencies of plant formation, 63%, if Kn was applied at a concentration of 1 mg 1^–1. From the early cotyledon stage onwards, the frequency of plant formation gradually decreased, reaching a minimum at the late cotyledon stage. Subsequently it began to increase again up to the late maturation stage. The poor plant formation shown by the intermediate-aged embryos could be improved slightly by lowering the sucrose concentration to 0.5% and by increasing the Kn concentration to 10 mg 1^–1. Relative to the wild species, embryos of C. sativus showed lower percentages of plant formation. The optimum sucrose concentration was 2% for the heart-stage C. sativus embryos. In all three species the ability to form plants strongly decreased with increasing embryo age, from early to late cotyledon. This is thought to be caused by the increasing tendency of the embryos at these stages to continue in vitro the normal embryo development.     

A key to totipotency: Wuschel-like homeobox 2a unlocks embryogenic culture response in maize (Zea mays L.)

The ability of plant somatic cells to dedifferentiate, form somatic embryos and regenerate whole plants in vitro has been harnessed for both clonal propagation and as a key component of plant genetic engineering systems. Embryogenic culture response is significantly limited, however, by plant genotype in most species. This impedes advancements in both plant transformation-based functional genomics research and crop improvement efforts. We utilized natural variation among maize inbred lines to genetically map somatic embryo generation potential in tissue culture and identify candidate genes underlying totipotency. Using a series of maize lines derived from crosses involving the culturable parent A188 and the non-responsive parent B73, we identified a region on chromosome 3 associated with embryogenic culture response and focused on three candidate genes within the region based on genetic position and expression pattern. Two candidate genes showed no effect when ectopically expressed in B73, but the gene Wox2a was found to induce somatic embryogenesis and embryogenic callus proliferation. Transgenic B73 cells with strong constitutive expression of the B73 and A188 coding sequences of Wox2a were found to produce somatic embryos at similar frequencies, demonstrating that sufficient expression of either allele could rescue the embryogenic culture phenotype. Transgenic B73 plants were regenerated from the somatic embryos without chemical selection and no pleiotropic effects were observed in the Wox2a overexpression lines in the regenerated T0 plants or in the two independent events which produced T1 progeny. In addition to linking natural variation in tissue culture response to Wox2a, our data support the utility of Wox2a in enabling transformation of recalcitrant genotypes.     

Influence of primary callus induction conditions on the establishment of barley cell suspensions yielding regenerable protoplasts

Summary With the aim of the development of a culture method for efficient plant regeneration from barley (Hordeum vulgare L.) protoplasts, we examined several culture conditions for primary calli from immature embryos of cvs. Dissa and Igri, which were used for initiation of cell suspensions. Among the primary callus culture conditions tested, growth condition of donor plants had a great impact on these efficiencies; Igri protoplasts derived from embryos of plants grown in a greenhouse gave rise to albino plants and few green shoots while several cell lines originating from embryos of plants grown in a growth chamber (16h light, 12°C) yielded protoplasts developing into green plants. In contrast, cell suspensions were produced at higher frequencies from calli derived from embryos of greenhouse-grown Dissa plants. In Igri, increased levels of 2,4-dichlorophenoxyaceticacid (2,4-D) significantly reduced the efficiency of cell suspension establishment and plant regeneration from protoplasts was achieved only with suspension cells derived from calli induced at the lowest level (2.5 mg/l), while the effect of the 2,4-D concentration was not clear in Dissa. The developmental stage of immature embryos also affected the efficiency of cell suspension establishment, and the optimal embryo size was determined to be approximately 1mm in diameter. These results demonstrate the importance of callus induction conditions for successful barley protoplast culture.     

Plant regeneration from microspore-derived embryos ofBrassica Napus: Effect of embryo age,culture temperature,osmotic pressure,and abscisic acid

Summary Microscope cultures ofBrassica napus cv. Topas undergo high frequency embryogenesis in vitro; however, the majority of microspore-derived embryos do not develop directly into plants but usually undergo abnormal development including the formation of secondary embryos on the hypocotyls. The present studies show that older embryos or embryos cultured at higher temperature (25° C) were more likely to undergo secondary embryogenesis whereas embryos cultured at 20° C or pretreated at 5° to 10° C for 28 days developed more readily into normal plants. Compared with embryos cultured at 25° C, those cultured at 20° C gave a threefold increase in normal plant production. Pretreatments at cooler temperatures (5° to 10° C) resulted in an additional two-to threefold increase in the recovery of normal plants. Higher osmoticum during pretreatment improved embryo survival at low temperatures but generally inhibited normal plant development. Abscisic acid was ineffective or deleterious.     

In vitro development of maize immature embryos: a tool for embryogenesis analysis

During monocot embryo development, the zygote goes through a proembryo stage characterized by a radial symmetry and later becomes a true embryo with a bilateral symmetry. In order to determine culture conditions for immature embryonic stages, proembryos and embryos were isolated from controlled pollinated maize plants and developed in vitro. Precise culture conditions were determined for each type of explant: a monolayer system for embryos using NBM medium enriched with maltose (0.25 M) but without hormones, and a bilayer system for proembryo stages using N6 medium supplemented with maltose (0.35 M) and zeatin (3 mM). Morphological, cytological, and in situ hybridization analysis have shown that the resulting embryos (stages 1-2), developed in vitro, were similar to those formed in vivo and subsequently gave rise to fertile plants. This work demonstrates that successful embryo differentiation is dependent on specific parameters including the genotype, the nature of the carbon source, the type and concentration of hormones used and orientation of the embryos on the medium. The potential use of these results for embryo rescue and mutant analysis are discussed.     

AtCSLA7, a cellulose synthase-like putative glycosyltransferase,is important for pollen tube growth and embryogenesis in Arabidopsis

The cellulose synthase-like proteins are a large family of proteins in plants thought to be processive polysaccharide beta-glycosyltransferases. We have characterized an Arabidopsis mutant with a transposon insertion in the gene encoding AtCSLA7 of the CSLA subfamily. Analysis of the transmission efficiency of the insertion indicated that AtCSLA7 is important for pollen tube growth. Moreover, the homozygous insertion was embryo lethal. A detailed analysis of seed developmental progression revealed that mutant embryos developed more slowly than wild-type siblings. The mutant embryos also showed abnormal cell patterning and they arrested at a globular stage. The defective embryonic development was associated with reduced proliferation and failed cellularization of the endosperm. AtCSLA7 is widely expressed, and is likely to be required for synthesis of a cell wall polysaccharide found throughout the plant. Our results suggest that this polysaccharide is essential for cell wall structure or for signaling during plant embryo development.     

Isolated microspore culture of Chinese flowering cabbage (Brassica campestris ssp. parachinensis)

Microspores of several genotypes of Brassica campestris ssp. parachinensis have been cultured in vitro and induced to undergo embryogenesis and plant formation. Conditions favourable for embryogenesis in this species include a bud size of 2–2.9 mm, NLN-13 culture medium (Nitsch and Nitsch 1967; Lichter 1981, 1982; Swanson 1990), and an induction through exposure to 32°C for a period of 48 h. Longer periods of an elevated temperature for induction of embryogenesis resulted in embryo abortion at early developmental stages. With the protocol developed here, microspores of 60–80% of donor plants could be induced to produce embryos, although embryo yields were low, i.e. 2–5 embryos per 10 buds. Some genotypes responded to culture conditions with high numbers of embryo formation (100–150 embryos per 10 buds) but most of these subsequently failed to mature. The pattern of cell division and morphological changes of the microspores in culture were studied using various microscopic techniques.     

Enclosure of bacteria by the rough endoplasmic reticulum of shrimp hepatopancreas cells

Summary Zygotic embryos ofArabidopsis thaliana showed three different types of developmental response, when cultured in vitro: (1) normal development, (2) formation of morphogenetic callus, and (3) somatic embryogenesis. Early zygotic embryos were mechanically isolated and inoculated into different volumes of various culture media. It was possible to isolate embryos to the octant stage. Survival and further development in culture were observed in embryos to the early globular stage. Culture success increased with the initial size of the cultivated embryos. Neither the volume of the culture medium nor its composition were found to significantly influence the proportion of embryos developing in vitro. Whereas normal development from stages beyond 35 m diameter was possible without phytohormones, callus formation was frequently observed in the presence of phytohormones, even if used at very low concentrations. Embryos smaller than 35 m formed callus even without added phytohormones, and the proportion of embryos undergoing callus formation decreased with increasing embryo size at the time of culture initiation. Shoot morphogenesis was easily induced in embryo derived callus. Somatic embryogenesis was reliably observed during the culture of embryos from later stages (post heart-shaped) in liquid medium on a shaker.Abbreviations IAA indoleacetic acid - KIN kinetin - NAA -naphthaleneacetic acid     

Comparative analysis of early embryonic sunflower cDNA libraries

To gain information concerning cell functions and activities during sunflower embryogenesis, an expressed sequence tag (EST) approach was used to analyse gene expression in the early stages of sunflower embryos development. Confocal microscopy observations of whole-mounted embryos allowed us to identify precisely the major steps of the zygotic embryonic development. A time-course analysis was then employed to collect the embryonic material. Three cDNA libraries were constructed from microdissected embryos, and three other cDNA libraries were created using a classical day after pollination schedule. A total of 7106 ESTs were produced and assembled. The total number of putative different genes represents about 43.1 (3064 tentative contigs and singlets) of the analysed sequences. The unigenes that showed similarity to proteins with known or predicted functions (50.3) were classified into 15 different functional categories. The functional profiles were found to be quite similar for all studied embryo stages but statistical analysis revealed that successive and coordinate sets of genes are expressed at each embryonic stage. The analysis allowed us to identify abundant and differentially expressed genes at the early stages of embryos development as well as some putatively interesting genes, showing strong similarities with genes playing key roles in plant and animal embryogenesis. The data presented in this study not only provide a first global overview of the genes expression profile during sunflower embryogenesis but also represent an original and valuable tool for developmental genomics studies on exalbuminous dicots.     

Pleiotropic morphological and abiotic stress resistance phenotypes of the hyper-abscisic acid producing Abo™ mutant in the periwinkleCatharanthus roseus

The pleiotropic properties of aabo abo (Abo^™) γ-ray induced mutant ofCatharanthus roseuscv. Nirmal, selected among the M₂ generation seeds for ability to germinate at 45°C, are described. The mutant produced seeds possessing tricotyledonous embryos, unlike the typically dicotyledonous embryos present in the wild type Abo⁺ seeds. In comparison to Abo⁺ adults, the mutant plants had short stature and lanceolate leaves. The vascular bundles in the leaves and stem were poorly developed. Leaf surfaces were highly trichomatous, epidermal, cortex and mesophyll cells were small sized and a large majority of stomata were closed. Besides high temperature, the mutant was salinity and water-stress tolerant. The abscisic acid (ABA) content in the leaves was about 500-fold higher. The genetic lesionabo responsible for the above pleiotropy was recessive and inherited in Mendelian fashion. The seedlings and adult plants of the mutant accumulated higher proline than Abo⁺ plants. The phenotypes ofabo abo mutants permitted the conclusions that (i) the mutant synthesizes ABA constitutively, (ii) both ABA-dependent and ABA independent pathways for proline and betaine accumulation are functional in the mutant, and (iii) cell division, elongation and differentiation processes in embryo and adult plant stages are affected in the mutant.     

The initiation of callus and regeneration from callus culture ofTulipa gesneriana

Intergeneric Fragaria vesca x Potentilla fruticosa hybrids were produced using in vitro culture. Hybrid plants were not obtained by direct embryo rescue, but were regenerated from cotyledon-derived callus. Experiments with F. vesca indicated that using cotyledon halves was not more productive than using entire cotyledons. A polarity was observed in cotyledons and in cotyledon halves, with callus and regenerated shoots produced more frequently from proximal ends. Cotyledons from 17% of hybrid embryos produced callus and regenerated mature plants. The technique enabled rapid multiplication of some embryos, with the production of more than one hybrid plant. In some cases more than 100 shoots were obtained from one embryo, demonstrating the potential usefulness of this technique for the production of intergeneric hybrids.Abbreviations BA 6-benzylaminopurine - IAA indole-3-acetic acid - NAA -naphthaleneacetic acid