Proteins of cotyledons of mature horse chestnut seeds

This is the first characterization of proteins from storage parenchyma of cotyledons of mature dormant recalcitrant horse chestnut (Aesculus hippocastanum L.) seeds and evaluation the cell protein-synthesizing capacity. It was established that the content of protein in cotyledons did not exceed 0.5% of tissue fresh weight. Soluble proteins (the proteins of the postmitochondrial supernatant or cytosol) comprised the bulk (up to 90%) of total proteins. Protein of subcellular structures (20000 g-pellet) comprised 5–7% of total protein. Cotyledon proteins were heterogenous in their charges and molecular weights of subunits. Cotyledon protein was easily extracted with a salt (1 M NaCl); they comprised 90% of water-soluble albumin-like proteins. The proportion of globulins was insignificant; it did not exceed 5%. Most water-soluble proteins (more than 80%) were tolerant to heat denaturing. Among these heat-stable proteins, two major groups of polypeptides dominated: an electrophoretically homogeneous component with a mol wt of 24–25 kD and a complex group from three to five polypeptides with mol wts in the range between 6 and 12 kD. Native heat-stable proteins had disulfide bonds. Four fractions of heat-stable proteins were obtained by ammonium sulfate fractionation; three of them were alike in their polypeptide composition and contained major components with mol wts of 24–25 and 5–12 kD. It was established that the active translational machinery functioned in the cells of storage parenchyma in cotyledons of mature dormant horse chestnut seeds. During each stage of stratification, cotyledon fragments incorporated ³⁵S-methionine into TCA-insoluble material more actively than axial organs. We discuss cotyledon protein composition, their function as a storage organ, and a possible role of heat-stable proteins.     

Identification and characterization of dehydrins in horse chestnut recalcitrant seeds

The fraction of heat-stable dehydrins cytosolic proteins from mature recalcitrant seeds of horse chestnut (Aesculus hippocastanum L.) was studied in the period of their dormancy and germination in order to identify and characterize stress-induced dehydrin-like polypeptides. In our experiments, in tissues of dormant seeds, dehydrin was identifies by immunoblotting as a single bright band with a mol wt of about 50 kD. Low-molecular-weight heat-stable proteins with mol wts of 25 kD and below 16 kD, which were abundant in this fraction, did not cross-react with the antibody. Dehydrin was detected in all parts of the embryo: in the cells of axial organs, cotyledon storage parenchyma, and petioles of cotyledonary leaves. This indicates the absence of tissue-specificity in distribution of these proteins in the horse chestnut seeds. Dehydrins were detected among heat-stable proteins during the entire period of stratification and also radicle emersion. During radicle emergence, not only the fraction of heat-stable proteins was reduced but also the proportion of dehydrins in it decreased. In vitro germination of axes excised at different terms of stratification also resulted in dehydrin disappearance. When growth of excised axes was retarded by treatments with ABA, cycloheximide, or α-amanitin, dehydrins did not disappeared from the fraction of heat-stable proteins. When excised axes were germinated in vitro in the presence of compounds, which did not affect their growth or stimulated it (dehydrozeatin, glucose), this resulted in dehydrin disappearance. This means that dehydrin metabolism is closely related to the process of germination. Dehydrin in the horse chestnut seeds could cross-react with the antibody against ubiquitin, which can indicate the involvement of ubiquitination in the process of dehydrin degradation during germination via the proteasome system. The analysis of total proteins of the homogenate from horse chestnut seeds revealed, along with a 50-kD heat-stable dehydrin, one more component with a mol wt of 80 kD, which was located in the fraction of heat-sensitive proteins and was named as a dehydrin-like protein. It was demonstrated that dehydrins in horse chestnut seeds represented only a very small fraction of heat-stable cytosolic proteins. The role and function of major heat-stable proteins in horse chestnut seeds are yet to be studied.     

Proteins of Axial Organs of Dormant and Germinating Horse Chestnut Seeds: 1. General Characterization

This is the first characterization of proteins from axial organs of recalcitrant horse chestnut seeds during deep dormancy, dormancy release, and germination. We demonstrated that, during the entire period of cold stratification, axial organs were enriched in easily soluble albumin-like proteins and almost devoid of globulins. About 80% of the total protein was found in the cytosol. Approximately one third of cytosolic proteins were heat-stable polypeptides, which were major components of total proteins. Heat-stable proteins comprised three groups of polypeptides with mol wts of 52–54, 24–25, and 6–12 kD with a predominance of low-molecular-weight proteins. The polypeptide patterns of heat-stable and thermolabile proteins differed strikingly. Heat-stable proteins accumulated in axes during the late seed maturation, comprising more than 30% of the total protein in axes of mature seeds. The polypeptide patterns of the total protein of axial organs and its particular fractions did not change in the course of seed dormancy and release. At early germination, the content of heat-stable proteins in axes decreased and their polypeptide pattern changed both in the cytosol and cell structures. We believe that at least some heat-stable proteins can function as storage proteins in the axes. Localization of storage proteins in the cells of axial organs and the role of heat-stable proteins in recalcitrant seeds are discussed.     

Hormonal Complex and Ultrastructure of Maturing Aesculus hippocastanum Seeds

The content and temporal changes in the endogenous IAA, cytokinins, gibberellin-like compounds (GLC), and ABA were determined during horse chestnut (Aesculus hippocastanum L.) seed development (the stages of embryo axis development, its active growth, and storage compound deposition). The active growth of the embryo was characterized by the highest amounts of free phytohormones. Later, by the end of seed maturation, we observed the accumulation of the bound forms of IAA and ABA and a trend to a decrease in the content of free IAA, zeatin, and GLC (butanol fraction). The electron-microscopic examination of the embryo from the mature seed demonstrated that some structural components of the cytoplasm were similar in the cells of embryo axes and cotyledons. During the entire period of maturation, the embryo cells preserved native vacuoles and protein bodies were not formed. Thus, the structure of cotyledonary and axial cells and the distribution of free and bound phytohormones in the horse-chestnut seeds are similar to those in maturing seeds characterized by exogenous dormancy.     

Water relations in germinating seeds

Life strategy of plants depends on successful seed germination in the available environment, and sufficient soil water is the most important external factor. Taking into account a broad spectrum of roles played by water in seed viability and its maintenance during germination, the review embraces early germination events in seeds different in their water status. Two seed types are compared, namely orthodox and recalcitrant seeds, in terms of water content in the embryonic axes, vacuole biogenesis, and participation of water channels in membrane water transport. Mature orthodox seeds desiccate to low water content and remain viable during storage, whereas mature recalcitrant seeds are shed while well hydrated but die during desiccation and cannot be stored. In orthodox Vicia faba minor air-dry seeds remaining viable at 8–10% water content in embryonic axes, the vacuoles in hypocotyl are preserved as protein storage vacuoles, then restored to vacuoles in imbibing seeds in the course of protein mobilization. However, in newly produced meristematic root cells, the vacuoles are formed de novo from provacuoles. In recalcitrant Aesculus hippocastanum seeds, embryonic axes have a water content of 63–64% at shedding and they lack protein storage vacuoles but preserve vacuoles preformed in maturing seeds. Independent of the vacuolar biogenetic patterns, their further trend is similar; they expand and fuse, thus producing an osmotic compartment, which precedes and becomes an obligatory step for the initiation of cell elongation. Prior to this, water moves in imbibing seeds through the membranes by diffusion, although the aquaporins forming water channels are present. In both seed types, water channels are opened and actively participate in water transport only after growth initiation. Aquaporin gene expression and their composition change in broad bean embryonic axes after growth initiation. This is the way how a mass water flow into growing seedling cells is achieved, independent of differences in seed water content and vacuole biogenesis patterns.     

Biogenesis of Protein Bodies in Embryonic Axes of Soybean Seeds (Glycine max. cv. Enrei)

Protein bodies in embryonic axes of soybean seeds have inclusion structures containing phytin globoids. Biogenesis of the protein bodies during seed development was examined by transmission electron microscopy. Protein bodies in embryonic axes originated from central vacuoles. The central vacuole in embryonic axes subdivided into smaller vacuoles with internal membranous structure. Then the subdivided vacuoles were directly associated with rough endoplasmic reticulum (rER), and were filled with proteinaceous matrix from the peripheral region. The increase of matrix was simultaneous with accumulation of β-conglycinin estimated by SDS-polyacrylamide gel electrophoresis. Glycinin-rich granules that had been found in developing cotyledons were not observed in embryonic axes. After proteinaceous matrix filled the protein bodies, electron-transparent regions presumably surrounded by a single membrane appeared in the matrix. Phytin globoids were constructed in this internal structures of protein bodies as the final step of protein body formation.     

Seed protein fraction electrophoresis in peanut (<Emphasis Type="Italic">Arachis hypogaea</Emphasis> L.) accessions and wild species

Total seed storage proteins were studied in 50 accessions of A. hypogaea (11 A. hypogaea ssp. hypogaea var hypogaea, 13 A. hypogaea ssp. hypogaea var hirsuta, 11 A. hypogaea ssp. fastigiata var fastigiata and 15 A. hypogaea ssp. fastigiata var. vulgaris accessions) in SDS PAGE. These accessions were also analysed for albumin and globulin seed protein fractions. Among the six seed protein markers presently used, it was found that globulin fraction showed maximum diversity (77.2%) in A. hypogaea accessions followed by albumin (52.3%), denatured total soluble protein fraction in embryo (33.3%) and cotyledon (28.5%). The cluster analysis based on combined data of cotyledons, embryos, albumins and globulins seed protein fractions demarcated the accessions of two subspecies hypogaea and fastigiata into two separate clusters supported by 51% bootstrap value, with few exceptions, suggesting the genotypes to be moderately diverse. Native and denatured total soluble seed storage proteins were also electrophoretically analysed in 27 wild Arachis species belonging to six sections of the genus. Cluster analysis using different methods were performed for different seed proteins data alone and also in combination. Section Caulorrhizae (C genome) and Triseminatae (T genome) formed one, distantly related group to A. hypogaea and other section Arachis species in the dendrogram based on denatured seed storage proteins data. The present analysis has maintained that the section Arachis species belong to primary and secondary genepools and, sections Procumbenetes and Erectoides belong to tertiary gene pools.     

Acid vacuolar invertase in dormant and germinating seeds of the horse chestnut

A high water content is maintained in the tissues of the axial organs of horse chestnut seeds after the fruit is shed and down to the time the seeds germinate. The plant cell vacuoles, features of whose metabolism can influence the cells’ preparation to initiate growth in germination, are preserved. It was shown that the activity of acid invertase and its capacity to hydrolyze both sucrose and raffinose remain stable throughout the period of dormancy and the transition to germination, as do the molecular weight of its subunits (63 and 65 kDa) and multimer (500 to 550 kDa). The activity of the enzyme increases when the seeds swell under optimal conditions for germination; this is associated with the synthesis of new molecules of the enzyme in long-lived mRNA templates. The storability of the enzyme in the vacuoles of dormant seeds, together with the increase in its activity when seeds coming out of dormancy swell, ensures the rapid hydrolysis of sucrose issuing from the seeds’ cotyledons, thus leading to increased osmotic pressure and, as a result, the beginning of cell elongation, i.e., germination.     

Cytological aspects of recalcitrance in dormant seeds of <Emphasis Type="Italic">Mauritia flexuosa</Emphasis> (Arecaceae)

We evaluated the physiological and cytological aspects of the embryos of the palm tree Mauritia flexuosa, whose seeds show a rare association of recalcitrance and dormancy. Seeds were subjected to dehydration, or stored with stabilized water contents for 420 days. Seed viability and germination, as well as the anatomy, cytochemistry and ultrastructure of the embryos were evaluated using standardized methodologies. Under initial conditions (seeds with water contents of 44.6 %), viability was as high as 94 %, although without germination. Seeds dehydrated to water contents of 20 % lost all viability, whereas 87 % of the seeds stored while hydrated remained viable and 25 % germinated. Embryonic cells showed characteristics associated with recalcitrance in other palms species, such as the presence of large vacuoles and the absence of lipidic reserves, but also had abundant protein bodies and terpenoids in their cytoplasm as well as carbohydrate and protein reserves in their vacuoles—conditions found in the embryo cells of palms having orthodox seeds. Dehydration caused invagination of the cell walls, retraction of the plasma membrane, proliferation of the endoplasmic reticulum and autophagic vacuoles, and increased the densities of vacuolar contents—culminating in the collapse of the protoplast. Stored seeds showed preserved cell structures. M. flexuosa seeds are sensitive to dehydration, but will retain viability if kept hydrated, allowing dormancy to be overcome in seed banks in the swampy soils where this species occurs. The accumulations of secondary metabolites, vacuolation and the storage of carbohydrates and proteins in the vacuole all have important roles in the modulation of recalcitrance.     

Storage reserves and cellular water in mature seeds of Araucaria angustifolia

Seed tissues of Araucaria angustifolia (Bertol.) Kuntze were investigated using histochemistry, transmission electron microscopy (TEM) and energy dispersive X-ray (EDX) analysis. Moisture content and water status in tissues were also evaluated. In the embryo, TEM studies revealed the presence of one to several central vacuoles and a peripheral layer of cytoplasm in cells from different tissues of the cotyledons and axis. In the cytoplasm, lipid bodies, starch grains, mitochondria and a nucleus are evident. In most tissues, vacuoles contain proteins, indicating that the storage proteins are highly hydrated. In cells of the root cap, proteins are stored in discrete protein bodies. Both protein storage vacuoles and discrete protein bodies have inclusions of crystal globoids. EDX analysis of globoids revealed the presence of P, K and Mg as the main constituents and traces of S, Ca and Fe. In the root and shoot meristems, deposits of phytoferritin are present in the stroma of proplastids. The gametophyte consists of cells characterized by relatively thin cell walls and one to several nuclei per cell. Protein and lipid bodies are present, although starch is the most conspicuous reserve. Immediately after shedding, moisture content is approximately 145% (dry weight) for the embryo and 95% (dry weight) for the gametophyte. Calorimetric studies reveal that axes and cotyledons have a very high content of freezable water, corresponding to types 5 and 4, i.e. dilute and concentrated (or capillary) solution, respectively. The results are discussed in relation to the behaviour of the species, which has been categorized as recalcitrant.  © 2002 The Linnean Society of London . Botanical Journal of the Linnean Society , 2002, 140 , 273−281.     

A comparison of partial dehydration and hydrated storage-induced changes in viability,reactive oxygen species production,and glutathione metabolism in two contrasting recalcitrant-seeded species

This study compared the responses of Avicennia marina and Trichilia dregeana seeds, both of which are recalcitrant, to partial dehydration and storage. Seeds of A. marina exhibited a faster rate of water and viability loss (± 50% viability loss in 4 days) during partial dehydration, compared with T. dregeana (± 50% viability loss in 14 days). In A. marina embryonic axes, reactive oxygen species (ROS) production peaked on 4 days of dehydration and was accompanied by an increase in the GSH:GSSG ratio; it appears that the glutathione system alone could not overcome dehydration-induced oxidative stress in this species. In A. marina, ROS and axis water content levels increased during hydrated storage and were accompanied by a decline in the GSH:GSSG ratio and rapid viability loss. In T. dregeana embryonic axes, ROS production (particularly hydrogen peroxide) initially increased and thereafter decreased during both partial dehydration and hydrated storage. Unlike in A. marina embryonic axes, this reduced ROS production was accompanied by a decline in the GSH:GSSG ratio. While T. dregeana seeds may have incurred some oxidative stress during storage, a delay in and/or suppression of the ROS-based trigger for germination may account for their significantly longer storage longevity compared with A. marina. Mechanisms of desiccation-induced seed viability loss may differ across recalcitrant-seeded species based on the rate and extent to which they lose water during partial drying and storage. While recalcitrant seed desiccation sensitivity and, by implication, storage longevity are modulated by redox metabolism, the specific ROS and antioxidants that contribute to this control may differ across species.     

The pharmaceutics from the foreign empire: the molecular pharming of the prokaryotic staphylokinase in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> plants

Here, we present the application of microbiology and biotechnology for the production of recombinant pharmaceutical proteins in plant cells. To the best of our knowledge and belief it is one of few examples of the expression of the prokaryotic staphylokinase (SAK) in the eukaryotic system. Despite the tremendous progress made in the plant biotechnology, most of the heterologous proteins still accumulate to low concentrations in plant tissues. Therefore, the composition of expression cassettes to assure economically feasible level of protein production in plants remains crucial. The aim of our research was obtaining a high concentration of the bacterial anticoagulant factor—staphylokinase, in Arabidopsis thaliana seeds. The coding sequence of staphylokinase was placed under control of the β-phaseolin promoter and cloned between the signal sequence of the seed storage protein 2S2 and the carboxy-terminal KDEL signal sequence. The engineered binary vector pATAG-sak was introduced into Arabidopsis thaliana plants via Agrobacterium tumefaciens-mediated transformation. Analysis of the subsequent generations of Arabidopsis seeds revealed both presence of the sak and nptII transgenes, and the SAK protein. Moreover, a plasminogen activator activity of staphylokinase was observed in the protein extracts from seeds, while such a reaction was not observed in the leaf extracts showing seed-specific activity of the β-phaseolin promoter.     

Localization of a metalloproteinase and its inhibitor in the protein bodies of buckwheat seeds

Cotyledons of dry buckwheat (Fagopyrum esculentum Moench) seeds were used to study the cellular localization of a metalloproteinase which performs in vitro the initial limited proteolysis of the main storage protein of the seed, and of its proteinaceous inhibitor. Fractions of complex protein bodies (PB 1) and of the cytoplasm and membrane material (CMM) were obtained by fractionating cotyledons in a mixture of acetone and CCl₄. The greater part of the metalloproteinase activity was found to be localized in the PB 1 fraction, with a lesser amount in the CMM fraction, whereas the metalloproteinase inhibitor was localized almost entirely in the PB 1 fraction. The data obtained indicate that the complex protein bodies of dry buckwheat seeds contain the components of the proteolytic system responsible for the initial degradation of the main storage protein — the 13S globulin — of buckwheat seeds, i.e. 13S globulin, the metalloproteinase, and its inhibitor. This confirms that it is possibile for the metalloproteinase to perform a controlled proteolysis of the 13S globulin in vivo. The effect of divalent cations on the degradation of the 13S globulin was also studied. A mechanism is discussed whereby the proteolysis of 13S globulin is initiated by divalent cations released as a result of phytin decationization during seedling growth.Abbreviations CMM cytoplasm and membrane material - PAGE polyacrylamide gel electrophoresis - PB 1 complex protein bodies with globoids     

Origin and development of protein bodies in cotyledons of Vicia faba

Storage proteins of the field bean (Vicia faba L., var. minor, cv. “Fribo”) are synthesized and accumulated in the cotyledons during stage 2 of seed development. Deposition of protein reserves takes place in the protein bodies. The generation of protein bodies was investigated electronmicroscopically using ultra-thin sections as well as the freeze-fracturing technique. During the initial period of storage protein formation, globulins are deposited in large vacuoles which later are transformed to give increasing numbers of small vacuoles with decreasing size. The vacuoles disappear early during the stage of storage protein formation and generate the first protein bodies. During the subsequent period of maximum storage protein formation, which takes place at the rough endoplasmic reticulum (rER), swollen ER strands appear which seem to be entirely filled with protein, and these generate ER-produced protein vacuoles (ERPVAC). The vesicles are transformed in a manner comparable to the vacuoles in the initial period of developmental stage 2 and thus generate the major quantity of protein bodies. Both processes seem to represent only two variants of an uniform mechanism of protein body generation.     

Identification of an oleosin-like gene in seagrass seeds

Objective

To investigate the oil body protein and function in seeds of mature seagrass, Thalassia hemprichii.

Results

Seeds of mature seagrass T. hemprichii when stained with a fluorescent probe BODIPY showed the presence of oil bodies in intracellular cells. Triacylglycerol was the major lipid class in the seeds. Protein extracted from seagrass seeds was subjected to immunological cross-recognition with land plant seed oil body proteins, such as oleosin and caleosin, resulting in no cross-reactivity. An oleosin-like gene was found in seagrass seeds. Next generation sequencing and sequence alignment indicated that the deduced seagrass seed oleosin-like protein has a central hydrophobic domain responsible for their anchoring onto the surface of oil bodies. Phylogenetic analysis showed that the oleosin-like protein was evolutionarily closer to pollen oleosin than to seed oleosins.

Conclusion

Oil body protein found in seagrass seeds represent a distinct class of land seed oil body proteins.

     

Stored proteinases and the initiation of storage protein mobilization in seeds during germination and seedling growth

Though endopeptidases and carboxypeptidases are present in protein bodies of dry quiescent seeds the function of these proteases during germination is still a matter of debate. In some plants it was demonstrated that endopeptidases of dry protein bodies degrade storage proteins of these organelles. Other studies describe cases where this did not happen. The role that stored proteinases play in the initiation of storage protein breakdown in germinating seeds thus remains unclear. Numerous reviews state that the initiation of reserve protein mobilization is attributed to de novo formed endopeptidases which together with stored carboxypeptidases degrade the bulk of proteins in storage organs and tissues after seeds have germinated. The evidence that the small amounts of endopeptidases in protein bodies of embryonic axes and cotyledons of dry seeds from dicotyledonous plants play an important role in the initiation of storage protein mobilization during early germination is summarized here.     

Protein bodies of seeds: Ultrastructure,biochemistry, biosynthesis and degradation

Typical organelles for protein storage occur in seeds, protein bodies are found in haploid, diploid or triploid tissues and are single membrane bound. In some plants, they exhibit inclusions (globoid and crystalloid), but not in Gramineae endosperm or in Leguminosae cotyledons. A relationship between species and protein body ultrastructure can be put forward. The chemical composition is based mainly on storage proteins and phytic acid but, hydrolytic enzymes(protease and phytase), cations and ribonucleic acids are also present. Other minor biochemical components include oxalic acid, carbohydrates (excluding starch) and lipids. The locations of the storage proteins, enzymes and phytin are described. Protein body ontogeny during seed maturation has given rise to much controversy: are they plastidic or vacuolar? Recent studies on the location of proteosynthesis show that protein bodies are probably synthesized in endoplasmic reticulum lumen and that the Golgi apparatus plays an important role in storage protein synthesis. During germination protein bodies swell and fuse, giving rise to the cell central vacuole, while the integrity of the membrane is maintained. Protein bodies may be considered as being an example of tonoplast origin from endo-plasmic reticulum.