Effects of light on somatic embryo development and abscisic levels in carrot suspension cultures

Carrot cells were cultured under various light spectra and intensities at different times following the initiation of suspension cultures from callus. The highest intensity white and blue light treatments were inhibitory to growth and somatic embryogenesis. Red and green light were not different from dark treatments which produced the highest total number of embryoids. After extended time in culture, carrot cells in blue light produced secondary embryoids and anthocyanin. Cultures in red light had multiple cotyledons and orange-pigmented radicles. Leafy cotyledons occurred in all light treatments. Abscisic acid production peaked at the heart stage of embryogenesis and synthesis was most pronounced in blue light. Red light enhanced development to the heart stage. Both the red and blue light spectra may be used to manipulate carrot cell cultures to optimize growth.     

Synchronization of somatic embryogenesis in a carrot cell suspension culture

Synchronization of somatic embryogenesis was achieved in a carrot (Daucus carota L. cv. “Kurodagosun”) suspension culture by sieving the initial heterogeneous cell population, by density gradient centrifugation in Ficoll solutions, and by subsequent repeated centrifugations at a low speed (50g) for a short time (5 seconds), followed by transferring the cell clusters obtained, which were composed of 3 to 10 cells, to a medium containing zeatin (0.1 micromolar) but no auxin. The frequency of embryo formation reached more than 90%, and synchrony of the embryogenetic process was observed at least in the early stages of the process. The system established in the present work provides a useful system for biochemical research into the mechanisms of somatic embryogenesis.     

Isolation of putative glycoprotein gene from early somatic embryo of carrot and its possible involvement in somatic embryo development

Somatic embryogenesis is a unique process in plant cells. For example, embryogenic cells (EC) of carrot (Daucus carota) maintained in a medium containing 2,4-dichlorophenoxyacetic acid (2,4-D) regenerate whole plants via somatic embryogenesis after the depletion of 2,4-D. Although some genes such as C-ABI3 and C-LEC1 have been found to be involved in somatic embryogenesis, the critical molecular and cellular mechanisms for somatic embryogenesis are unknown. To characterize the early mechanism in the induction of somatic embryogenesis, we isolated genes expressed during the early stage of somatic embryogenesis after 2,4-D depletion. Subtractive hybridization screening and subsequent RNA gel blot analysis suggested a candidate gene, Carrot Early Somatic Embryogenesis 1 (C-ESE1). C-ESE1 encodes a protein that has agglutinin and S-locus-glycoprotein domains and its expression is highly specific to primordial cells of somatic embryo. Transgenic carrot cells with reduced expression of C-ESE1 had wide intercellular space and decreased polysaccharides on the cell surface and showed delayed development in somatic embryogenesis. The importance of cell-to-cell attachment in somatic embryogenesis is discussed.     

Aspects of DNA, RNA and protein synthesis during somatic embryogenesis in a carrot cell suspension culture

Changes in DNA, RNA and protein content, incorporation of ³H-thymidine, ¹⁴C-uridine and ³H-leucine and template activity of chromatin were investigated in the early process of somatic embryogenesis in a carrot (Daucus carota L. cv. Kurodagosun) cell suspension culture using a synchronous system. An embryogenetic culture in a medium containing 10^-7M zeatin was compared with a non-embryogenetic culture in a medium containing 10^-7M zeatin and 5 x 10^-7M 2,4-D. DNA was synthesized very actively prior to and during the formation of globular embryos in the embryogenetic culture. The RNA and protein content per tube increased at an almost constant rate in both cultures, while the rate of incorporation of labelled precursors of RNA and protein rose much more prior to active DNA synthesis in the embryogenetic culture than in the non-embryogenetic culture. Template activity of chromatin was high in the early stage of embryogenesis in the embryogenetic culture. The results obtained here showed that synthesis and turnover of RNA and protein became active prior to active DNA synthesis in the early stage of embryogenesis, and that these changes at macromolecular levels may play important roles in embryogenesis.     

Growth and division of carrot cells in suspension culture

In a submerged culture of a strain of carrot cells, cellularmorphology and the mode of cell division were greatly affectedby growth factor(s) added to the medium. In the presence of2,4-D, cells showed two-dimensional growth and often formedtetrad-like structure after a set of two divisions. The sequenceof events was observed microscopically. Orientation of cellgrowth changed after the first division and the second cellplate formed at an oblique angle to the first. When IAA wasadded, instead of 2,4-D, cells showed one-dimensional growthand developed to a filamentous form. (Received June 1, 1970; )     

Isoperoxidases as markers of somatic embryogenesis in carrot cell suspension cultures

Growth, peroxidase activity and isoperoxidase pattern were studied during the growth cycle of 3 cell suspension lines of carrot ( Daucus carota L.), an embryogenic, a non-embryogenic and a habituated cell line. Isoelectric focusing of extracted proteins on agarose gels revealed the isoperoxidase pattern of the embryogenic line to include, among other differences, an isoperoxidase with a pl of pH 7.0 when grown under conditions stimulating embryogenesis. This isoperoxidase (P7.0: EC 1.11.1.7) was present between days 2 and 6 after subculturing, and this period correlates well with the early stages of somatic embryogenesis. This isoenzyme showed very low activity in the non-embryogenic and habituated cell suspension lines as well as in the embryogenic cell line in the presence of Daucus carota , 2,4–dichlorophenoxyacetic acid. P7.0 could probably be used as a biochemical marker of somatic embryogenesis.     

Pectic polysaccharides in carrot cells growing in suspension culture

Pectic polysaccharides in the cell wall of suspension-cultured carrot cells (Daucus carota L.) were fractionated into high- and low-molecular-weight components by molecular-sieve chromatography with a Sepharose 4B column. During the phase of cell-wall expansion, the relative content of low-molecular-weight polymers rapidly increased. Electrophoretic analyses of these fractions showed that the high-molecular-weight components were largely composed of neutral and weakly acidic polymers while the low-molecular-weight fraction contained, in addition to neutral polymers, strongly acidic polyuronides in which the content of neutral sugars was very small. The accumulation of a large amount of the strongly acidic polyuronides occurred in a late stage of cell-wall growth, concomitant with a marked decrease in the high-molecular-weight components.Abbreviation MW molecular weight     

Carotenoid synthesis in a suspension culture of carrot cells

Biosynthesis of carotenoid in cultured carrot cells was studiedin relation to cell growth and acetate metabolism. Of the twostrains tested, one (GD-1) predominantly produces ß-caroteneand the other (GD-2) lycopene. In both strains, carotenoid wasproduced in parallel with cell growth. Incorporations of acetate-¹⁴Cinto carotenoids, organic acids and amino acids were acceleratedby increasing the concentration of 2,4-D in the medium. (Received November 17, 1970; )     

Alcohol dehydrogenase gene expression in callus and somatic embryo of carrot

A carrot mRNA of about 1700 nucleotides hybridized specifically to a cloned maize alcohol dehydrogenase (Adh) gene. Hybridization of mRNAs from callus and somatic embryo to the maize probe suggests that Adh expression in carrot is similar in these two cell types.     

A carrot somatic embryo mutant is rescued by chitinase.

At the nonpermissive temperature, somatic embryogenesis of the temperature-sensitive (ts) carrot cell mutant ts11 does not proceed beyond the globular stage. This developmental arrest can be lifted by the addition of proteins secreted by wild-type cells to the culture medium. From this mixture of secreted proteins, a 32-kD glycoprotein, designated extracellular protein 3 (EP3), that allows completion of somatic embryo development in ts11 at the nonpermissive temperature was purified. On the basis of peptide sequences and biochemical characterization, EP3 was identified as a glycosylated acidic endochitinase. The addition of the 32-kD endochitinase to ts11 embryo cultures at the nonpermissive temperature appeared to promote the formation of a correctly formed embryo protoderm. These results imply that a glycosylated acidic endochitinase has an important function in early plant somatic embryo development.     

Potassium transport in suspension culture cells and protoplasts of carrot

The properties of potassium transport in carrot (Daucus carota L.) suspension culture cells and their isolated protoplasts were examined. Cells cultured in Murashige and Skoog (MS) medium (Plant Physiol 15: 473-497) were potassium saturated and, consequently, they exhibited little net potassium accumulation. Cells that transport and accumulate potassium were derived from the MS-grown cells by culturing them in a potassium-free modified medium. The transport properties of the modified medium cells included: (a) smooth nonsaturating kinetics with 80% of the maximum rates occurring at 0.1 millimolar KCl, (b) linear transport for at least 75 min, (c) alkaline pH optimum, (d) little accompanying anion uptake with increased malate concentrations balancing net increases in positive charge, and (3) little effect on transport by plasmolysis. Potassium transport activity appeared to be 50% lower in protoplasts isolated from the modified medium cells. Nevertheless, the protoplasts exhibited essentially the same kinetics, time course, pH response, and malate adjustment as the intact cells. We concluded from these results that the low potassium cells and their isolated protoplasts are ideally suited to investigating potassium transport at the cell level without the complications associated with multilayered and highly differentiated tissues.     

Calcium increases the yield of somatic embryos in carrot embryogenic suspension cultures

An upward shift in the concentration of calcium present in the medium during somatic embryogenesis increased the number of embryos produced approximately two-fold. This was observed when embryogenic suspension cells grown in 2,4-D medium with the normal calcium concentration of 10^–3 M were transferred to hormone-free medium containing 10^–2 M calcium and when embryogenic suspension cells grown in 2,4-D medium containing 10^–4 M calcium were transferred to hormone-free medium with 10^–3 M calcium. At calcium concentrations between 6·10^–3 and 10^–2 M globular stage somatic embryos were found in cultures supplemented with 2·10^–6 M of 2,4-D indicating that elevated calcium counteracts the inhibitory effect of 2,4-D on somatic embryogenesis. No qualitative changes were found in the pattern of extracellular polypeptides as a result of growth and embryogenesis in media with different calcium concentrations.     

Osmotically induced proton extrusion from carrot cells in suspension culture

Addition of 200 mm of a polyol to anthocyanin containing carrot (Daucus carota L.) cells in suspension culture decreased turgor pressure to zero and induced hyperpolarization of the membrane potential and acidification of the medium due to H⁺ extrusion. These changes were shown to be slightly affected by vanadate. In parallel, a decrease in intracellular ATP and total adenylate concentrations were observed. However, when the osmoticum was NaCl acidification of the medium occurred in the absence of considerable changes in intracellular ATP concentration. These results are interpreted as indicating that a drop of turgor, by addition of a polyol, triggers a proton extrusion activity which is only slightly inhibited by vanadate but apparently ATP utilizing. The observed decrease in ATP level occurs without a change in respiration rate and is accompanied by a drop in total adenylate pool. However when NaCl is the osmoticum it is assumed that Δ_μH+ is enhanced through a Na⁺/H⁺ antiporter. The difference between the two types of osmotica as related to their ability to penetrate through the cellular membrane is discussed.     

Induction of green ash embryogenic cultures with potential for scalable somatic embryo production using suspension culture

Key message

The developmental sequences of zygotic embryos of green ash collected from the same tree were widely asynchronous and an intermediate developmental stage was the best explant for inducing somatic embryogenesis.

Abstract

All North American ash (Fraxinus) species are under threat of extirpation from their native ranges by the emerald ash borer (EAB; Agrilus planipennis), an exotic wood-boring beetle that has already destroyed millions of ash trees in 15 U.S. states and Canada. We tested treatments aimed at initiating embryogenic cultures from seeds of green ash (F. pennsylvanica), with the long-term goal of using these cultures to aid in research to generate EAB-resistant ash trees for restoration. In preparation for somatic embryogenesis induction experiments, we first defined specific stage(s) of green ash zygotic embryo development using time-tracing sampling by collecting samaras of two green ash trees from May to August in 2012. Seed development was divided into seven stages according to both seed and embryo size, and the numbers of seeds and embryos in each stage were recorded for each collection date. Surprisingly, a broad range of seed and embryo developmental stages could be found in samaras collected from the same tree on the same date, in particular for the later collection dates. Using this information, single-date collections of seeds with embryos at various stages of development were made from three local Athens, GA green ash trees and one horticultural cultivar and cultured on two different basal media with different combinations of plant growth regulators (PGRs). A low percentage of zygotic embryo explants at an intermediate stage of development from all three local source trees produced proembryogenic masses (PEMs) when cultured on a modified Woody Plant Medium with 2,4-dichlorophenoxyacetic acid and benzyladenine. Although embryogenesis was also induced from explants of the horticultural cultivar, these cultures failed to produce germinable somatic embryos. Transfer of PEMs to PGR-free medium resulted in highly dense production of somatic embryos, some of which were germinated to produce somatic seedlings.     

Regulation of the shikimate pathway of carrot cells in suspension culture

The activity of the first enzyme of the shikimate pathway, 3-deoxy-d-arabino-heptulosonate 7-phosphate synthase, is demonstrated in extracts of Daucus carota cells grown in suspension culture. Maximum specific enzyme activity is found midway through the logarithmic growth of the culture; cells in lag and stationary phases of growth have lower enzyme levels. The enzyme is activated by tyrosine and tryptophan. The extent of activation varies during cell growth.     

Callus concentration regulates somatic embryo production in orchardgrass suspension cultures

Summary The effects of callus inoculation concentration and culture duration on somatic embryogenesis of orchardgrass,Dactylis glomerata L., were evaluated in suspension cultures of an embryogenic genotype Embryogen-P. Somatic embryo formation was induced in liquid SH medium containing 30 μM dicamba (SH-30 and 1.5% casein hydrolysate; embryo development was in liquid SH medium without plant growth regulators (SH-0); and embryo maturation and germination occurred on solid SH-0 medium. Callus proliferation in SH-30 suspension cultures was greatest when callus was inoculated into the liquid medium at a relatively high concentration of 4% (4 g callus/100 ml medium), but the induction of somatic embryos was highest in this medium if the callus was inoculated at a lower concentration (<2%). In a second experiment, somatic embryo yield was highest when SH-0 development medium was inoculated with suspension culture callus at 0.1% concentration and declined markedly as inoculation concentration increased. Cell concentration is a critical factor in regulating the somatic embryogenesis response in orchardgrass suspension cultures.     

Embryogenesis from microinjected single cells in a carrot cell suspension culture

A micrroinjection method was established for intact single cells with cell walls using a carrot suspension culture system in which selected single cells differentiate to embryos at high frequency. A solution of a fluorescent dye, Lucifer Yellow CH, was microinjected into those single cells, using an inverted microscope and a hydraulic micro-manipulator. In order to hold cells with cell walls and to overcome their turgor pressure, certain modification to conventional microinjection methods for protoplasts were necessary. The microinjected cells could divide and differentiate to embryos at a frequency of about 50%.     

An evaluation of gene expression during somatic embryogenesis of two temperature-sensitive carrot variants unable to complete embryo development

The synthesis of putative stage-specific polypeptides during somatic embryogenesis of the carrot ( Daucus carota L. cv. Danvers) was investigated in the temperature-sensitive variants OB-2 and OB-3. These variants undergo normal embryo development to produce mature plantlets at the permissive temperature (24°C), but are arrested at the oblong stage to form elongated embryos without cotyledons at the restrictive temperature (33°C). Using two-dimensional polyacrylamide gel electrophoresis of in vivo labelled polypeptides, the patterns of stage-specific polypeptides in both lines were compared in: (1) oblong embryos grown at continuous 24°C vs oblong embryos exposed to 33°C during their temperature-sensitive period (i.e. embryos of identical morphology but different developmental fates); and (2) heartshaped embryos grown at constant 24°C vs enlarged oblong embryos exposed to 33°C during their temperature-sensitive period (i.e. embryos of the same age but different morphologies). The 22 putative stage-specific, polypeptides observed in this study fall into four classes: (1) line-specific, (2) age-specific, (3) unsynchronized, and (4) synchronized polypeptides. Only the last class, which consists of 4 polypeptides, exhibits synthesis patterns which are consistent with the polypeptides being causally involved in somatic embryo development. It is concluded that stage-specific behavior as assayed by PAGE analyses of simple 'present or absent' comparisons is insufficient to identify most of the polypeptides that may be relevant for somatic embryogenesis.     

Kinetics of chick embryo cell types in culture

The growth kinetics and population doubling limits of chick embryonic fibroblasts, chondroblasts, and retinal pigment cells were compared. Chondroblasts were found to have a cumulative population doubling level (37 +/- 3 PDL) similar (p = 0.05) to that of control fibroblasts (42 +/- 2 PDL), in individual and pooled clones. While both cell types have similar doubling potential, the proportion of tritium-labeled nuclei decreases, and differs significantly as doubling level increases. This age-associated decline is due to an extension in the population doubling time. Direct cell-cycle analysis shows this increase to occur in the G1 phase. Furthermore, cartilage colonies maintain their phenotypic expression (metachromasia) throughout their lifespan under conditions of subcloning at sparse density. When fibroblasts derived from 15 day chick embryos are compared with fibroblasts from 10 day embryos (41 +/- 2 PDL) there is no significant difference (p = 0.05) in cumulative PDL or percent labeled nuclei, indicating that fibroblasts of different embryonic age have similar potential. The addition of hydrocortisone and insulin to the medium significantly shortens (25 +/- 2 PDL) the lifespan of 10 day chick fibroblasts. Kinetics of retinal pigment cells show a population doubling potential (29 +/- 1 PDL) different from fibroblasts and chondroblasts, suggesting that different cell types may not have similar limits on doubling potential when first determined in embryogenesis. Hydrocortisone and insulin have no effect on the growth kinetics or lifespan of retinal pigment cells in culture.