Somatic embryogenesis in Encephalartos cycadifolius

Callus cultures of Encephalartos cycadifolius were established from zygotic embryo explants on a modified B5 medium containing 1 mg l^–1 2,4-D and 1 mg l^–1 kinetin. Callus was transferred to media containing various combinations of 2,4-D and kinetin for improvement of somatic embryogenesis. Somatic embryos were produced on media with several growth regulator combinations. The somatic embryos developed from proembryos, which developed long suspensors. A dicotyledonary embryo formed at the distal end of the suspensor. The embryos turned green in light. When transferred to a medium containing 1 mg l^–1 ABA the somatic embryos matured. The suspensors desiccated and these embryos rooted when transferred to a medium without phytohormones.Abbreviations ABA abscisic acid - 2,4-D 2,4-dichlorophenoxyacetic acid     

Developmental pathway of somatic embryogenesis in Picea abies as revealed by time-lapse tracking

Several coniferous species can be propagated via somatic embryogenesis. This is a useful method for clonal propagation, but it can also be used for studying how embryo development is regulated in conifers. However, in conifers it is not known to what extent somatic and zygotic embryos develop similarly, because there has been little research on the origin and development of somatic embryos. A time-lapse tracking technique has been set up, and the development of more than 2000 single cells and few-celled aggregates isolated from embryogenic suspension cultures of Norway spruce (Picea abies L. Karst.) and embedded in thin layers of agarose has been traced. Experiments have shown that somatic embryos develop from proembryogenic masses which pass through a series of three characteristic stages distinguished by cellular organization and cell number (stages I, II and III) to transdifferentiate to somatic embryos. Microscopic inspection of different types of structures has revealed that proembryogenic masses are characterized by high interclonal variation of shape and cellular constitution. In contrast, somatic embryos are morphologically conservative structures, possessing a distinct protoderm-like cell layer as well as embryonal tube cells and suspensor. The lack of staining of the arabinogalactan protein epitope recognized by the monoclonal antibody JIM13 was shown to be an efficient marker for distinguishing proembryogenic masses from somatic embryos. The vast majority of cells in proembryogenic masses expressed this epitope and none of cells in the early somatic embryos. The conditions that promote cell proliferation (i.e. the presence of exogenous auxin and cytokinin), inhibit somatic embryo formation; instead, continuous multiplication of stage I proembryogenic masses by unequal division of embryogenic cells with dense cytoplasm is the prevailing process. Once somatic embryos have formed, their further development to mature forms requires abscisic acid and shares a common histodifferentiation pattern with zygotic embryos. Although the earliest stages of somatic embryo development comparable to proembryogeny could not be characterized, the subsequent developmental processes correspond closely to what occurs in the course of early and late zygotic embryogeny. A model for somatic embryogenesis pathways in Picea abies is presented.     

The ultrastructure of somatic embryo development in pearl millet (Pennisetum glaucum; Poaceae)

The ultrastructure, morphology, and histology of somatic embryogenesis in pearl millet (Pennisetum glaucum) were examined using light and electron microscopic techniques. Somatic embryogenesis was initiated from zygotic embryo explants cultured 8 d after pollination. Formation of a ridge of tissue began 3–4 d after culture (DAC) by divisions in the epidermal and subepidermal cells of the scutellum. Ridge formation was accompanied by a decrease in vacuoles, lipid bodies, and cell size, and an increase in endoplasmic reticulum (ER). Proembryonic cell masses (proembryoids) formed from the scutellar ridge by 10 DAC. Proembryoid cells had abundant Golgi bodies and ER while the amounts of lipids and starch varied. Somatic embryos developed from the proembryonic masses 13 DAC and by 21 DAC had all the parts of mature zygotic embryos. Although shoot and root primordia of somatic embryos were always less differentiated than those of zygotic embryos, scutellar cells of somatic and zygotic embryos had similar amounts of lipids, vacuoles, and starch. Somatic scutellar epidermal cells were more vacuolated than their zygotic counterparts. In contrast, somatic scutellar nodal cells were smaller and not as vacuolated as in zygotic embryos. Somatic embryogenesis was characterized by three phases of cell development: first, scutellar cell dedifferentiation with a reduction in lipids and cell and vacuole size; second, proembryoid formation with high levels of ER; and third, the development of somatic embryos that were functionally and morphologically similar to zygotic embryos.     

Histological comparison of single somatic embryos of maize from suspension culture with somatic embryos attached to callus cells

An embryogenic suspension culture of Zea mays, genotype 4C1, was obtained from friable callus that was cultured on solid medium and had been obtained from zygotic embryos. The suspension contained non-dividing elongated cells, clusters of dividing isodiametric cells, and globular, ovoid, and polar stages of somatic embryos. The single somatic embryos were blocked in shoot meristem formation: when transferred to regeneration medium they developed a root and, at the shoot side, a green cap with meristematic cells, but a scutellum and leaf primordia were not formed. In medium containing 2,4-dichlorophenoxy acetic acid, somatic embryos formed embryogenic callus aggregates, consisting of globular stage somatic embryos attached to each other via undifferentiated callus cells. These somatic embryos developed into mature embryos with the zygotic histological characteristics, such as scutellum and leaf primordia, in maturation medium, and then regenerated into plants in regeneration medium. By omitting the maturation phase, regeneration occurred via organogenesis. Polyembryos, i. e. embryos attached to each other without callus tissue in between, behaved as single somatic embryos. It is concluded that the attached callus tissue provides a factor that stimulates scutellum and leaf primordia formation.Abbreviations CMM callus maintenance medium - 2,4D 2,4-dichlorophenoxy acetic acid - PCV packed cell volume - MS Murashige and Skoog medium     

Ultrastructural Studies of Somatic Embryos of Eucalyptus nitens and Comparisons with Zygotic Embryos Found in Mature Seeds

Although somatic embryogenesis has been observed in tissuesfrom a limited number of Eucalyptus species cultured in vitro,no comparisons have been made of the morphology and structureof eucalypt somatic embryos and zygotic embryos found in matureseeds. We used scanning and transmission electron microscopy,in conjunction with histological analysis, to compare maturezygotic embryos with somatic embryos of the commercially-importanttemperate eucalypt Eucalyptus nitens. Apart from differencesin the nature of the outer coating enclosing both embryo types,somatic embryos of E. nitens were observed to have strong similaritieswith zygotic embryos in seeds in terms of their overall size,morphology and internal cellular organization. Many cells inboth sexually-produced and somatic embryos contained numerouslipid-rich globular bodies. The wider significance of theseobservations is discussed with regard to their potential applicationsin eucalypt plantation biotechnology programmes. Copyright 2000Annals of Botany Company Eucalyptus nitens, shining gum, somatic embryo, tissue culture, ultrastructure, zygotic embryo     

Imbibition of white spruce seeds and somatic embryos: A study of morphological changes in an environmental scanning electron microscope and potassium leakage

Summary Potassium leakage and morphological changes during imbibition of white spruce [Picea glauca (Moench) Voss] seeds and somatic embryos were investigated. A single desiccated somatic embryo, a single somatic embryo exposed to a high relative humidity environment for 2 d, and a single dry zygotic embryo leaked similar amounts of potassium over a 120-min period of imbibition in liquid germination medium. A seed without a seed coat leaked two and eight times more potassium than a single whole seed and a single zygotic embryo, respectively. Nearly 50% of the potassium leaked for all tissues was leaked within the first 20 min of imbibition. Exposure of somatic embryos to an environment with high relative humidity resulted in a reduction in the percentage of potassium leaked after 80 and min to levels equivalent to those for zygotic embryos. Using an environmental scanning electron microscope, we found that desiccated somatic embryos and dry zygotic embryos had wrinkled surface cells, with cells in the surface of zygotic embryos being more shrunken in appearance. Imbibition of both types of embryos in water resulted in turgid surface cells after 2 h. Imbibition in liquid germination medium did not cause much hydration of surface cells, which still had wrinkled appearances after 2 h. Finally, imbibition on filter paper on semisolidified germination medium resulted in slower hydration of somatic and zygotic embryos. Cells near the medium appeared hydrated while cotyledon surface cells furthest from the medium resembled cells in desiccated embryos.     

Development of white spruce somatic embryos: II. Continual shoot meristem development during germination

Summary This study compares the development of shoot apical meristems of white spruce somatic and zygotic embryos during germination. In mature somatic embryos, the functional part of the shoot apical meristem was bi-layered. After partial drying, a normal shoot meristem was formed from these two cell layers during germination. Other cells within the meristem were vacuolated and separated by intercellular air spaces. In the absence of the partial drying treatment, somatic embryos enlarged in size primarily due to vacuolation of cells and the formation of large intercellular air spaces. A majority of these somatic embryos failed to form a functional shoot apical meristem. Compared with somatic embryos, the shoot apical meristem of a mature zygotic embryo was well organized with a densely cytoplasmic apical layer. The cells within the meristem were tightly packed. Judging from the cell profiles during germination, all cells within the meristem of the zygotic embryo took part in the formation of the vegetative shoot apical meristem.     

In vitro plant regeneration from immature zygotic embryos and repetitive somatic embryogenesis in kohlrabi (Brassica oleracea var. gongylodes)

A simple and efficient protocol for direct somatic embryogenesis and plant regeneration of kohlrabi (Brassica oleracea var. gongylodes) was developed. Somatic embryos were induced from immature zygotic embryos at different developmental stages cultured on Murashige and Skoog medium supplemented with 0, 0.5, 1.0, or 1.5 mg/l 2,4-dichlorophenoxyacetic acid. Zygotic embryos at the early cotyledonary stage, which were cultured for 4 wk on plant growth regulator-free (PGR-free) medium, displayed the highest percentage of somatic embryogenesis (80.7%). Embryogenic tissue could be subcultured on the same medium for over 1 yr. Embryogenic lines derived from early cotyledonary stage zygotic embryos displayed the highest intensity of secondary embryogenesis (highest mean number of new somatic embryos per responsive somatic embryo explant). Histological analyses confirmed the direct origin of the secondary somatic embryos. Prolonged culturing of embryogenic tissue on PGR-free medium led to somatic embryo development into plantlets that were successfully acclimated in the greenhouse with a survival rate of 72.5%. Flow cytometry analysis showed no ploidy variation in 96.7% of the acclimated plants.     

Development of white spruce somatic embryos: I. Storage product deposition

Summary The growth and development of white spruce somatic embryos was followed from the filamentous immature to the mature cotyledonary embryo stage. Histochemical examination of the various stages of embryo development showed that lipids, proteins, and polysaccharides were produced to varying degrees during the process. During early stages (1 to 2 wk on ABA), mostly polysaccharide was produced, whereas during later stages, polysaccharides, lipids, and protein accumulated. Electron microscopy indicated that lipid deposition in somatic embryos started during the first week after transfer to ABA-containing medium. Deposition of the storage products began at the basal end of the embryonal mass and within the proximal zone of the suspensors. Accumulation continued to the peripheral regions and then inward toward the cortex of the developing embryo. In all cases, polysaccharide accumulated first, followed by lipid and lastly, protein. Quantitatively, cotyledonary stage somatic embryos had less lipid and protein and more starch when compared to zygotic embryos at the same developmental stage. Total protein profiles elucidated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the majority of proteins were similar in zygotic and somatic embryos. Prominent protein bands were found at 30, 20, 19.5, 15, 14.4, 12, and 10 Kd. However, protein bands at 40, 15, and 12 Kd in total protein from somatic embryos were either absent or highly underexpressed.     

Improved plantlet regeneration from open-pollinated families of <Emphasis Type="Italic">Abies alba</Emphasis> trees of Dobroč primeval forest and adjoing managed stand via somatic embryogenesis

Possibility to improve plantlet regeneration from Abies alba Mill. open-pollinated families of 4 trees in Dobroč primeval and 3 trees in managed forest was studied. Immature zygotic embryos were cultured in order to obtain initiation of embryogenic tissue. Totally, three from the families of the managed forest (57%) and two from the primeval families (50%) responded to initiation condition. Initiation frequencies among families ranged in managed forest: 4.5–56.2%, primeval: 5.4–16.8%. Maturation ability was shown by 77.3% of the primeval cell lines, 36.4% cell lines produced cotyledonary somatic embryos. In managed forest, in 62.5% of the cell lines embryo maturation was observed. Cotyledonary embryos developed only in 15% of cell lines. Regenerants were obtained from 9 cell lines of primeval and from 6 cell lines of managed forest. Biochemically, the mature somatic embryos were characterized by the variation in soluble and protein profiles. The corresponding profiles of insoluble proteins exhibited uniform pattern. The variation was characteristic for somatic embryos of individual cell lines rather than for the primeval and managed stands. Enzymatically, no indications were obtained supporting higher metabolic potential of somatic embryos derived from zygotic embryos of silver fir primeval stand than in somatic embryos originating from the trees of managed stand.     

Comparison between somatic and zygotic embryo development in Quercus robur L.

ABSTRACT

Somatic embryogenesis from juvenile explants as an efficient way for oak clonal propagation is drastically limited by the low rate of embryo germination. A comparison of the development of immature somatic and zygotic embryos, and a study of the changes in sugar content and lignin accumulation during somatic versus zygotic embryo development were conducted in view of understanding the effect of reserve substance deficiency upon somatic embryo maturation. A morphological comparison of somatic and zygotic embryos led to the identification of 4 to 7 similar developmental stages in both types of embryos, thus indicating that the accumulation phase in both zygotic and somatic embryos occurs at the same stage, when the cotyledons became thicker and opaque. Carbohydrate analysis showed the presence of glycerol, inositol, mannitol, galactose, trehalose, xylose, arabinose, glucose, fructose and sucrose in all stages of zygotic and somatic embryo development, but in different amounts. The amount of glycerol, inositol, glucose and sucrose during the early stages is larger in zygotic embryos than in somatic ones, but the time course of their accumulation is similar in both types of embryos. Lignin content, which increased continuously during development, showed a similar behaviour in zygotic and somatic embryos. In somatic embryos which were able to germinate, lignin content was higher than in nongerminating embryos at the same stage.     

Changes in soluble carbohydrates and starch amounts during somatic and zygotic embryogenesis of Acca sellowiana (Myrtaceae)

Comparative analysis of zygotic and somatic embryogenesis of Acca sellowiana showed higher amounts of sucrose, fructose, raffinose, and myo-inositol in zygotic embryos at different developmental stages than in corresponding somatic ones. These differences were mostly constant. In general, glucose levels were significantly lower than the other soluble carbohydrates analyzed, showing minor variation in each embryo stage. Despite the presence of sucrose in the culture medium, its levels conspicuously diminished in somatic embryos compared with the zygotic ones. Raffinose enhanced parallel to embryo development, regardless of its zygotic or somatic origin. Analysis of the soluble carbohydrate composition of mature zygotic cotyledon used as explant pointed out fructose, glucose, myo-inositol, sucrose, and raffinose as the most important. Similar composition was also found in the corresponding somatic cotyledon. Total soluble carbohydrates varied inversely, decreasing in zygotic embryos and increasing in somatic embryos until the 24th d, at which time they increased rapidly about sixfold in zygotic embryos until the 27th d, a period coinciding with the zygotic proembryos formation. Such condition seems to reflect directly the variation of endogenous sucrose level, mainly because glucose and fructose diminished continuously during this time period. This means that, in terms of soluble sugars, zygotic embryo formation occurred under a situation represented by high sucrose amounts, simultaneously with low fructose and glucose levels, while in contrast, somatic embryo formation took place under an endogenous sugar status characterized by a substantial fructose enhancement. Starch levels increased continuously in zygotic embryos and decreased in somatic ones, the reverse to what was found in fructose variation. Starch accumulation was significantly higher in somatic torpedo and cotyledonary embryos than in the corresponding zygotic ones.     

A hormonal misunderstanding in Acca sellowiana embryogenesis: levels of zygotic embryogenesis do not match those of somatic embryogenesis

Endogenous levels of IAA, ABA and four types of CKs were analyzed in zygotic and indirect (ISE) and direct somatic embryogenesis of Acca sellowiana. Zygotic and somatic embryos at different developmental stages were sampled for morphological and hormonal analysis. Both embryo types showed substantial asymmetry in hormone levels. Zygotic embryos displayed a conspicuous peak of IAA in early developmental stages. The results outlined the hormonal variations occurring during zygotic and somatic embryogenesis regarding the timing, nature and hormonal status involved in both processes. The short transient pulse of IAA observed on the 3rd day in culture was suggested to be involved with the signaling for the induction of somatic embryogenesis. Fertilized ovule development was associated with increased IAA levels 21?C24?days after pollination, followed by a sharp decrease in the cotyledonary stage, both in zygotic and somatic embryos. There was a prominent increase in ABA levels in cultures which generated ISE 24?C30?days after pollination, a period that corresponds to the heart and torpedo stages. The levels of total CKs (Z, [9R]Z, iP and [9R]iP) were also always higher in zygotic than in somatic embryogenesis. While zygotic embryogenesis was dominated by the presence of zeatin, the somatic process, contrarily, was characterized by a large variation of the other cytokinin forms and amounts studied. The above results, when taken together, could be related to the previously observed high frequency formation of anomalous somatic embryos formed in A. sellowiana, as well as to their low germination ability.     

Distribution and changes of reserve materials in cotyledon cells of Panax ginseng related to direct somatic embryogenesis and germination

Cotyledon explants from zygotic embryos of Panax ginseng produced somatic embryos on Murashige and Skoog basal medium without growth regulators. Somatic embryos developed directly from epidermal cells at the cotyledon base. Somatic embryos were always formed from the side of the cotyledon opposite to the one attached to the medium surface regardless of cotyledon orientation. The frequency of somatic embryo formation from the abaxial epidermis (66%) was much higher than that from the adaxial epidermis (12%). Differences in embryogenic response were likely related to cell structure. Abaxial epidermal cells were filled with reserve materials (lipid bodies), while adaxial epidermal cells were devoid of any prominent reserves. During germination, the reserve materials in the cells of the cotyledons disappeared rapidly. At the same time, the competency of somatic embryo formation from cotyledon explants declined rapidly to zero. Upon culture of the cotyledon explants (for somatic embryo induction), lipid bodies slowly disappeared, but starch grains accumulated prominently. Reserve materials disappeared after commencement of embryogenic cell division. During germination, lipid bodies rapidly disappeared, and chloroplasts developed instead of starch grains. Received: 29 January 1997 / Revised version received: 16 April 1997 / Accepted: 9 May 1997     

Patterns of storage protein and triacylglycerol accumulation during loblolly pine somatic embryo maturation

Conifer somatic embryo germination and early seedling growth are fundamentally different than in their zygotic counterparts in that the living maternal megagametophyte tissue surrounding the embryo is absent. The megagametophyte contains the majority of the seed storage reserves in loblolly pine and the lack of the megagametophyte tissue poses a significant challenge to somatic embryo germination and growth. We investigated the differences in seed storage reserves between loblolly pine mature zygotic embryos and somatic embryos that were capable of germination and early seedling growth. Somatic embryos utilized in this study contained significantly lower levels of triacylglycerol and higher levels of storage proteins relative to zygotic embryos. A shift in the ratio of soluble to insoluble protein present was also observed. Mature zygotic embryos had roughly a 3:2 ratio of soluble to insoluble protein whereas the somatic embryos contained over 5-fold more soluble protein compared to insoluble protein. This indicates that the somatic embryos are not only producing more protein overall, but that this protein is biased more heavily towards soluble protein, indicating possible differences in metabolic activity at the time of desiccation.     

Lipid composition of somatic and zygotic embryos from Prunus avium. Effect of a cold treatment on somatic embryo quality

In order to evaluate the quality of Prunus avium somatic embryos, a comparison of lipid composition between somatic and zygotic embryos was undertaken. In both zygotic and somatic embryos, neutral glycerolipids (NL) and phosphatidylcholine (PC) were the 2 major lipid classes. The content of NL increased over the course of development in zygotic embryos and reached 490 μg per embryo, while the PC content reached 100 μg per embryo. However, the contents of NL and PC in somatic embryos were similar to immature zygotic embryos at stage 3. Fatty acid composition of NL from both zygotic and somatic embryos revealed more unsaturated than saturated fatty acids. In somatic embryos, the saturated/unsaturated fatty acid ratios of NL and phosphatidylinositol (PI) were similar to those observed in immature zygotic embryos up to stage 6. Conversely, in phosphatidylethanolamine (PE) the ratio was similar to the ratio observed in mature zygotic embryos, at stage 7. Histological studies confirmed the immaturity of somatic embryos: no protein or lipid reserves were observed in the vacuolated cotyledonary cells. Maturation of somatic embryos was improved by a 2-month cold period. In cold-treated somatic embryos, both NL and PC increased to levels comparable to those observed in mature zygotic embryos, and the PE content reached 10 times the level of that in mature zygotic embryos. The cold treatment induced a large increase in the saturated/unsaturated fatty acid ratio in phospholipids but only a slight increase in that of neutral glycerolipids. Histological studies revealed a lipid accumulation at cellular level. Lipid bodies surrounded by protein bodies were observed in cotyledonary cells of cold-treated somatic embryos. Furthermore, the cold-treated somatic embryos developed into plantlets with a frequency of 14%, whereas no development was obtained with the non-treated somatic embryos.     

Effect of light conditions on anatomical and biochemical aspects of somatic and zygotic embryos of hybrid larch (Larix?×?marschlinsii)

Background and Aims In conifers, mature somatic embryos and zygotic embryos appear to resemble one another physiologically and morphologically. However, phenotypes of cloned conifer embryos can be strongly influenced by a number of in vitro factors and in some instances clonal variation can exceed that found in nature. This study examines whether zygotic embryos that develop within light-opaque cones differ from somatic embryos developing in dark/light conditions in vitro. Embryogenesis in larch is well understood both in situ and in vitro and thus provides a suitable system for addressing this question.Methods Features of somatic and zygotic embryos of hybrid larch, Larix × marschlinsii, were quantified, including cotyledon numbers, protein concentration and phenol chemistry. Somatic embryos were placed either in light or darkness for the entire maturation period. Embryos at different developmental stages were embedded and sectioned for histological analysis.Key Results Light, and to a lesser degree abscisic acid (ABA), influenced accumulation of protein and phenolic compounds in somatic and zygotic embryos. Dark-grown mature somatic embryos had more protein (91·77 ± 11·26 µg protein mg^–1 f.wt) than either dark-grown zygotic embryos (62·40 ± 5·58) or light-grown somatic embryos (58·15 ± 10·02). Zygotic embryos never accumulated phenolic compounds at any stage, whereas somatic embryos stored phenolic compounds in the embryonal root caps and suspensors. Light induced the production of quercetrin (261·13 ± 9·2 µg g^–1 d.wt) in somatic embryos. Mature zygotic embryos that were removed from seeds and placed on medium in light rapidly accumulated phenolics in the embryonal root cap and hypocotyl. Delaying germination with ABA delayed phenolic compound accumulation, restricting it to the embryonal root cap.Conclusions In larch embryos, light has a negative effect on protein accumulation, but a positive effect on phenol accumulation. Light did not affect morphogenesis, e.g. cotyledon number. Somatic embryos produced different amounts of phenolics, such as quercetrin, depending on light conditions. The greatest difference was seen in the embryonal root cap in all embryo types and conditions.     

Differences in protodermal cell wall structure in zygotic and somatic embryos of <Emphasis Type="Italic">Daucus carota</Emphasis> (L.) cultured on solid and in liquid media

The ultrastructure, cuticle, and distribution of pectic epitopes in outer periclinal walls of protodermal cells of Daucus carota zygotic and somatic embryos from solid and suspension culture were investigated. Lipid substances were present as a continuous layer in zygotic and somatic embryos cultured on solid medium. Somatic embryos from suspension cultures were devoid of cuticle. The ultrastructure of the outer walls of protodermis of embryos was similar in zygotic and somatic embryos from solid culture. Fibrillar material was observed on the surface of somatic embryos. In zygotic embryos, in cotyledons and root pectic epitopes recognised by the antibody JIM5 were observed in all cell walls. In hypocotyls of these embryos, these pectic epitopes were not present in the outer periclinal and anticlinal walls of the protodermis. In somatic embryos from solid media, distribution of pectic epitopes recognised by JIM5 was similar to that described for their zygotic counterparts. In somatic embryos from suspension culture, pectic epitopes recognised by JIM5 were detected in all cell walls. In the cotyledons and hypocotyls, a punctate signal was observed on the outside of the protodermis. Pectic epitopes recognised by JIM7 were present in all cell walls independent of embryo organs. In zygotic embryos, this signal was punctate; in somatic embryos from both cultures, this signal was uniformly distributed. In embryos from suspension cultures, a punctate signal was detected outside the surface of cotyledon and hypocotyl. These data are discussed in light of current models for embryogenesis and the influence of culture conditions on cell wall structure.     

Role of 2,4-dichlorophenoxyacetic acid (2,4-D) in somatic embryogenesis on cultured zygotic embryos of Arabidopsis: cell expansion, cell cycling, and morphogenesis during continuous exposure of embryos to 2,4-D

The relationship between cell expansion and cell cycling during somatic embryogenesis was studied in cultured bent-cotyledon-stage zygotic embryos of a transgenic stock of Arabidopsis thaliana harboring a cyclin 1 At:β-glucuronidase (GUS) reporter gene construct. In embryos cultured in a medium containing 2,4-dichlorophenoxyacetic acid (2,4-D), following a brief period of growth by cell expansion, divisions were initiated in the procambial cells facing the adaxial side at the base of the cotyledons. Cell division activity later spread to almost the entire length of the cotyledons to form a callus on which globular and heart-shaped embryos appeared in about 10 d after culture. Anatomical and morphogenetic changes observed in cultured embryos were correlated with patterns of cell cycling by histochemical detection of GUS-expressing cells. Although early-stage somatic embryos did not develop further during their continued growth in the auxin-containing medium, maturation of embryos ensued upon their transfer to an auxin-free medium. In a small number of cultured zygotic embryos the shoot apical meristem was found to differentiate a leaf, a green tubular structure, or a somatic embryo. Contrary to the results from previous investigations, which have assigned a major role for the shoot apical meristem and cells in the axils of cotyledons in the development of somatic embryos on cultured zygotic embryos of A. thaliana, the present work shows that somatic embryos originate almost exclusively on the callus formed on the cotyledons. Other observations such as the induction of somatic embryos on cultured cotyledons and the inability of the embryo axis (consisting of the root, hypocotyl, and shoot apical meristem without the cotyledons) to form somatic embryos, reaffirm the important role of the cotyledons in somatic embryogenesis in this plant.