The molecular characterization of PaHB2, a homeobox gene of the HD-GL2 family expressed during embryo development in Norway spruce

PaHB1 (for Picea abies Homeobox1), an evolutionarily conserved HD-GL2 homeobox gene, specifically expressed in the protoderm during somatic embryogenesis in the gymnosperm Norway spruce has been reported previously. An additional HD-GL2 gene designated PaHB2 is reported here. During somatic embryogenesis, the PaHB2 gene is uniformly ex pressed in proembryogenic masses and in early somatic embryos, but it is not detectably transcribed at the beginning of maturation. In mature embryos, PaHB2 expression was essentially detected in the outermost layer of the cortex and the root cap. A similar PaHB2 expression is detected post-embryonically in both the primary root and the hypocotyl. Phylogenetic reconstructions and intron pattern analyses revealed that the PAHB proteins fall within two distinct subclasses comprising highly similar angiosperm homologues. The PAHB1 subclass consists of protoderm/epiderm-specific members. By contrast, the PAHB2 subclass gathers homologues with a subepidermal and protodermal/epidermal activity. This study suggests that at least two distinct HD-GL2 genes with a layer-specific expression already existed in the last common ancestor of angiosperms and gymnosperms. The conserved protodermal/epidermal and subepidermal expression of HD-GL2 genes could be used to study embryo radial pattern formation across seed plants.     

Tissue-specific expression of Pa18, a putative lipid transfer protein gene,during embryo development in Norway spruce (Picea abies)

A full-length Picea abies cDNA clone Pa18, encoding a protein with the characteristics of plant lipid transfer proteins, has been isolated and characterized. The size of the deduced 173 amino acid (aa) long protein is around 18 kDa. The first 100–120 aa show similarity to angiosperm lipid transfer proteins in amino acid sequence as well as in predicted secondary structure. The Pa18 gene is constitutively expressed in embryogenic cultures of Picea abies representing different stages of development as well as in non-embryogenic callus and seedlings. The Pa18 gene product has an antimicrobial activity. In situ hybridization showed that the Pa18 gene is equally expressed in all embryonic cells of proliferating embryogenic cultures but during embryo maturation the expression of the gene in maturing and mature somatic as well as in mature zygotic embryos is stronger in the outer cell layer than in other tissues. Southern blot analysis at different stringencies was consistent with a single gene with one or two copies rather than a gene family. Twenty independent transgenic sublines over- and under-expressing the Pa18 gene under the Zea mays ubiquitin promoter were established. There was a high yield of mature somatic embryos with a smooth surface only in untransformed, control cultures. Irrespective of the expression level of Pa18, the somatic embryos started to mature when given a maturation treatment. However, in the transgenic sublines, the outer cells in the maturing embryos frequently became elongated and vacuolated instead of remaining small and uniform. One explanation for this was that the expression of Pa18 was not restricted to the outer cell layer in transformed sublines. Angiosperms and gymnosperms separated about 300 million years ago and the embryo genesis is different in the two groups. The outer cell layer (protoderm), the first tissue to differentiate, is less clearly delineated in gymnosperms. For normal embryo development in angiosperms, expression of the LTP gene must be restricted to the protodermal cells. In this work we show that the expression of the Pa18 gene must be restricted to the putative protodermal cells of the gymnosperm.     

Pattern Formation in the Arabidopsis Embryo Revealed by Position-Specific Lipid Transfer Protein Gene Expression

During Arabidopsis embryogenesis, the zygote divides asymmetrically in the future apical-basal axis; however, a radial axis is initiated only within the eight-celled embryo. Mutations in the GNOM, KNOLLE, and KEULE genes affect these processes: gnom zygotes tend to divide symmetrically; knolle embryos lack oriented cell divisions that initiate protoderm formation; and in keule embryos, an outer cell layer is present that consists of abnormally enlarged cells from early development. Pattern formation along the two axes is reflected by the position-specific expression of the Arabidopsis lipid transfer protein (AtLTP1) gene. In wild-type embryos, the AtLTP1 gene is expressed in the protoderm and initially in all protodermal cells; later, AtLTP1 expression is confined to the cotyledons and the upper end of the hypocotyl. Analysis of AtLTP1 expression in gnom, knolle, and keule embryos showed that gnom embryos also can have no or reversed apical-basal polarity, whereas radial polarity is unaffected. knolle embryos initially lack but eventually form a radial pattern, and keule embryos are affected in protoderm cell morphology rather than in the establishment of the radial pattern.     

Propagation of Norway spruce via somatic embryogenesis

Somatic embryogenesis combined with cryopreservation is an attractive method to propagate Norway spruce (Picea abies) vegetatively both as a tool in the breeding programme and for large-scale clonal propagation of elite material. Somatic embryos are also a valuable tool for studying regulation of embryo development. Embryogenic cell lines of Norway spruce are established from zygotic embryos. The cell lines proliferate as proembryogenic masses (PEMs). Somatic embryos develop from PEMs. PEM-to-somatic embryo transition is a key developmental switch that determines the yield and quality of mature somatic embryos. Withdrawal of plant growth regulators (PGRs) stimulates PEM-to-somatic embryo transition accompanied by programmed cell death (PCD) in PEMs. This PCD is mediated by a marked decrease in extracellular pH. If the acidification is abolished by buffering the culture medium, PEM-to-somatic embryo transition together with PCD is inhibited. Cell death, induced by withdrawal of PGRs, can be suppressed by extra supply of lipo-chitooligosaccharides (LCOs). Extracellular chitinases are probably involved in production and degradation of LCOs. During early embryogeny, the embryos form an embryonal mass surrounded by a surface layer. The formation of a surface layer is accompanied by a switch in the expression pattern of an Ltp-like gene (Pa18) and a homeobox gene (PaHB1), from ubiquitous expression in PEMs to surface layer-specific in somatic embryos. Ectopic expression of Pa18 and PaHB1 leads to an early developmental block. Transgenic embryos and plants of Norway spruce are routinely produced by using a biolistic approach. The transgenic material is used for studying the importance of specific genes for regulating plant development, but transgenic plants can also be used for identification of candidate genes for use in the breeding programme.     

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.     

Developmental pattern formation of somatic embryos induced in cell suspension cultures of cowpea [Vigna unguiculata (L.) Walp]

The sequence of events in the functional body pattern formation during the somatic embryo development in cowpea suspensions is described under three heads. Early stages of somatic embryogenesis were characterized by both periclinal and anticlinal cell divisions. Differentiation of the protoderm cell layer by periclinal divisions marked the commencement of somatic embryogenesis. The most critical events appear to be the formation of apical meristems, establishment of apical-basal patterns of symmetry, and cellular organization in oblong-stage somatic embryo for the transition to torpedo and cotyledonary-stage somatic embryos. Two different stages of mature embryos showing distinct morphology, classified based on the number of cotyledons and their ability to convert into plantlets, were visualized. Repeated mitotic divisions of the sub-epidermal cell layers marked the induction of proembryogenic mass (PEM) in the embryogenic calli. The first division plane was periclinally-oriented, the second anticlinally-oriented, and the subsequent division planes appeared in any direction, leading to clusters of proembryogenic clumps. Differentiation of the protoderm layer marks the beginning of the structural differentiation in globular stage. Incipient procambium formation is the first sign of somatic embryo transition. Axial elongation of inner isodiametric cells of the globular somatic embryo followed by the change in the growth axis of the procambium is an important event in oblong-stage somatic embryo. Vacuolation in the ground meristem of torpedo-stage embryo begins the process of histodifferentiation. Three major embryonic tissue systems; shoot apical meristem, root apical meristem, and the differentiation of procambial strands, are visible in torpedo-stage somatic embryo. Monocotyledonary-stage somatic embryo induced both the shoot apical meristem and two leaf primordia compared to the ansiocotyledonary somatic embryo.     

Arabinogalactan proteins and the extracellular matrix surface network during peach palm somatic embryogenesis

Somatic embryogenesis has been described in peach palm as a reliable method for its in vitro multiplication and conservation. In this study, we evaluated the possible role of arabinogalactan proteins (AGPs) during this morphogenetic pathway. The presence of Yariv reagent, a synthesized chemical antibody that specifically binds AGP molecules, affected somatic embryos and callus development rate, but no effect was observed on fresh weight increment. This substance also had profound effects on embryo morphology: somatic embryos presented loose cells in the protoderm and no signs of polarization could be observed. To better evaluate the role of AGPs, analyses of specific monoclonal antibodies (MAbs) against different AGP epitopes revealed a specific pattern of distribution for each epitope. MAb JIM13 had differential expression and showed intense signal on the embryogenic sector and some immediately adjacent layers. MAb JIM7 against pectin recognized cell walls and a specific layer over the developing somatic embryo, as well as over the shoot meristem region of mature somatic embryos. This corresponds to an extracellular matrix surface network (ECMSN) associated with the development of somatic embryos and closely related to the expression of MAb JIM13. Scanning electron microscopy confirmed the presence of an ECMSN covering a specific group of cells and ultra-structural analyses revealed that the ECMSN had lipophilic substances.     

Position dependent expression of GL2-type homeobox gene, Roc1: significance for protoderm differentiation and radial pattern formation in early rice embryogenesis

In early plant embryogenesis, the determination of cell fate in the protodermal cell layer is considered to be the earliest event in radial pattern formation. To elucidate the mechanisms of epidermal cell fate determination and radial pattern formation in early rice embryogenesis, we have isolated a GL2-type homeobox gene Roc1 (Rice outermost cell-specific gene1), which is specifically expressed in the protoderm (epidermis). In early rice embryogenesis, cell division occurs randomly and the morphologically distinct layer structure of the protoderm cannot be observed until the embryo reaches more than 100 microm in length. Nonetheless, in situ hybridization analyses revealed that specific expression of Roc1 in the outermost cells is established shortly after fertilization, much earlier than protoderm differentiation. In the regeneration process from callus, the Roc1 gene is also expressed in the outermost cells of callus in advance of tissue and organ differentiation, and occurs independently of whether the cells will differentiate into epidermis in the future or not. Furthermore, this cell-specific Roc1 expression could be induced flexibly in the newly produced outermost cells when we cut the callus. These findings suggest that the expression of Roc1 in the outermost cells may be dependent on the positional information of cells in the embryo or callus prior to the cell fate determination of the protoderm (epidermis). Furthermore, the Roc1 expression is downregulated in the inner cells of ligule, which have previously been determined as protodermal cells, also suggesting that the Roc1 expression is position dependent and that this position dependent Roc1 expression is important also in post-embryonic protoderm (epidermis) differentiation.     

Diphtheria toxin-mediated cell ablation reveals interregional communication during Arabidopsis seed development

Fertilization of the female gametophyte in angiosperm plants initiates a process of coordinated development of embryo, endosperm, and seed coat that ensures the production of a viable seed. Mutant analysis has suggested that communication between the endosperm and the seed coat is an important determinant in this process. In addition, cell groups within the embryo, derived from the apical and from the basal cell, respectively, after zygote division, concertedly establish a functional root meristem, and cells in the apical region of the embryo are hypothesized to repress cell divisions in the basal cell-derived suspensor. The available evidence for these interregional communication events mostly relies on the analysis of mutant phenotypes in Arabidopsis. To provide independent and direct evidence for communication events, we used conditional domain-specific expression of the diphtheria toxin A chain (DTA) in developing Arabidopsis seeds. By using a collection of cell- or tissue-type-specific promoters, we show that the mGAL4:VP16/UAS two-component gene expression allows reliable spatiotemporal and conditional expression of the GFP:GUS reporter and the DTA gene in the developing embryo and endosperm. Expression of DTA in the protoderm of the embryo proper led to excessive proliferation of suspensor cells, sometimes resulting in the formation of secondary embryos. Endosperm-specific expression of DTA caused complete cessation of seed growth, followed by pattern defects in the embryo and embryo arrest. Taken together, the results presented here substantiate the evidence for and underline the importance of interregional communication in embryo and seed development and demonstrate the usefulness of conditional toxin expression as a method complementary to phenotypic analysis of developmental mutants.     

Expression and maintenance of embryogenic potential is enhanced through constitutive expression of AGAMOUS-Like 15

The MADS domain protein AGL15 (AGAMOUS-Like 15) has been found to preferentially accumulate in angiosperm tissues derived from double fertilization (i.e. the embryo, suspensor, and endosperm) and in apomictic, somatic, and microspore embryos. Localization to the nuclei supports a role in gene regulation during this phase of the life cycle. To test whether AGL15 is involved in the promotion and maintenance of embryo identity, the embryogenic potential of transgenic plants that constitutively express AGL15 was assessed. Expression of AGL15 was found to enhance production of secondary embryos from cultured zygotic embryos, and constitutive expression led to long-term maintenance of development in this mode. Ectopic accumulation of AGL15 also promoted somatic embryo formation after germination from the shoot apical meristem of seedlings in culture. These results indicate that AGL15 is involved in support of development in an embryonic mode.     

Somatic embryogenesis by liquid culture of epidermal layers in sunflower: from genetic control to cell development

Embryos were obtained using liquid medium culture of sunflower hypocotyl epidermis layers according to the Pélissier etal. (1990) method. In the present work we identified genetic factors controlling somatic embryogenesis and we evidenced the role of ionic channels in embryogenic tissues. Two traits, the number of embryogenic explants (EE) and the number of embryos (EM) were scored in 74 recombinant inbred lines (RILs) from a cross between lines PAC-2 and RHA-266. Analysis of variance indicated the existence of highly significant differences among the parental genotypes and their RILs. Heritability for the somatic embryogenesis traits studied were high (0.64 for EE and 0.77 for EM). Four quantitative trait loci (QTLs) for EE and seven for EM were detected using composite interval mapping. The QTLs for EE explained 48% of the phenotypic variation while the QTLs for EM explained about 89% of the variation, thus revealing several genomic regions related to somatic embryogenesis control in sunflower. In order to study the distribution of ion channels in somatic embryos as compared to zygotic ones, we used a fluorescent-labelled phenylalkylamine, DM-Bodipy PAA, as a probe. Fluorescence labelling was determined by confocal microscopy. The probe intensively labelled the protoderm and epidermis cells in both zygotic and somatic embryos. Callus exhibited labelling on sites where somatic embryos developed. Considering that the location of phenylalkylamine (PAA) binding sites is related to the distribution of ion channels, the high intensity in the protoderm and epidermis of embryos, point to similar properties and functions and their key role in embryo development.     

Micromorphology,structural and ultrastructural changes during somatic embryogenesis of a Tunisian oat variety (<Emphasis Type="Italic">Avena sativa</Emphasis> L. var ‘Meliane’)

To better understand micromorphological and structural changes, histological sections provide additional insight into cellular process and developmental pathways occurring in oat somatic embryogenesis. Environmental scanning electron microscopy (ESEM) and transmission electron microscopy (TEM) were also used to follow the ultrastructural modifications during this system. Histological observations allowed following the events leading to the development of mature somatic embryos. The scheme includes the following steps: cell reactivation, the first organized cell division in diads, triads, tetrads as well as octant stages, the observation of an extracellular matrix (ECM) as a fibrillar material that bounded the surface of individualized proembryos. The transition from proembryo stage to an early globular somatic embryo was noted, where the embryogenic cortex is surrounded by the protoderm. The late globular stage was marked by bipolarity. The early and late transitional stages, the coleoptilar, mature and germinated stages were also described. The ESEM allowed us to follow some rearrangements, related to the morphology and surfaces involved in somatic embryos development. These events are proembryo formation, transition from proembryo to globular stage, marked by protoderm formation, scutellum and coleoptile development and finally somatic embryos germination. The TEM showed that embryogenic cells were very rich in organelles; mitochondria, rough endoplasmic reticulum, Golgi apparatus and ribosomes. Cells of proembryos, globular and late somatic embryos showed more vacuoles and differentiated organelles. The ECM was also detected by TEM as fibrillar material coating the cell walls. These results on structural and ultrastructural changes provided new insights and findings on oat somatic embryogenesis.     

Important processes during differentiation and early development of somatic embryos of Norway spruce as revealed by changes in global gene expression

The aim of this study has been to identify important processes that regulate early stages of embryo development in conifers. Somatic embryogenesis in Picea abies has become a model system for studying embryology in conifers, providing a well-characterized sequence of developmental stages, resembling zygotic embryogeny, which can be synchronized by specific treatments, making it possible to collect a large number of somatic embryos at specific developmental stages. We have used this model to analyze global changes in gene expression during early stages of embryo development by generating an expression profile of 12,536 complementary DNA clones. This has allowed us to identify molecular events regulating putative processes associated with pattern formation during the earliest stages of embryogenesis which have not been identified on the molecular level in conifers before. We recognize notable changes in the expression of genes involved in regulating auxin biosynthesis and auxin response, gibberellin-mediated signaling, signaling between the embryo and the female gametophyte, tissue specification including the formation of boundary regions, and the switch from embryonic to vegetative development. In addition, our results confirm the involvement of previously described processes, including stress, differentiation of a protoderm, and programmed cell death.     

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.