A carrot G-box binding factor-type basic region/leucine zipper factor DcBZ1 is involved in abscisic acid signal transduction in somatic embryogenesis.

Carrot (Daucus carota) somatic embryogenesis has been extensively used as an experimental system for studying embryogenesis. In maturing zygotic embryos, abscisic acid (ABA) is involved in acquisition of desiccation tolerance and dormancy. On the other hand, somatic embryos contain low levels of endogenous ABA and show desiccation intolerance and lack dormancy, but tolerance and dormancy can be induced by exogenous application of ABA. In ABA-treated carrot embryos, some ABA-inducible genes are expressed. We isolated the Daucus carota bZIP1 (DcBZ1) gene encoding a G-box binding factor-type basic region/leucine zipper (GBF-type bZIP) factor from carrot somatic embryos. The expression of DcBZ1 was detected in embryogenic cells, non-embryogenic cells, somatic embryos, developing seeds, seedlings, and true leaves. Notably, higher expression was detected in embryogenic cells, true leaves, and seedlings. The expression of DcBZ1 increased in seedlings and true leaves after ABA treatment, whereas expression was not affected by differences in light conditions. During the development of zygotic and somatic embryos, increased expression of DcBZ1 was commonly detected in the later phase of development. The recombinant DcBZ1 protein showed specific binding activity to the two ABA-responsive element-like motifs (motif X and motif Y) in the promoter region of the carrot ABA-inducible gene according to results from an electrophoretic mobility shift assay. Our findings suggest that the carrot GBF-type bZIP factor, DcBZ1, is involved in ABA signal transduction in embryogenesis and other vegetative tissues.     

Vacuolar accumulation of acridine orange and neutral red in zygotic and somatic embryos of carrot (Daucus carota L.)

Summary The accumulation of neutral red and acridine orange, to indicate differences in vacuolar pH, was studied during embryogenesis of carrot. Neutral red accumulated barely in proembryogenic masses, but was present conspicuously in globular-shaped somatic embryos. From the late globular to the torpedo-shaped stage, it was mainly found in the root side of the somatic embryo. Here, neutral red was predominantly present in large dark-red to purple stained vesicles. In the cotyledons neutral red was found in small orange vesicles. In zygotic embryos of carrot, the dye was uniformly distributed with no specific localization in organelles. During germination, however, neutral red accumulated mainly in regions in the root side and the hypocotyl of the germling. Acridine orange was dispersed erratically in proembryogenic masses with a great variety in intensity. It was quite obviously present in early stages of somatic embryogenesis and restricted to the root side in late globular to torpedo-shaped embryos. Confocal images revealed the vacuolar presence of the fluorescence and the predominant presence in the protoderm. During germination of zygotic embryos the signal changed from uniform to localized, with sharp borders between fluorescent and non-fluorescent regions. Two to three days after the beginning of germination, acridine orange accumulated preferentially in the root tip of the germling. Differences between somatic and zygotic embryos and similarities between somatic embryogenesis and zygotic embryo germination are discussed.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - pH_c cytosolic pH - pH_e extracellular pH - pH_v vacuolar pH     

Embryogenesis in flowering plants: Recent approaches and prospects

The overall architectural pattern of the mature plant is established during embryogenesis. Very little is known about the molecular processes that underlie embryo morphogenesis. Last decade has, nevertheless, seen a burst of information on the subject. The synchronous somatic embryogenesis system of carrot is largely being used as the experimental system. Information on the molecular regulation of embryogenesis obtained with carrot somatic embryos as well as observations on sandalwood embryogenic system developed in our laboratory are summarized in this review. The basic experimental strategy of molecular analysis mostly relied on a comparison between genes and proteins being expressed in embryogenic and non-embryogenic cells as well as in the different stages of embryogenesis. Events such as expression of totipotency of cells and establishment of polarity which are so critical for embryo development have been characterized using the strategy. Several genes have been identified and cloned from the carrot system. These include sequences that encode certain extracellular proteins (EPs) that influence cell proliferation and embryogenesis in specific ways and sequences of the abscisic acid (ABA) inducible late embryogenesis abundant (LEA) proteins which are most abundant and differentially expressed mRNAs in somatic embryos. That LEAs are expressed in the somatic embryos of a tree flora also is evidenced from studies on sandalwood. Several undescribed or novel sequences that are enhanced in embryos were identified. A sequence of this nature exists in sandalwood embryos was demonstrated using aCuscuta haustorial (organ-specific) cDNA probe. Somatic embryogenesis systems have been used to assess the expression of genes isolated from non-embryogenic tissues. Particular attention has been focused on both cell cycle and histone genes     

Molecular and genetic analysis of an embryonic gene, DC 8, from Daucus carota L

Summary To understand the morphogenetic and physiological processes occurring during plant embryogenesis, we isolated cDNA clones homologous to genes preferentially expressed during somatic embryogenesis. One of these cDNA clones detected an embryo-specific mRNA species with a corresponding protein of 66 kDa. The expression pattern of the mRNA is similar between somatic and zygotic embryos of carrots. To characterize the gene encoding this mRNA, we isolated the corresponding genomic clones. Molecular analysis of the DNA from several haploid and diploid carrots showed that the mRNA was encoded by a single copy gene, named DC 8. DNA sequence analysis showed that the gene consisted of three exons and coded for a hydrophilic protein with a central region composed of 17 repeats. At the NH₂-terminus no typical signal sequence was found. Immunocytochemical analysis localized the protein primarily in the vacuoles and protein bodies of zygotic embryos; the cytoplasm showed some antibody staining. The protein was also found in cell walls of endosperm tissue. The amount of DC 8 protein was too low for it to be categorized as a seed storage protein; its role in embryogenesis remains to be determined.     

Isolation of the gene encoding Carrot leafy cotyledon1 and expression analysis during somatic and zygotic embryogenesis.

The Arabidopsis thaliana LEC1 gene regulates embryo morphology and seed maturation. For a better understanding of its function, we isolated a carrot (Daucus carota L. cv. US-Harumakigosun) counterpart of this gene, C-LEC1, from a cDNA library of carrot somatic embryos, since carrot is a better model plant for preparing large quantities of somatic embryos at the same developmental stage. The predicted amino acid sequence of C-LEC1 is similar to that of LEC1 and contains regions that are conserved in the heme-activated protein 3 (HAP3) subunit of plants, animals and microorganisms. C-LEC1 expression was detected in embryogenic cells, somatic embryos, and developing seeds. In situ hybridization analysis revealed C-LEC1 expression in the peripheral region of the embryos but not in the endosperm. Expression of C-LEC1 driven by Arabidopsis LEC1 promoter was able to complement the defects of the Arabidopsis lec1-1 mutant. These results suggest that C-LEC1 is a functional homolog of Arabidopsis LEC1, an important regulator of zygotic and somatic embryo development.     

4-Hydroxybenzyl alcohol accumulates in flowers and developing fruits of carrot and inhibits seed formation

Somatic embryogenesis in carrot (Daucus carota) is autonomously inhibited by 4-hydroxybenzyl alcohol (4HBA), which is produced by embryogenic cells. Because somatic embryogenesis is used as a model of zygotic embryogenesis, we assayed for 4HBA in carrot seeds and analyzed the effect of 4HBA on seed formation to determine whether 4HBA is also produced during zygotic embryogenesis. HPLC analysis showed that 4HBA accumulated in flowers and immature and mature fruits, but not in vegetative tissues. The concentration of 4HBA was highest after flowering, when the zygote developed into the early globular-stage embryo. 4HBA accumulation then decreased with seed development. Exogenous application of 4HBA to immature carrot fruits inhibited seed formation. Many 4HBA-treated seeds did not include a mature embryo. These results indicate that the production and accumulation of 4HBA occurs during carrot seed development and that 4HBA has an inhibitory effect on carrot seed formation.