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.     

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.     

Relationship between auxin-induced cell proliferation and somatic embryogenesis in culture of carrot cotyledons

We elucidated the relationship between cell proliferation and somatic embryogenesis in the culture of carrot cotyledons. Fresh weights of the cotyledon expiants were determined every five days while being cultured on a medium containing 2,4-D. Callus production increased exponentially from Day 20 to Day 25, showing a two-fold rate of proliferation. To examine the embryogenic potential of the callus, we pre-cultured cotyledon explants on an MS medium with 2,4-D, then transferred them to an MS basal medium at five-day intervals. Somatic embryos formed most frequently when the cotyledons were pre-cultured for 20 days on an MS medium that contained 5 μ2,4-D. The frequency of somatic embryo formation was 81%, while that of normal embryos with two cotyledons was 51% among those formed on a hormone-free medium. We used FACScan analysis to relate the embryogenic potential of the callus to the S phase in the cell cycle of cultured cells. The S phase was high after 25 days of culture on the medium with 5 μM 2,4-D. In contrast, the frequency of normal embryogenesis was higher at Day 20 of the pre-culture period. Culturing embryogenic calli on a medium with 5 μM 2,4-D was most favorable for producing somatic embryos with two cotyledons. We verified that active somatic embryogenesis was apparently related to cell division activity; somatic embryos induced from actively dividing cells were apt to accompany cotyledonary abnormality.     

Kinetics of carrot somatic embryo development in suspension culture

Somatic embryos in liquid culture can serve as a mass cloning system in a plant propagation program. A quantitative formulation of embryo development obtained from cell suspension cultures is used to develop a segregated kinetic model. The model is based on standard classification schemes as previously developed by plant physiologists. Dependent variables include carbohydrate concentrations (sucrose, fructose, and glucose) and biomass apportioned among the inoculum (free single cells, cell clusters), normal developmental stages, and aberrant cell and embryo types. Good agreement between the model and experimental results is indicated and allows for a rigorous approach to media optimization and reactor scaleup for embryo formation.     

Effect of humidity on somatic embryogenesis in cotyledon explant culture of carrot

In order to clarify the influence of low humidity culture on the structure and function of somatic embryo the cotyledon expiants ofDaucus carrota L. cv. Hongshim were cultured in the petridish whose lids had holes sealed with millipore filters. In the low humidity culture, the production of somatic embryos was enhanced and their maturation promoted but the cotyledon structure of somatic embryos were nearly similar to control. In addition, the low humidity culture improved the germination of somatic embryos. Especially, the germination frequency of jar-shaped embryos was much improved (68%) in comparison with that of jarshaped embryos formed in constant humidity culture (23%). But low humidity culture at its extreme became an obstacle to normal plant regeneration in that precocious embryos were generated and the primary embryos turned into callus and formed secondary embryos. Therefore it is suggested that moderately low humidity culture (80–90% R.H.) is important to the higher production and better-quality of somatic embryos.     

Tunicamycin affects somatic embryogenesis but not cell proliferation of carrot

The antibiotic tunicamycin which specifically blocks the first step in the lipid-linked oligosaccharide pathway is capable of arresting somatic embryogenesis in a reversible way. At the same drug concentration cell proliferation is not affected. The quantitative and qualitative changes induced by tunicamycin in glycolipids and glycoproteins are the same in embryogenic and non-embryogenic conditions and this might therefore indicate some proteins whose glycosylation is essential for development.     

Gene expression during induction of somatic embryogenesis in carrot cell suspensions

We report the identification, via their cDNAs, of genes which are temporarily transcribed during the initiation of somatic embryogenesis in carrot (Daucus carota L.) cells cultured in an auxin-free medium. Their expression is roughly associated with the first morphogenetic, or globular, stage. A cDNA library ( gt 10) was established using poly(A)⁺ -rich RNAs from cells deprived of auxin for 8 d. By differential screening a number of clones corresponding to early-induced embryogenic genes were identified. For several a temporary accumulation of the specific mRNA between 6 and 16 d after induction was observed. With regard to the nucleotide sequence and the respective deduced amino-acid sequence, two glycine-rich proteins and a polypeptide with a proline-rich domain were among the products of genes activated at the onset of somatic embryogenesis.Abbreviations b, bp bases, basepairs - 2,4-D 2,4-dichlorophenoxyacetic acid Sequence data reported here will appear in the EMBL Genbank and DDBJ Nucleotide Sequence Databases under the following accession numbers: X 15436 for clone DC 2.15 (proline-rich protein), X 15706 for clone DC 7.1 (glycine-rich protein, DCGRP) and X 14067 for clone DC 9.1 (glycine-rich protein, DCGRP)This research was supported by the Deutsche Forschungsgemeinschaft. We thank Mrs. I. Liebscher for her competent assistance.     

Temperature-sensitive carrot variants impaired in somatic embryogenesis

Cultured cells of many plant species are capable of regenerating back to plants. In carrots, plant regeneration takes place via embryogenesis. Because vast numbers of somatic embryos are produced from haploid carrot cultures, it is possible to design a selection procedure for recovering temperature-sensitive variants impaired in early embryogenesis (ts-emb^?). The ts-emb^? lines fall into three classes. The first class is blocked before any growth in embryogenic medium can take place; the second class is blocked in organized growth: cells can grow as callus, but cannot form embryos; the third is blocked at the first stage of embryo development, the globular stage. These classes are useful in delineating the developmental steps during early somatic embryogenesis. The ts-emb^? phenotype of most variant lines is stable in culture and is maintained through plant regeneration. Hypotheses are made concerning the origin of the ts-emb^? phenotype. In addition to the ts-emb^? lines, other classes of variants have been recovered, i.e., ts-growth^?, habituated lines, and lines with altered responses to growth regulators.     

Enhancer-trapping system for somatic embryogenesis in carrot

Somatic embryogenesis in the carrot was used to model zygotic embryogenesis because the spatial and temporal changes in somatic and zygotic embryogenesis are quite similar. To establish an enhancer-trapping system for somatic embryogenesis in the carrot, we constructed 2 enhancer-trap vectors (pETVs) using the GUS reporter gene with a minimal promoter. We also constructed several positive control vectors (pPCVs) using the CaMV 35S promoter. These are models in which pETVs are inserted near a native enhancer region in correct or reverse orientation. First, we tested whether these vectors could be used as enhancer-trap vectors using transgenic hairy root of tobacco. Histochemical GUS assays revealed that pETVs could be used as enhancer-trap vectors, even when the reporter gene in the pETVs was inserted near the native enhancer. Subsequently, we examined the availability of pETVs in somatic embryogenesis in the carrot. The constructed vector was activated in transgenic carrot embryogenic cells at high frequency (64%). This suggests that the enhancer-trapping vector is suitable as a carrot somatic embryogenesis system.     

Effect of anti-microtubular drug amiprophos-methyl on somatic embryogenesis and DNA ploidy levels in alfalfa and carrot cell suspension cultures

A short treatment with the anti-microtubular drug amiprophos-methyl (APM) blocked somatic embryogenesis in alfalfa(Medicago sativa L.) and carrot (Daucus carota L.). The interruption was temporary and restoration of somatic embryogenesis was observed in long-term cultures. In addition to the effect on somatic embryogenesis, APM treatment induced polyploidization the extent of which was concentration dependent. In long-term alfalfa cultures, APM-induced loss of somatic embryogenesis led to ploidy instability and to a shift to DNA aneuploidy. Critical stages of somatic embryogenesis sensitive to disruption of microtubule-mediated processes were determined in carrot cell cultures. Complete embryogenic arrest occurred when APM was added within the first 5 d of embryogenesis from single cells. The role of the cytoskeleton in the first events of somatic embryogenesis and the relation between totipotency and ploidy stabilityin vitro is discussed.     

Identification of a transitional cell state in the developmental pathway to carrot somatic embryogenesis

We have located a novel carbohydrate epitope in the cell walls of certain single cells in embryogenic, but not in non-embryogenic, suspension cultures of carrot. Expression of this epitope, recognized by the mAb JIM8, is regulated during initiation, proliferation, and prolonged growth of suspension cultures such that changes in the abundance of JIM8-reactive cells always precede equivalent changes in embryogenic potential. Therefore, a direct correlation exists between the presence of the JIM8-reactive cell wall epitope and somatic embryo formation. The JIM8-reactive cell wall epitope is expressed in the cell walls of three types of single cells and one type of cell cluster. One of the single cell types seems able to follow one of two phytohormone-controlled developmental pathways, either a cell elongation pathway that eventually leads to cell death, or a cell division pathway that gives rise to proembryogenic masses. We demonstrate that all JIM8-reactive cell types in embryogenic carrot suspension cultures are developmentally related, and that the switch by one of them to somatic embryogenesis is accompanied by the immediate dissipation of the JIM8-reactive cell wall epitope. The cell wall carbohydrate epitope recognized by JIM8 therefore represents a cell wall marker for a very early transitional cell state in the developmental pathway to carrot somatic embryogenesis.     

Expression of the JIM8 cell wall epitope in carrot somatic embryogenesis

Certain single cells in carrot (Daucus carota L.) suspension cultures react with the monoclonal antibody JIM8, and it has been proposed that these cells represent a transitional stage in somatic embryo formation. Shortly after isolation of the single cells by sieving, up to 80% of the cells react with JIM8. Within 4 d, JIM8 labelling becomes restricted to 1% of the single cells. To obtain evidence for the proposed correlation between expression of the JIM8 cell wall epitope and somatic embryo formation the developmental fate of carrot single cells labelled with JIM8 was determined by cell tracking. The results, obtained by recording 43 000 cells, show that only few JIM8-labelled cells give rise to embryos, and most somatic embryos develop from cells devoid of the JIM8 cell wall epitope. We therefore conclude that the presence of the JIM8 cell wall epitope does not coincide with the ability of single suspension cells to form embryos.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - AGP arabino galactan protein - B5-0 Gamborg's B5 medium - B5-0.2 Gamborg's B5 medium supplemented with 0.2 M 2,4-D - FITC fluoresceïn isothiocyanate - PBS phosphate-buffered saline     

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%.     

Genetic analysis of somatic embryogenesis in carrot cell culture: Initial characterization of six classes of temperature-sensitive variants

Cell cultures of the carrot Daucus carota are a useful experimental system for studying the genetic regulation of plant embryogenesis. A modified filtration-enrichment procedure was used to isolate 21 temperature-sensitive variants in somatic embryogenesis; the variants display normal embryo development at the permissive temperature (24°C) and altered development at the restrictive temperature (33°C). Temperature-shift experiments were performed on these variants to determine the timing of gene action for the putative temperature-sensitive alleles. According to their phenotypes at the restrictive temperature, these variants can be divided into six classes: No Growth, Callus Proliferation, Globularstage Block, Oblong-stage Block, Lateral Growth, and Root Formation. Although many variants exhibit lengthy temperature-sensitive periods, the temperature sensitivity of some variants is restricted to one or two embryonic stages. These results plus those in the literature are incorporated into a preliminary model concerning the genetic regulation of carrot embryogenesis.     

Regeneration of a metal tolerant grass Echinochloa colona via somatic embryogenesis from suspension culture

An efficient protocol was developed for in vitro plant regeneration via somatic embryogenesis from cell suspension cultures of metal tolerant grass Echinochloa colona (L.) Link. Callus was obtained by culturing leaf base on MS medium supplemented with 0.5 mg dm^-3 of 6-benzylaminopurine (BAP) and 2.0 mg dm^-3 of 1-naphthaleneacetic acid (NAA). Cell suspensions were initiated and established in MS liquid medium containing 0.5 mg dm^-3 BAP, 1.0 mg dm^-3 NAA and 2.0 mg dm^-3 2,4-dichlorophenoxyacetic acid (2,4-D). A reduction in the concentration of 2,4-D to 0.5 mg dm^-3 induced formation of somatic embryos. The embryos developed and grew into normal plants in the presence of half strength MS medium without growth regulators. The regenerated plants were hardened in the greenhouse and subsequently grown in the open. This system may be also used for isolation and culture of protoplasts as a first step in somatic hybridization. This revised version was published online in July 2006 with corrections to the Cover Date.     

Isozyme patterns in zygotic and somatic embryogenesis of carrot

Isozyme patterns of carrot (Daucus carota L.) zygotic embryos between the torpedo stage up to 5-day-old seedlings have been compared with those of the similar stages from the embryogenic cell suspension culture to the late somatic plantlet. Somatic embryos blocked at the torpedo stage by -cyclodextrine have also been analyzed. All these stages have been analyzed with respect to seven different enzyme systems: arylesterase, glucosephosphate isomerase, phosphogluconate dehydrogenase, alcohol dehydrogenase, isocitrate dehydrogenase, aspartate aminotransferase and phosphoglucomutase (EC 2.7.5.1, PGM). The relationships between the different stages of both types of embryogenesis have been visualized using an unrooted tree. Generally, profiles of somatic embryos were different from those of zygotic embryos. Interestingly however, a typical zygotic embryo pattern was found in the cyclodextrine-blocked somatic embryos. Only aspartate aminotransferase patterns revealed a similarity between zygotic and somatic torpedo embryos. Both plantlet types showed close patterns with common isozymes. Moreover, similarities were evident between somatic plantlets and cell suspensions. A few isozymes appeared to be stage specific markers: esterase 10–11 were specific to achenes and early germination, phosphogluconate dehydrogenase 8 was specific to 4–5 day-old seedlings and phosphoglucomutase 1 and 7 and alcohol dehydrogenase 4 were markers for zygotic embryos. No somatic embryogenesis specific isozyme could be found. We show that patterns can be associated with particular tissue formation: mainly, aspartate aminotransferase 2 and 1, phosphoglucomutase 8 and 9 and phosphogluconate dehydrogenase 7 coincided with apical meristem initiation and phosphoglucomutase 4 and 5, zones b and d of esterase and zone b of phosphogluconate dehydrogenase coincided with vascular bundle formation.Abbreviations ADH alcohol dehydrogenase - CD -cyclodextrine - CS cell suspension culture - 2,4-D 2,4-dichlorophenoxyacetic acid - EDTA ethylenediaminetetraaeetie acid - LiBo lithium hydroxide/boric acid - PEG polyethylene glycol - PVP polyvinylpyrrolidone - SEg somatic embryo at the globular stage - SEh heart stage - SEte early torpedo stage - SEtl late torpedo stage - SEce early cotyledonary stage - SEcl late cotyledonary stage - SECD somatic embryo blocked at the torpedo stage with -cyclodextrine - EST esterase - GOT aspartate aminotransferase - IDH isocitrate dehydrogenase - MTT 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazolium bromide) - PMS phenazonium methosulfate - PGD phosphogluconate dehydrogenase - PGI glucosephosphate isomerase - PGM phosphoglucomutase - SO dry seed - S1–3 seed after 1–3 days of germination - SP1–2 young and old somatic plantlets - ZE zygotic embryo - ZP4–5 4–5 day-old seedlings     

Role of permanent dicentric systems in carrot somatic embryogenesis

Summary A permanent dicentric chromosome system was studied on carrot cultures and regenerated somatic embryos at different stages of development. The large chromosomal variability of the cultures and the presence of the breakage-fusion bridge cycle did not interfere with the initial developmental process up to the seedling stage but subsequent growth proceeded only if healing of the broken ends or dicentric loss had occurred. The behaviour of the dicentric chromosome in culture and during somatic embryogenesis is discussed in relation to chromosomal variability, abnormal development and the somaclonal variation that such mechanisms may generate in regenerated plants.     

AtLTP1 luciferase expression during carrot somatic embryogenesis

The carrot (Daucus carota L.) EP2 gene encodes a Lipid Transfer Protein (LTP) which is expressed during protoderm formation in developing embryos. To develop a vital reporter system for gene expression during somatic embryo development a 1.1 kB fragment of the Arabidopsis thaliana LTP1 promoter was fused to the firefly luciferase (LUC) coding sequence. The AtLTP1 luciferase expression pattern in transformed carrot suspension cultures was identical to the expression pattern of the endogenous carrot EP2 gene. Cell tracking experiments revealed that all somatic embryos were derived from AtLTP1 luciferase expressing cell clusters. However, not all cell clusters that expressed the AtLTP1 luciferase reporter gene developed into a somatic embryo, suggesting that initiation of an embryogenic pathway in tissue culture does not always lead to development of a somatic embryo.     

Synchronization of carrot cell culture by starvation and cold treatment

When a suspension culture of carrot cells in the early stationary phase was allowed to stand at 4 °C for 72 h, the cell population was partially synchronized in relation to their division cycle. Judging from a pattern of increase of cell number, two steps in the cell cycle are thought to be sensitive to these treatments. When an additional cold treatment was applied to the culture, degree of synchronization was markedly increased. Protein content in a synchronized culture increased in a stepwise fashion as well as DNA while RNA increased continuously.     

Synchronization of somatic embryogenesis from carrot cells at high frequency as a basis for the mass production of embryos

Synchronization of somatic embryogenesis at high frequency is a useful system for the mass production of embryos. Many attempts have been carried out, however, it was difficult to obtain the system in which most of the initial embryogenic cells or cell clusters synchronously differentiate to embryos. In carrot suspension cultures, high frequency, synchronous embryogenesis systems (following three systems) have been established.(1) Small spherical single cells from suspension cultures obtained by sieving and density gradient centrifugation in Percoll solutions differentiated to embryogenic cell clusters at high frequency when they were cultured in a medium containing 2,4-dichlorophenoxyacetic acid (0.05 micromolar), zeatin (1 micromolar) and mannitol (0.2 molar). (2) Embryogenic cell clusters from suspension cultures obtained by sieving, density gradient centrifugation in Ficoll solutions, and subsequent centrifugation at a low speed for a short time synchronously differentiated to embryos, especially globular embryos at high frequency, when they were cultured in a medium containing zeatin (0.1 micromolar) but no auxin. (3) Embryogenic cell clusters obtained by above method are cultured at cell densities of 2×10³ cell clusters ml^-1. Globular embryos which were sieved from embryos induced synchronously differentiated to torpedo-shaped embryos at high frequency when they were cultured at densities below 150 globular embryos ml^-1.Using these systems, the whole process of embryogenesis from single cells to whole plants could be synchronously induced at high frequency.Abbreviations ABA abscissic acid - 2,4-d 2,4-dichlorophenoxyacetic acid - GA₃ gibberellin A₃ - IAA indoleacetic acid - NAA naphthylacetic acid