Somatic embryo development in carrot is associated with an increase in levels of S-adenosylmethionine,S-adenosylhomocysteine and DNA methylation

Almost homogeneous populations representing different developmental stages of somatic embryos (globular, torpedo-shaped, plantlets) and vacuolated cells were obtained from a cell suspension culture of carrot. The concentrations of S-adenosylmethionine (SAM), S-adenosylhomocysteine (SAH) and methylated DNA were determined in embryos at different developmental stages and were found to increase during somatic embryogenesis. The highest increase during embryogenesis was a 5-fold increase in the level of SAM. A considerable increase in the methylation index (SAM/SAH ratio) was also found. We propose that the levels of SAM and SAH may be involved in the control of somatic embryogenesis by affecting the level of DNA methylation, which in turn might cause differential changes in gene activation. An increase in the level of SAM may be a prerequisite for progression of embryogenesis and the development of complete embryos.     

Low external pH prevents cell elongation but not multiplication of embryogenic carrot cells

Embryogenic cultures of cultivated carrot ( Daucus crota cv. Scarlet Nantes) were initiated from seedling hypocotyls on hormone-containing nutrient medium and from wounded zygotic embryos on hormone-free medium. Both of these cultures were maintained with continuous multiplication as unorganized, embryogenic cell masses on hormone-free medium at pH 4.0, containing NH⁺₄ as the sole nitrogen source. When grown on hormone-free medium at pH 4.0, neither culture contained any elongated cells. Virtually all cells were densely cytoplasmic and nearly spherical. Some cells were enlarged, not densely cytoplasmic, but always spherical. When either culture was transferred to an auxin-containing medium at pH 5.8, numerous elongated cells were produced. Elongated cells were observed when either naphthaleneacetic acid or 2,4-dichlorophenoxyacetic acid was used, and whether the nitrogen source was NH⁺₄ alone or a combination of NH⁺₄ and NO⁻₃. Elongated cells were more abundant when a combined nitrogen source was used. When cultures containing elongated cells were transferred to and multiplied on hormone-free or hormone-containing medium buffered at pH 4.0, all elongated cells disappeared after 2 weeks. No elongated cells were observed in any of the lines tested at pH 4.0. These results clearly show that it was the pH of the culture medium and not the presence or absence of an auxin or the nitrogen source(s) that permitted or prevented cell elongation in the embryogenic cultures tested.     

Morphogenetic and Histological Events during Somatic Embryogenesis in Intact Carrot Plantlets (Daucus carota L.) in Various Nutrient Media

It is shown that the induction of somatic embryogenesis neither requires the isolation of explants from intact carrot plants nor mechanical or chemical “wounding”.     

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.     

Evidence for phosphorylation of tubulin in carrot suspension cells

Two-dimensional gels of phosphoproteins from carrot ( Daucus carota L. var. Juwarot) suspension cells labeled in vivo or in vitro revealed phosphoproteins that comigrate with carrot tubulin. A polyclonal antiserum to hibiscus tubulin immunoprecipitated an in vivo labeled phosphoprotein of 50 kDa. Cell-free extracts of carrot suspension cells phosphorylated both purified carrot and bovine brain tubulins in the presence of gamma-labeled adenosine triphosphate. This tubulin phosphorylating activity was reduced 2-fold in extracts from globular stage embryos and approximately 10-fold in extracts from heart/torpedo stage embryos. These data suggest that carrot cells phosphorylate tubulin, and that tubulin phosphorylating activity may be developmentally regulated     

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.     

Low external pH replaces 2,4-D in maintaining and multiplying 2,4-D-initiated embryogenic cells of carrot

A mixed culture comprised of both embryonic globules and nonembryogenic callus. was derived from seedling hypocotyls of Daucus carota cv. Scarlet Nantes on 2,4-D-containing medium using well-established methods. Then the mixed cultures were transferred to, and serially subcultured on, a hormone-free medium near pH 4. The medium contained 1 m M NH+ as the sole nitrogen source. When cultured in this way, embryonic globules were able to multiply without development into later embryo stages Nonembryogenic callus did not survive. Continuous culture of embryonic globules on this low pH hormone-free medium yielded cultures consisting entirely of preglobular stage proembryos (PGSPs). PGSP cultures have been maintained as such with continuous multiplication for nearly 2 years without loss of embryogenic potential. These hormone-free-maintained PGSPs continue their development to later embryo stages when cultured on the same hormone-free medium buffered at pH 5.8. We show that hormone-free medium near pH 4 can replace 2.4-D in its ability to sustain multiplication of 2,4-D-initiated embryogenic cells of carrot at an acceptable growth rate without their development into later embryo stages. This procedure provides selective conditions that do not permit the growth of nonembryogenic cells while providing an adequate environment for embryogenic cell proliferation and should prove invaluable in studying habituation.     

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.     

Transient reduction in secreted 32 kD chitinase prevents somatic embryogenesis in the carrot (Daucus carota L.) variant ts11

At the nonpermissive temperature, somatic embryos of the temperature-sensitive (ts) carrot (Daucus carota L.) cell variant ts11 only proceed beyond the globular embryo stage in the presence of medium conditioned by wild-type cells. The causative component in the conditioned medium has been identified as an acidic 32 kD endochitinase. An antiserum raised against the 32 kD chitinase detected this protein in culture medium from ts11 embryo cultures grown at the permissive temperature as well as at the nonpermissive temperature. No difference in biochemical characteristics or in effect on ts11 embryo development could be detected between the 32 kD chitinase purified from wild-type cultures and the chitinase from ts11 cultures grown at the permissive or at the nonpermissive temperature. Compared to the amount present in a ts11 embryo culture at the permissive temperature, a reduction in the amount of 32 kD chitinase was observed during the temperature-sensitive period at the nonpermissive temperature. These results imply that the arrested embryo phenotype of ts11 is not the result of a structural difference in its 32 kD chitinase, but is the result of a transient decrease in the amount of 32 kD chitinase present. Morphological observations indicate that the ts11 phenotype is pleiotropic and also affects the cell wall of nonembryogenic cells. © 1995 Wiley-Liss, Inc.     

Protease activities in non-embryogenic and embryogenic carrot cell strains during callus growth and embryo formation

Embryogenic and non-embryogenic cell strains of Daucus carota L. were examined for their protease activity using a wide range of chromogenic synthetic peptides as substrates. High arginine-specific activity was present in all strains, but no protease activity "specific" for embryogenic or non-embryogenic strains could be detected with the substrates tested. The specific protease activity was 5–10 times higher in the non-embryogenic as compared to the embryogenic strain for most tested substrates, and this difference was not due to release of proteases in the latter. All strains showed a decrease in protease activity when cultured in media without 2,4-dichlorophenoxyacetic acid, but the embryos had high protease activity in comparison with the nondifferentiated cell aggregates. In the latter aggregates, hydrolyzing activity towards three of the substrates (H-D-Phe-Pip-Arg- p -nitroanilide, Suc-Ala-Pro-Phe- p -nitro-anilide and Bz-Phe-Val-Arg- p -nitroanilide) was absent, whereas the embryos were able to hydrolyze them.     

Artificial seeds of alfalfa (Medicago sativa L.). Induction of desiccation tolerance in somatic embryos

Summary The use of somatic embryos from cell culture systems in the clonal propagation of plants would be greatly facilitated if the somatic embryos could be dried and stored in a dormant state similar to true seeds. A cell culture system was developed for alfalfa (Medicago sativa L.) line RL34 which gave high yields of somatic embryos in an approximately synchronized pattern. These somatic embryos were treated with abscisic acid (ABA) at the cotyledonary stage of development to induce desiccation tolerance. With no visual preselection, approximately 60% of the dried embryos converted into plants upon reimbibition. When high quality embryos were selected prior to drying, 90 to 100% conversion rates were observed. The timing of the application of ABA in terms of embryo development was critical with an optimum being at cotyledonary stage spanning approximately 4 days; thus, synchronized embryo development is required for optimal expression in bulk samples. The vigor of the seedlings from dried somatic embryos was greater than those from embryos which had not been dried, but remained substantially lower than those from true seeds.     

Optimization of culture medium extends response time of embryogenic carrot cells but does not restore initial high response of young cultures

The greatest number of embryos was obtained using young carrot callus cultured on Gamborg's B-5 medium containing 1 g l-1 casein hydrolysate and 10 -10 M 2,4-dichlorophenoxyacetic acid. The largest increase in embryogenesis for old cultures also was obtained using Gamborg's B-5 medium supplemented with 1 g l-1 casein hydrolysate and 10 -10 M 2,4-dichlorophenoxyacetic acid; however, no combination of factors for the older culture restored the initial vigorous morphogenetic response seen in young cultures. This revised version was published online in June 2006 with corrections to the Cover Date.     

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.     

胡萝卜精、卵细胞、助细胞和中央细胞的分离

用两个解剖针挤压胡萝卜花粉使其破裂释放出精细胞。用酶解-解剖方法分离胡萝卜胚囊中的卵细胞、助细胞和中央细胞。胡萝卜胚珠先在酶液中酶解40~50min,然后将其转移到不含酶的分离液中用解剖针解剖胚珠。将胚珠的合点端切破,轻轻挤压胚珠的珠孔,卵细胞、助细胞和中央细胞即可逸出。在最佳条件下,20min可从20个胚珠中分离出5个卵细胞。对分离胚囊细胞的渗透压和酶液成分进行了筛选。分离出的卵细胞用显微操作仪收集。胡萝卜精、卵细胞的成功分离为在双子叶植物中进行离体受精探索创造了条件。     

Population and biomass kinetics in fed-batch cultures of Daucus carota L. somatic embryos

The population dynamics of developing somatic embryos of carrot (Daucur carota L.) was investigated in batch and fed-batch cultures using modified Murashige and Skoog medium. These substrate limitations coincided not only with stoppage of biomass increase, but also with the increase in total concentration of embryos as well as the advancement of the embryo into a more mature stage. Both glucose and ammonium were depleted from the culture. Restoring either glucose, or ammonium and nitrate, as to approximately initial concentrations in fed-batch experiments, did not result in a significant increase of the total normal embryo concentration. On the other hand, medium replacement led to increase in biomass concentration, total embryo number, and improved embryo maturity. The addition of a mixture of glucose, ammonium, and nitrate to the spent medium resulted in variable increases in biomass and embryo number, but always less than those resulting from media replacement. Although the total number of embryos was higher after medium replacement, the fraction of embryos reaching torpedo stage was still only 50%. The need for a better means of population characterization for further kinetic studies is discussed. (c) 1993 Wiley & Sons, Inc.