Structural diversity of Papaver somniferum L. cell surfaces in vitro depending on particular steps of plant regeneration and morphogenetic program

Culture of Papaver somniferum in vitro was used for a characterisation of cell surface structures and mode of cell adhesion and cell separation during cell differentiation and plant regeneration in somatic embryogenesis and shoot organogenesis. In early stages of somatic embryogenesis, cell type-specific and developmentally regulated change of cell morphogenesis was demonstrated. Cell wall of separated embryonic cells were self-covered with external tubular network, whereas morphogenetic co-ordination of adhered cells of somatic proembryos was supported by fine and fibrillar external cell wall continuum of peripheral cells, interconnecting also local sites of cell separation. Such type of cell contacts disappeared during histogenesis, when the protodermis formation took place. Tight cell adhesion of activated cells with polar cell wall thickening, and production of extent mucilage on the periphery were the crucial aspects of meristemoids. Fine amorphous layer covered developing shoot primordia, but we have not observed such comparable external fibrillar network. On the contrary intercellular separation of differentiated cells in regenerated organs, and accepting distinct developmental system of somatic embryogenesis and shoot organogenesis, cell adhesion in early stages and ultrastructural changes associated with tissue disorganisation, and the subsequent reorganisation into either embryos or shoots appear to be regulatory morphogenetical events of plant regeneration in vitro.     

Direct somatic embryogenesis and shoot organogenesis from leaf explants of Primulina tabacum

An efficient propagation system via somatic embryogenesis and shoot organogenesis and plant regeneration system for endangered species Primulina tabacum Hance was established. Thidiazuron (TDZ) was the key plant growth regulator for inducing somatic embryogenesis and kinetin (KIN) and 6-benzylaminopurine (BAP) were the key cytokinins for inducing shoot organogenesis from leaf explants. TDZ combined with BAP or KIN in the induction Murashige and Skoog medium induced both somatic embryos and adventitious shoots. Leaf explants with abaxial site in contact with the medium induced less somatic embryos or adventitious shoots compared to inversely placed leaf explants and the optimum pH was 6.5–7.0. Secondary somatic embryos or adventitious shoot could be induced from primary somatic embryos using TDZ and BAP. Shoots developed adventitious roots on rooting medium containing 0.5 μM indole-3-butyric acid and 0.2 % activated carbon. Over 90 % of plantlets survived following acclimatization and transfer to potting mixture (sand:Vermiculite:limestone; 1:2:1).     

Two SERK genes are markers of pluripotency in Cyclamen persicum Mill

The genetic basis of stem cell specification in somatic embryogenesis and organogenesis is still obscure. SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE (SERK) genes are involved in embryogenesis and organogenesis in numerous species. In vitro culture of Cyclamen persicum immature ovules provides a system for investigating stem cell formation and maintenance, because lines forming either organs or embryos or callus without organs/embryos are available for the same cultivar and plant growth regulator conditions. The present aim was to exploit this property of cyclamen cultures to understand the role of SERK(s) in stem cell formation and maintenance in somatic embryogenesis and organogenesis in vitro, in comparison with expression in planta. CpSERK1 and CpSERK2 were isolated from embryogenic callus. CpSERK1 and CpSERK2 levels by RT-PCR showed that expression is high in embryogenic, moderate in organogenic, and null in recalcitrant calli. in situ hybridizations showed that the expression of both genes started in clumps of pluripotent stem cells, from which both pre-embryogenic aggregates and organ meristemoids derived, and continued in their trans-amplifying, meristem-like, derivatives. Expression declined in organ meristemoids, in parallel with a partial loss of meristematization. In mature somatic embryos, and in shoot and root primordia, CpSERK1 and CpSERK2 were expressed in meristems, and similar patterns occurred in zygotic embryo and primary meristems in planta. The results point to SERK1 and SERK2 as markers of pluripotency in cyclamen. It is proposed that the high expression of these genes in the trans-amplifying derivatives of the stem cells maintains a pluripotent condition leading to totipotency and, consequently, somatic embryogenesis.     

Organogenesis and embryogenesis from diverse explants in pigeonpea (Cajanus cajan L.)

Seed and seedling expiants of pigeonpea were evaluated for organogenesis and somatic embryogenesis. De novo plant regeneration through organogenesis was obtained from mature cotyledons, primary leaves and roots of seedlings. Production of multiple shoots from the cotyledonary node was observed in cultures of whole seeds on 6-benzylaminopurine enriched medium. Somatic embryos were induced from immature cotyledons and embryonal axes, however, well-developed plants could not be derived from these embryos. The regenerants obtained through organogenesis were transferred to the field and grown to maturity.     

Regeneration of roots, shoots and embryos: physiological, biochemical and molecular aspects

When the proper stimuli are given, somatic plant cells may form adventitious embryos, roots or shoots. The three pathways of regeneration show apparent similarities. They consist of three analogous phases: 1) dedifferentiation (during which the tissue becomes competent to respond to the organogenic/embryogenic stimulus), 2) induction (during which cells become determined to form either a root, a shoot or an embryo), and 3) realization (outgrowth to an organ or an embryo). The first phase may involve a period of callus growth (indirect regeneration), but often cells present in the explant become competent without cell division or without cell division at a large scale (direct regeneration). In an explant, only very few cells show the organogenic/embryogenic response. In direct regeneration, the three regenerative pathways start from cells in different tissues. This is most obvious when the different types of regeneration occur in the same explant. The hormonal trigger for the dedifferentiation phase is a general one, probably auxin. During the induction phase, each pathway requires specific hormonal triggers. During the realization phase, hormones should be absent or at low concentration. The successive steps in the regeneration process coincide with events on the molecular and biochemical levels, but so far no coherent picture has emerged. In particular during the early stages of regeneration, research on these levels is hampered by a technical problem, viz., the very low proportion of cells that participate in the process of regeneration. New methods may overcome this problem. This revised version was published online in July 2006 with corrections to the Cover Date.     

Cell fate switch during in vitro plant organogenesis

Plant mature cells have the capability to reverse their state of differenUation and produce new organs under cultured conditions. Two phases, dedifferentiation and redifferentiation, are commonly characterized during in vitro organogenesis.In these processes, cells undergo fate switch several times regulated by both extrinsic and intrinsic factors, which are associated with reentry to the cell cycle, the balance between euchromatin and heterochromatin, reprogramming of gene expression, and so forth. This short article reviews the advances in the mechanism of organ regeneration from plant somatic cells in molecular, genomic and epigenetic aspects, aiming to provide important information on the mechanism underlying cell fate switch during in vitro plant organogenesis.     

Plant regeneration via somatic embryogenesis and shoot organogenesis from immature cotyledons of Camellia nitidissima Chi

Camellia nitidissima Chi (Theaceae) is a world-famous economic and ornamental plant with golden-yellow flowers. It has been classified as one of the rarest and most endangered plants in China. Our objective was to induce somatic embryogenesis, shoot organogenesis and plant regeneration for C. nitidissima. Three types of callus (whitish, reddish and yellowish) were induced from immature cotyledons on improved woody plant medium (WPM) with different plant growth regulators (PGRs). Among the callus, whitish callus was induced by 4.5 μM 2,4-dichlorophenoxyacetic acid (2,4-D) and reddish and yellowish callus were induced by strongly active cytokinins, thidiazuron (TDZ) or 6-benzylaminopurine (BAP), singly or combined with weakly active auxin, α-naphthaleneacetic acid (NAA). The embryogenic callus could differentiate into somatic embryos, nodular embryogenic structures (large embryo-like structures) or adventitious shoots depending on the PGR used in WPM. BAP was best for adventitious buds and zeatin was best for somatic embryogenesis while kinetin (Kt) was best for the formation of nodular embryogenic structures. The three regeneration pathways often occurred in the same embryogenic callus clumps. Most shoots (80.0%) developed roots in WPM supplemented with 24.6 μM IBA and 0.3 μM NAA while 47.5% of somatic embryos could germinate directly and develop into plantlets on induction medium supplemented with 0.9 μM BAP and 0.1 μM NAA. The nodular embryogenic structures could be sub-cultured and cyclically developed in one of two differentiation pathways: shoot organogenesis or somatic embryogenesis. Plantlets derived from shoot buds rooted and somatic embryos germinated when transplanted into soil in a greenhouse; 66.7% of plantlets from shoot culture and 78.6% of plantlets from somatic embryos survived after 8 weeks’ acclimatization.     

Papaver somniferum regeneration by somatic embryogenesis and shoot organogenesis

Secondary somatic embryogenesis and shoot organogenesis from primary somatic embryos of Papaver somniferum L. are described. The embryos became malformed, the root meristem expressed dividing activity without position-dependent cell differentiation, causing abnormal development or arrested growth of primary somatic embryos. The adventitious shoots regenerated from embryo hypocotyl, but secondary somatic embryos had an epidermal origin close to the root meristem. The regeneration occurred without hormonal treatment, indicating endogenous nature of triggering signals. These signals are probably related to the integrity loss of morphogenetic steps during development of primary somatic embryos, which appeared to induce an activation of cells competent to regeneration. This revised version was published online in August 2006 with corrections to the Cover Date.     

Differences in capacities of in vitro organ regeneration between two Arabidopsis ecotypes Wassilewskija and Columbia

In vitro organogenesis is well-controlled and thus provides an ideal system to study mechanisms of plant organ development. Although it has been well investigated for a long time that exogenous hormones play important roles in determining the types of organs regenerated in vitro, there is currently limited information available for other key factors that mediate de novo organ regeneration. Here, we reported simple and efficient one-step processes for evaluating capacities of inflorescence stem-derived in vitro organogenesis between two different ecotypes in Arabidopsis. Different types of organs, including shoots and roots were initiated from inflorescence stem explants cultured on the media containing 216 combinations of exogenous auxin and cytokinin. Further, we showed that Wassilewskija ecotype had the much higher shoot regeneration capacity than Columbia with different combinations of hormones, indicating that the ecotype is an essential factor determining de novo organogenesis. Our results also suggested that the defined expression patterns of genes involved in auxin and cytokinin biosynthesis were correlated with the variations in organogenesis capacities between the two ecotypes. Thus, in vitro organogenesis is likely regulated by ecotypes through mediating endogenous hormonal biosynthesis.     

High-frequency conversion of abnormal peanut somatic embryos

Peanuts (Arachis hypogaea L.) are widely cultivated as a rich source of protein and oil. Although protocols for the regeneration of peanut via somatic embryogenesis and organogenesis have been developed, most of them have resulted in low frequencies of plant recovery. In this report, we describe a protocol for plantlet formation at high frequency from somatic embryos. Morphologically abnormal somatic embryos germinated and produced roots only in medium devoid of growth regulators. Shoots emerged from the undeveloped plumule of these rooted embryos in medium containing both 6-benzyladenine (BA) and kinetin (KN), or in medium with thidiazuron (TDZ) alone. In Murashige and Skoog basal medium supplemented with 8.9 μm BA and 14 μm KN, 86% of the embryos developed shoots. Substitution of BA and KN with 22.7 μm TDZ increased plant recovery from 86% to 92%. Plants grown on TDZ had multiple shoots. Eighty-four percent of these plants survived in sandy soil and were grown to maturity. Received: 12 February 1996 / Revision received: 11 July 1996 / Accepted 30 April 1997     

Somatic embryogenesis from cell suspension and protoplast cultures ofCapsella bursa-pastoris (L.) Medic

Summary Rapidly growing cell suspension cultures of shepherd’s purse (Capsella bursa-pastoris L. Medic.) were established from leaf-derived calli. These suspensions remained unorganized in the presence of 2,4-D, but underwent extensive root organogenesis in a growth regulator-free liquid medium. Attempts to induce direct embryogenesis in liquid cultures were unsuccessful, but numerous embryos were obtained from cells plated onto growth-regulator-free solid medium. These embryos were frequently abnormal, and secondary embryogenesis was problematic for plant recovery but fertile plants were recovered. Viable protoplasts could readily be isolated from these cell suspensions. After 1 wk of culture, protoplast viability was 62%, and 7% of the cells had divided. Embryogenesis was observed from protoplast-derived microcolonies, plated on growth-regulator-free medium. Although these somatic embryos were difficult to root, plants were recovered. New cell suspensions were more recently established, which were only 4 to 6 mo. old when plant regeneration was attempted. Numerous shoots were obtained when these cells were plated onto growth-regulator-free solid media. However, these shoots differed from the embryos previously obtained in that they readily rooted and rapidly developed into plantlets. This system may allow the use of shepherd’s purse as a gene source for introgression of agronomically interesting traits intoBrassica crop species through protoplast manipulation and somatic hybridization.     

Detection of an Embryogenic Cell Antigen in Carrot

Monoclonal antibodies were raised against proteins in a microsomalfraction from carrot embryogenic cells. The presence of a 31-kDaembryogenic cell antigen detected by one antibody (ID 11) wasdemonstrated in embryogenic cells but not in other plant materials,such as non-embryogenic cells, somatic embryos, crown gallsand hairy roots. The antigen was also present in organ segmentsthat carried somatic embryos having been induced by exposureto various stresses. In non-embryogenic cells, the antibodyrecognized a small amount of a 32-kDa antigen. Both the 31-and the 32-kDa antigens accumulated in carrot seeds during theirdevelopment and then disappeared after germination. (Received April 16, 1990; Accepted July 16, 1990)     

Plant regeneration via direct embryo axis-like shoot and root formation from excised cotyledon explants of ginseng seedlings

Summary Cotyledon explants of Panax ginseng at various developmental stages were cultured on Murashige and Skoog (MS) medium with 0.5 μM indole butyric acid and 8.8 μM N⁶-benzyladenine. Upon culturing of cotyledon explants from mature zygotic embryos, 34% of the explants formed somatic embryos, and 46% formed adventitious shoots. In the cotyledon explants from 1-wk-old seedlings, embryo axis-like shoots and roots developed at a high frequency (79%) near the excised portion of the cotyledon base. The developmental pattern of embryo axis-like organ formation was structurally different from that of somatic embryos and adventitious shoots but similar to that of parts of the embryo axis of zygotic embryos. In the early stages of embryo axis-like organ formation, epicotyl-like shoot primordia were developed directly from the cotyledon base after 2 wk of culture; subsequently roots developed near the base of the epicotyl-like shoots and eventually regenerated into plantlets with both shoots and roots. The frequency of embryo axis-like organ formation declined as the growth of seedlings proceeded. In addition, the frequency of somatic embryo and adventitious bud formation rapidly declined with the age of the cotyledons. Plant regeneration via embryo axis-like organ formation might be a new pattern of morphogenesis in P. ginseng cotyledon culture.     

Somatic embryogenesis and shoot organogenesis from leaf explants of <Emphasis Type="Italic">Primulina tabacum</Emphasis>

Primulina tabacum is a rare and endangered species that is endemic to China. Establishing an efficient regeneration system is necessary for its conservation and reintroduction. In this study, when leaf explants collected from plants grown in four ecotypes in China are incubated on Murashige and Skoog (MS) medium containing 5.0 μM thidiazuron (TDZ) for 30 days, then transferred to medium containing 5.0 μM 6-benzyladenine (BA), adventitious shoots are then observed. Conversely, when leaf explants are incubated on medium containing 5.0 μM BA for 30 days, then transferred to medium containing 5.0 μM TDZ, somatic embryogenesis is induced. This indicates that somatic embryogenesis and shoot organogenesis could be switched simply by changing the order of two cytokinins supplemented in the culture medium. Histological investigation has revealed that embryogenic cells are induced within 30 days following incubation of explants in medium containing TDZ. Only if embryogenic cells were induced, TDZ could enhance somatic embryogenesis and BA could stimulate shoot organogenesis. When comparing explants from different ecotypes, leaf explants from Zixiadong in Hunan Province could induce low numbers (1–2) of either somatic embryos or adventitious shoots on medium containing either 5.0 μM TDZ or 5.0 μM BA, respectively. Whereas, leaf explants from plants collected from the other three ecological habitats could induce 50–70 somatic embryos/adventitious shoots per explant. Moreover, somatic embryos could induce secondary somatic embryogenesis and adventitious shoots on different media. All regenerated shoots developed adventitious roots when these are transferred to rooting medium, and over 95% of plantlets have survived following acclimatization and transfer to a potting mixture (1:1, sand:vermiculite).     

In vivo labeling of sunflower embryonic tissues by fluorescently labeled phenylalkylamine

Summary A fluorescently labeled phenylalkylamine, DM-Bodipy PAA, was used as a probe for the in vivo detection of ion channels in embryonic and nonembryonic tissues of sunflower. Zygotic embryos, somatic embryos, callus, leaves, roots, and shoots were analysed. Fluorescence intensity in the tissues was determined with cytofluorometry and confocal microscopy. DM-Bodipy PAA intensively labeled the protoderm and epidermis cells in both zygotic and somatic embryos. Callus cultures exhibited labeling on sites where somatic embryos developed. Labeling was, however, very weak in leaves, shoots, and roots, except in the root cap and in the epidermis of the root. Considering that the location of phenylalkylamine binding sites is related to the distribution of ion channels in both animal and plant cells, the high intensity of labeling observed in the protoderm and epidermis of zygotic and somatic embryos as well as in protoderm, epidermis, and caps of root tips, is consistent with the role these tissues may play in ion exchange with the environment.     

Shoot meristem: an ideal explant for Zea mays L. transformation.

We report on a rapid high-frequency somatic embryogenesis and plant regeneration protocol for Zea mays. Maize plants were regenerated from complete shoot meristem (3-4 mm) explants via organogenesis and somatic embryogenesis. In organogenesis, the shoot meristems were directly cultured on a high-cytokinin medium comprising 5-10 mg x L(-1) 6-benzylaminopurine (BAP). The number of multiple shoots produced per meristem varied from six to eight Plantlet regeneration through organogenesis resulted in just four weeks. Callus was induced in five days of incubation on an auxin-modified Murashige and Skoog (MS) medium. Prolific callus, with numerous somatic embryos, developed within 3-4 weeks when cultured on an auxin medium containing 5 mg 2,4-dichlorophenoxyacetic acid x L(-1). The number of multiple shoots varied from three to six per callus. Using R23 (Pioneer, Hi-Bred, Johnston, Iowa), the frequency of callus induction was consistently in excess of 80% and plant regeneration ranged between 47 and 64%. All regenerated plantlets survived in the greenhouse and produced normal plants. Each transgenic plant produced leaves, glumes, and anthers that uniformly expressed green fluorescent protein (GFP). The GFP gene segregated in the pollen. Based on this data it is concluded that the transgenics arose from single-cell somatic embryos. The rate of transfer DNA (T-DNA) transfer to complete shoot meristems of Zea mays was high on the auxin medium and was independent of using super-virulent strains of Agrobacterium.     

小麦根愈伤组织胚胎发育过程研究

实验通过对６个人工合成小麦品系和对照品种“中国春”种子根愈伤组织分化形成再生植株的过程进行形态和组织切片观察,发现分化初期有２种途径,一种是从愈伤组织先形成不定胚,然后再发育成不定芽和不定根,另一种途径是直接从愈伤组织中分化发育成不定根和不定芽;分化后期不定芽和不定根生长发育有３种类型：一种是不定芽发育先于不定根,一种是不定芽与不定期不定芽和不定根生长发育有种类型：一种是不一定芽发育先于不定根,一