High-resolution histographical mapping of glucose concentrations in developing cotyledons of Vicia faba in relation to mitotic activity and storage processes: glucose as a possible developmental trigger

Previous studies provided evidence that the carbohydrate status triggers developmental processes in the growing cotyledons of Vicia faba . We describe here the high-resolution mapping of glucose concentrations in tissue sections of developing faba bean cotyledons by quantitative bioluminescence and single-photon imaging. Patterns of local glucose distributions are compared with tissue cell type, mitotic index and the distribution pattern of starch. During cotyledon differentiation, gradients in the glucose concentration emerge which are related to the particular cell type. Higher concentrations are found in non-differentiated premature regions of the cotyledon whereas mature starch-accumulating regions contain particularly low concentrations of glucose. In addition, glucose concentration is correlated to mitotic activity. The glucose distribution pattern is therefore related to the developmental gradient. Our data provide for the first time evidence for steep glucose gradients across developing plant embryos and favour the idea that sugar gradients may have morphogenic functions in developing cotyledons.     

Nucleostemin-like 1 is required for embryogenesis and leaf development in Arabidopsis

Arabidopsis NSN1 encodes a nucleolar GTP-binding protein and is required for flower development. Defective flowers were formed in heterozygous nsn1/+?plants. Homozygous nsn1 plants were dwarf and exhibited severe defects in reproduction. Arrests in embryo development in nsn1 could occur at any stage of embryogenesis. Cotyledon initiation and development during embryogenesis were distorted in nsn1 plants. At the seedling stage, cotyledons and leaves of nsn1 formed upward curls. The curled leaves developed meristem-like outgrowths or hyperplasia tissues in the adaxial epidermis. Long and enlarged pavement cells, characteristic of the abaxial epidermis of wild type plants, were found in the adaxial epidermis in nsn1 leaves, suggesting a disoriented leaf polarity in the mutant. The important role of NSN1 in embryo development and leaf differentiation was consistent with the high level expression of the NSN1 gene in the developing embryos and the primordia of cotyledons and leaves. The CLAVATA 3 (CLV3) gene, a stem cell marker in the Arabidopsis shoot apical meristem (SAM), was expressed in expanded regions surrounding the SAM of nsn1 plants, and induced ectopically in the meristem-like outgrowths in cotyledons and leaves. The nsn1 mutation up-regulated the expression levels of several genes implicated in the meristem identity and the abaxial cell fate, and repressed the expression of other genes related to the specification of cotyledon boundary and abaxial identity. These results demonstrate that NSN1 represents a novel GTPase required for embryogenesis, leaf development and leaf polarity establishment in Arabidopsis.     

Evidence of a key role for photosynthetic oxygen release in oil storage in developing soybean seeds

Based on the topographical analysis of photosynthesis and oil storage, we propose in a companion paper that photosynthetic oxygen release plays a key role in the local energy state, storage metabolism and flux toward lipid biosynthesis in developing soybean seeds. To test this hypothesis, we combined topographical analysis of ATP gradients across tissues, microsensor quantifications of internal O2 levels, assays of energy balance, metabolite profiles and isotope-labelling studies. Seeds show a marked degree of oxygen starvation in vivo (minimum O2 levels 0.1 kPa, approximately 1.3 microm), affecting ATP gradients, overall energy state, metabolite pools and storage activity. Despite the low light availability, photosynthesis supplies significant amounts of oxygen to the hypoxic seed tissue. This is followed by an increase in local ATP levels, most prominently within the lipid-synthesizing (inner) regions of the embryo. Concomitantly, partitioning of 14C-sucrose to lipids is increased, suggesting higher rates of lipid biosynthesis. It is concluded that both respiratory and biosynthetic fluxes are dynamically adjusted to photosynthetic oxygen supply.     

Histology of Organogenic and Embryogenic Responses in Cotyledons of Somatic Embryos of Quercus Suber L

In cork oak (Quercus suber L.), recurrent embryogenesis is produced in vitro through autoembryony without exogenous plant growth regulators (PGRs); secondary embryos appear on the embryo axis but seldom on cotyledons. Focusing mainly on the histological origin of neoformations, we investigated the influence of the embryo axis and exogenous PGRs on the embryogenic potential of somatic embryo cotyledons. Isolated cotyledons of somatic embryos became necrotic when cultured on PGR-free medium but gave secondary embryos when cultured on media containing benzyladenine and naphthaleneacetic acid. Cotyledons of cork oak somatic embryos are competent to give embryogenic responses. Isolated cotyledons without a petiole showed a lower percentage of embryogenic response than did those with a petiole. In petioles, somatic embryos arose from inner parenchyma tissues following a multicellular budding pattern. Joined to the embryo axis, cotyledons did not show morphogenic responses when cultured on PGR-free medium but revealed budlike and phylloid formations when cultured on medium with PGRs. The different morphogenic behavior displayed by somatic cotyledons indicates an influence of the embryo axis and indicates a relationship between organogenic and embryogenic regeneration pathways.     

Energy status and its control on embryogenesis of legumes. Embryo photosynthesis contributes to oxygen supply and is coupled to biosynthetic fluxes

Legume seeds are heterotrophic and dependent on mitochondrial respiration. Due to the limited diffusional gas exchange, embryos grow in an environment of low oxygen. O(2) levels within embryo tissues were measured using microsensors and are lowest in early stages and during night, up to 0.4% of atmospheric O(2) concentration (1.1 micro M). Embryo respiration was more strongly inhibited by low O(2) during earlier than later stages. ATP content and adenylate energy charge were lowest in young embryos, whereas ethanol emission and alcohol dehydrogenase activity were high, indicating restricted ATP synthesis and fermentative metabolism. In vitro and in vivo experiments further revealed that embryo metabolism is O(2) limited. During maturation, ATP levels increased and fermentative metabolism disappeared. This indicates that embryos become adapted to the low O(2) and can adjust its energy state on a higher level. Embryos become green and photosynthetically active during differentiation. Photosynthetic O(2) production elevated the internal level up to approximately 50% of atmospheric O(2) concentration (135 micro M). Upon light conditions, embryos partitioned approximately 3-fold more [(14)C]sucrose into starch. The light-dependent increase of starch synthesis was developmentally regulated. However, steady-state levels of nucleotides, free amino acids, sugars, and glycolytic intermediates did not change upon light or dark conditions. Maturing embryos responded to low O(2) supply by adjusting metabolic fluxes rather than the steady-state levels of metabolites. We conclude that embryogenic photosynthesis increases biosynthetic fluxes probably by providing O(2) and energy that is readily used for biosynthesis and respiration.     

Storage protein gene expression is localised to regions lacking mitotic activity in developing pea embryos. An analysis of seed development in Pisum sativum XIV

Storage protein gene expression has been studied in relation to mitotic activity to ascertain whether these processes are linked during embryo development in pea. Sections from immature pea embryos were probed by in situ hybridisation to show the pattern of vicilin storage protein gene expression. In addition, the location of mitotic cells was identified using fluorescence microscopy. Vicilin mRNA was first localised in the parenchyma cells of the upper adaxial region of the cotyledons. As the embryos increased in fresh weight, gene expression spread from this region, in a wave-like manner, down and across the cotyledons. The gene was only expressed in those regions of the embryo that lacked mitotic activity.     

Changes in Abscisic Acid Content in Axis and Cotyledons of Developing Phaseolus vulgaris Embryos and their Physiological Consequences

Prevost, I. and Le Page–Degivry, M. Th. 1985. Changesin absicisic acid content in axis and cotyledons of developingPhaseolus vulgaris embryos and their physiological consequences.—J.exp. Bot. 36: 1900–1905.Changes in abscisic acid (ABA)content with time were measured in embryonic axes and in cotyledonsof Phaseolus vulgaris embryos using a radio–immunoassay.During embryogenesis, a similar pattern was observed in bothtissues: ABA increased to a maximum 29 d after an thesis, followedby a decrease as the seed matured. The level of ABA in the cotyledonswas always much higher than that in the axes. In in vitro cultures,the duration of the lag phase before germination of isolatedembryonic axes increased with ABA content. The presence of cotyledonsalways lengthened the lag phase; longer lag phases were associatedwith greater concentrations of ABA in the cotyledons. Moreoverthe presence of cotyledons stimulated the growth of seedlings. Key words: ABA distribution, embryo maturation, axis and embryo germinability     

Direct differentiation of somatic embryos on cotyledons of <Emphasis Type="Italic">Azadirachta indica</Emphasis>

Somatic embryos regenerated in high-frequency (up to 100 %) on immature cotyledons of Azadirachta indica at a low concentration of thidiazuron (TDZ; 0.5 M). Regeneration occurred exclusively from abaxial surface. Frequency of regeneration declined with the age of the cotyledons: on semimature cotyledons regeneration occurred only from some regions of the abaxial surface and on mature cotyledons it was confined to corners. However, an increase in concentration of TDZ to 1.0 M improved the regeneration response. Higher regenerative capacity of immature cotyledons was due to presence of milk in immature fruits because regeneration response of immature cotyledons declined on washing of cotyledons for 24 h in liquid medium, and milk from immature fruits augmented the regeneration response of mature cotyledons. Somatic embryos regenerated readily on hormone-free medium and plantlets derived were able to survive after transfer to soil.     

Enhanced somatic single embryo formation by plasmolyzing pretreatment from cultured ginseng cotyledons

Cotyledon explants of Panax ginseng zygotic embryos directly produced somatic embryos on Murashige and Skoog medium without growth regulators. Somatic embryos were formed only near the proximal excised region of cotyledons. Multiple and/or single embryos were formed and the frequency of these formations differed according to the degree of maturity of the zygotic embryos used as the explant source. When cotyledon explants pre-plasmolysed (1.0 M sucrose for 24 h), the frequency of single embryo formation was enhanced regardless of cotyledon maturity. In addition, the distribution pattern of somatic embryos changed markedly because the embryos were formed over the whole surface of the cotyledons. Histological observation revealed that plasmolyzing pretreatment broke the plasmodesmatal connection between cells and when the embryogenic cell divisions commenced, plasmodesmatal strands were hardly observed except for newly formed cell walls. This indicates that the enhanced single embryo formation over the entire surfaces of cotyledon explants might be the result of an interruption of cell–cell interaction by plasmolyzing pretreatment.     

THE DEVELOPMENTAL ANATOMY OF THE ANNONACEAE. I. EMBRYO AND EARLY SEEDLING STRUCTURE

Development of the epicotylary meristem is delayed; thus, it apparently has no immediate controlling influence on the procambium initiation either in the hypocotyl-root axis or in the cotyledons. Contrary to the situation found in most herbaceous dicotyledons, the procambium forms a hollow cylinder in the axis of the mature embryo. The first protophloem differentiates simultaneously in the upper part of the hypocotyl-root axis, at the base of the cotyledons, and in the cotyledons; protoxylem differentiation follows the same pattern as that of the protophloem. The direct vascular connection between the hypocotyl-root axis and cotyledons is established early in the mature embryo, and the fundamental aspects of transition phenomena are exhibited by the procambium before mature vascular elements differentiate. In the mature embryos, the pattern of lateral differentiation is irregular in that the number of protoxylem elements present at different levels is quite variable.     

Embryogenic cultures of the leguminous tree Albizia julibrissin and recovery of plants

A somatic embryogenic system was developed and plants regenerated in mimosa (Albizia julibrissin Durazz). Development of somatic embryos in the species has not previously been reported. Immature seeds, embryo cotyledons and embryo axes (cotyledons removed) at defined developmental stages were placed on induction media with different concentrations of 2,4-D. Two distinct embryogenic responses occurred: either proembryo masses or cotyledonary-stage embryos. Twenty five percent of all embryo axes cultured on basal medium produced cotyledonary somatic embryos. Six percent of in ovulo immature seed explants generated proembryo masses. These masses proliferated in liquid culture in the dark. Proembryos developed further when transferred to a growth-regulator-free semisolid medium in the light. Somatic embryos derived from either proembryo suspensions or cotyledonary embryo cultures on semisolid medium germinated to form plants that continued to grow vigorously following transfer to soil. This revised version was published online in June 2006 with corrections to the Cover Date.     

Energy state and its control on seed development: starch accumulation is associated with high ATP and steep oxygen gradients within barley grains

The role of oxygen and energy state in development and storage activity of cereal grains is an important issue, but has remained largely uninvestigated due to the lack of appropriate analytical methods. Metabolic profiling, bioluminescence-based in situ imaging of ATP, and oxygen-sensitive microsensors were combined here to investigate barley seed development. For the first time temporal and spatial maps of O2 and ATP distribution in cereal grains were determined and related to the differentiation pattern. Steep O2 gradients were demonstrated and strongly hypoxic regions were detected within the caryopsis (<0.1% of atmospheric saturation). Growing lateral and peripheral regions of endosperm remained well-supplied with O2 due to pericarp photosynthesis. ATP distribution in the developing grain was coupled to endosperm differentiation. High ATP concentrations were associated with the local onset of starch storage within endosperm, while low ATP overlapped with the hypoxic regions. Temporally, the building of steep gradients in ATP coincided with overall elevating metabolite levels, specific changes in the metabolite profiles (glycolysis and citrate cycle), and channelling of metabolic fluxes towards storage (increase of starch accumulation rate). These findings implicate an inhomogenous spatial arrangement of metabolic activity within the caryopsis. It is suggested that the local onset of starch storage is coupled with the accumulation of ATP and elevated metabolic activity. Thus, the ATP level reflects the metabolic state of storage tissue. On the basis of these findings, a hypothetical model for the regulation of starch storage in barley seeds is proposed.     

Developing embryos of Sesbania sesban have unique potential to photosynthesize under high osmotic environment

This study has been carried out to investigate the photosynthetic activities in developing embryos of Sesbania sesban under a highly osmotic environment. In S. sesban, the embryo turns green/chlorophyllous at the early heart shape stage. Interestingly, despite being deeply embedded within the supporting tissues (several layers of pod wall, seed coat and endosperm) and developing in a highly osmotic environment, the growing embryo of the developing seed showed the presence of various components of photosynthetic machinery besides being chlorophyllous. The shade-adaptive nature of the photosynthetic machinery of the embryo is evident from (a) low chlorophyll a/b ratio, (b) photosystem (PS) II attaining maximal activity at low photon flux density and (c) lesser plastoquinone pool. The photosynthetic potential of the growing embryo seems to contribute towards seed filling as it has the potential not only to harvest light energy but also to fix CO2 as efficiently as other photosynthetic parts of S. sesban. In fact, ribulose-1,5 bisphosphate carboxylase purified from embryos manifested subunit composition similar to that of leaves. The PS II activity in leaves, cotyledonary leaves and pod wall declined sharply with increase in the level of NaCl and sucrose above 150 and 300 mmol, respectively. Amazingly, PS II activity in developing embryos was maximal in the presence of 250 mmol NaCl or 500 mmol sucrose and remained high even when NaCl and sucrose levels were increased to 500 and 1000 mmol, respectively. We hypothesize that the developing embryos have some factor(s) which protect(s) the photosynthetic machinery in an environment of high osmotic strength.     

The development of photosynthetic light reactions in cultured apple embryos in relation to their embryonal dormancy

The development of photosynthetic light reactions (photoreduction and photophosphorylation) was studied in cotyledons of cultured embryos isolated from stratified and non-stratified apple seeds (Malus domestica Borb. cv. Antonówka). The results obtained show the presence of an energy transfer inhibitor in the cotyledons of the stratified embryos.Abbreviations PSII photosystem II - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - ATP adenosine triphosphate - ADP adenosine diphosphate - CCCP carbonyl cyanide m-chlorophenyl-hydrazone - EDTA ethylenediamine tetraacetic acid; P, inorganic orthophosphate - TES (N-tris [hydroxymethyl] methyl-2-aminoethane sulfonic acid) This work was partly supported by the Polish Academy of Sciences, Contract No 10.2.10     

Screening of soybean, Glycine max L.) Merrill, lines for somatic embryo induction and maturation capability from immature cotyledons

Summary Seventeen breeding lines of soybean, Glycine max (L.) Merrill, and cv. Jack, from relative maturity groups 0.3–7.5 were assessed for their ability to undergo somatic embryogenesis. The goal of this study was to determine which lines had high embryogenic capacity. We also sought to understand the relationship between relative maturity and embryogenesis. Embryos from immature cotyledons were initiated on solid MS medium with varying levels of 2,4-dichlorophenoxyacetic acid (2,4-D). Qualitative and quantitative measures of initiation, proliferation, differentiation, and maturation were recorded. The breeding lines differed significantly with respect to percent induction, number of embryos induced, and quality of induced embryos. After 1 mo, of proliferation, two early maturing lines, the control, Jack, and NK-5, had the best overall performance. High percent response of proliferating embryos was positively associated with lower maturity groups. Relatively high concentrations of 2,4-D (compared with that used in prolifcrating medium, e.g., 226 μM; 50 mg l⁻¹) in the initiating medium reduced numbers of embryo clusters per cotyledon initiated and percent initiation, and the concentration of 2,4-D affected the proliferation of somatic embryos in a breeding line-dependent manner. The breeding lines differed significantly in the time to produce mature somatic embryos. There was a positive correlation between immature embryo quality and number of differentiated somatic embryos produced. Retired.     

Somatic embryogenesis of a wild passion fruit species Passiflora cincinnata Masters: histocytological and histochemical evidences

The characterization of cellular changes that occur during somatic embryogenesis is essential for understanding the factors involved in the transition of somatic cells into embryogenically competent cells and determination of cells and/or tissues involved. The present study describes the anatomical and ultrastructural events that lead to the formation of somatic embryos in the model system of the wild passion fruit (Passiflora cincinnata). Mature zygotic embryos were inoculated in Murashige and Skoog induction media supplemented with 2,4-dichlorophenoxyacetic acid and 6-benzyladenine. Zygotic embryo explants at different development stages were collected and processed by conventional methods for studies using light, scanning, and transmission electron microscopy (TEM). Histochemical tests were used to examine the mobilization of reserves. The differentiation of the somatic embryos began in the abaxial side of the cotyledon region. Protuberances were formed from the meristematic proliferation of the epidermal and mesophyll cells. These cells had large nuclei, dense cytoplasm with a predominance of mitochondria, and a few reserve compounds. The protuberances extended throughout the abaxial surface of the cotyledons. The ongoing differentiation of peripheral cells of these structures led to the formation of proembryogenic zones, which, in turn, dedifferentiated into somatic embryos of multicellular origin. In the initial stages of embryogenesis, the epidermal and mesophyll cells showed starch grains and less lipids and protein reserves than the starting explant. These results provide detailed information on anatomical and ultrastructural changes involved in the acquisition of embryogenic competence and embryo differentiation that has been lacking so far in Passiflora.     

A comparative study of water distribution and dehydrin protein localization in maturing pea seeds

In this study, the distribution of water in pea seeds after harvesting at different seed stages was traced by magnetic resonance imaging (MRI). MRI visualized the process of water loss in maturing pea seeds. MR images showed local inhomogeneities of water distribution inside seeds. The intensity of the signal coming from water declined from the inner to the outer part of cotyledon tissue. This spatial inhomogeneity of water signals inside cotyledons may be correlated with the gradient of storage substances accumulation within cotyledons. Tissue localization of dehydrins showed the presence of dehydrin protein in the area of protovascular tissue of both the embryo axis and cotyledons. The temporal accumulation of two dehydrin proteins with molecular masses of 30 and 35kDa correlated well with seed desiccation. The pattern of dehydrin localization reflected the pattern of water distribution in the protovascular bundles region of maturing pea embryos, suggesting the involvement of these proteins in promoting water influx into the vascular bundles.