A histological and histochemical study of the cotyledons ofPhaseolus vulgaris L. during germination

Summary The cotyledon ofPhaseolus vulgaris L. comprises four tissues: epidermis, abaxial hypodermis, storage parenchyma, and procambium. A complex intercellular space system is present throughout the storage tissue and comprises about 16% of the cotyledon volume. All the cells contain protein bodies, and the hypodermis and storage parenchyma also contain starch grains. The epidermal cells are at the 2 C level of DNA, those of the hypodermis at the 4 C level, and the storage cells vary from 8 C to 32 C. During germination stomata differentiate in the epidermis. Reserve mobilization begins in the cells furthest from the epidermis and from the vascular tissue. Protein is removed from these cells with little or no coalescence of protein bodies. The DNA content of the nuclei decreases. The cell walls swell and then decrease in thickness as material is removed. Finally the nuclei and cytoplasm disappear and the cells collapse. In the cells near vascular bundles the protein bodies coalesce before losing their protein. The DNA content of the nuclei declines but nuclei and cytoplasm are still present at abscission. These cells do not collapse. Cytoplasmic RNA content is highest near the abaxial surface. Most of the RNA is removed during the first three days of germination.     

Histochemical and ultrastructural changes in the haustorium of date (Phoenix dactylifera L.)

Summary During imbibition ofPhoenix dactylifera embryos, all cotyledon cells show the same changes: protein and lipid bodies degrade, smooth endoplasmic reticulum (ER) increases in amount, and dictyosomes appear. At germination, the distal portion of the cotyledon expands to form the haustorium. At this time, epithelial cells have a dense cytoplasm with many extremely small vacuoles. Many ribosomes are present along with ER, dictyosomes, and mitochondria. The parenchyma cells have large vacuoles and a small amount of peripheral cytoplasm. Between 2 and 6 weeks after germination, epithelial cells still retain the dense cytoplasm and many organelles appear: glyoxysomes, large lipid bodies, amyloplasts, large osmiophilic bodies, and abundant rough and smooth ER which appear to merge into the plasmalemma. A thin electron-transparent inner wall layer with many small internal projections is added to the cell walls. Starch grains appear first in the subsurface and internal parenchyma and subsequently in the epithelium. Lipid bodies, glyoxysomes, protein, and osmiophilic bodies occur in the epithelial and subepithelial cell layers but not in the internal parenchyma. At 8 weeks after germination, the cytoplasm becomes electron transparent, vacuolation occurs, lipid bodies and osmiophilic bodies degrade, and the endomembranes disassemble. After 10 weeks, the cells are empty. These data support the hypothesis that the major functions of the haustorium are absorption and storage.     

Immunocytochemical localisation of lectins in cells of Phaseolus vulgaris L. seeds

Antibodies against pure E₄- and L₄-lectins from the seeds of Phaseolus vulgaris L. raised in rabbits were made monospecific by immunoaffinity chromatography on E₄- or L₄-lectin Sepharose 4B columns. Localisation of lectins in bean seeds was investigated by indirect immunofluorescence and by electron microscopy on sections stained with colloidal gold particles coated with monospecific anti-E₄- and anti-L₄-IgG. In parenchyma cells from the cotyledons both E- and L-type lectins were found inside the protein bodies. Apparently the matrix of all protein bodies contained both types of lectins. On the other hand in vascular and in axis cells the two types of lectins were localised in the cytoplasm, outside the protein bodies. Thus these findings suggest different roles for the lectins: in cotyledons this may be a specific form of N storage, while in vascular and axis cells lectins may have a more direct metabolic part to play.     

Localization of lipoxygenases 1 and 2 in germinating soybean seeds by an indirect immunofluorescence technique

Lipoxygenases 1 and 2 were localized in etiolated germinating soybean seeds (Glycine max [L.]. Merr. var. Williams) by an indirect immunofluorescence staining technique. Sections of paraffin-embedded seedlings were stained with affinity-purified antibodies directed against lipoxygenase 1 or 2. The specificity of the immunofluorescence technique was examined by use of nonimmune serum or immunoglobulin G preparations after total adsorption with the appropriate lipoxygenase coupled to Sepharose 4B.

After immunofluorescence staining with antilipoxygenase 1 or 2 IgG storage tissues of cotyledons fluoresce strongly the first days of germination. After 3 days, the abaxial hypodermis, the epidermis, and the vascular bundle sheaths show fluorescence, especially after incubation with antilipoxygenase 2 IgG. Fluorescence in cortex and pith of the hypocotyl migrates to the vascular cylinder during germination. In primary leaves, all tissues show fluorescence after 1 day of germination. In storage tissues of cotyledons, cytoplasm around the protein bodies fluoresces, whereas in other tissues protein bodies or other large cell organelles fluoresce.

It is reasonable to suggest that lipoxygenase exerts its function in cells at the time that rigorous changes in metabolism take place, namely at the start of mobilization of reserves in storage tissues and start of biosynthesis of chloroplastids in several tissues.

     

Subcellular Localization Studies Indicate That Lipoxygenases 1 to 6 Are Not Involved in Lipid Mobilization during Soybean Germination

Soybean (Glycine max) lipoxygenase (LOX) has been proposed to be involved in reserve lipid mobilization during germination. Here, subcellular fractionation studies show that LOX1, -2, -3, -4, -5, and -6 isozymes were associated with the soluble fraction but not with purified oil bodies. The purified oil bodies contained small amounts of LOX1 (<0.01% total activity), which apparently is an artifact of the purification process. Immunogold labeling indicated that, in cotyledon parenchyma cells of LOX wild-type seeds that had soaked and germinated for 4 d, the majority of LOX protein was present in the cytoplasm. In 4-d-germinated cotyledons of a LOX1/2/3 triple null mutant (L0), a small amount of label was found in the cytoplasm. In epidermal cells, LOX appeared in vacuoles of both wild-type and L0 germinated seeds. No LOXs cross-reacting with seed LOX antibodies were found to be associated with the cell wall, plasma membrane, oil bodies, or mitochondria. Lipid analysis showed that degradation rates of total lipids and triacylglycerols between the wild type and L0 were not significantly different. These results suggest that LOX1, -2, -3, -4, -5, and -6 are not directly involved in reserve lipid mobilization during soybean germination.     

Localization of phytohemagglutinin in the embryonic axis of Phaseolus vulgaris with ultra-thin cryosections embedded in plastic after indirect immunolabeling

We have examined the properties and subcellular localization of phytohemagglutinin (PHA), the major lectin of the common bean (Phaseolus vulgaris.), in the axis cells of nearly mature and imbibed mature seeds. On a protein basis the axis contained about 15% as much PHA as the cotyledons. Localization of PHA was done with an indirect immunolabeling method (rabbit antibodies against PHA, followed by colloidal gold particles coated with goat antibodies against rabbit immunoglobulins) on ultra-thin cryosections which were embedded in plastic on the grids after the immunolabeling procedure. The embedding greatly improved the visualization of the subcellular structures. The small (4 nm) collodial gold particles, localized with the electron microscope, were found exclusively over small vacuoles or protein bodies in all the cell types examined (cortical parenchyma cells, vascular-bundle cells, epidermal cells). The matrix of these vacuoles-protein bodies appears considerably less dense than that of the protein bodies in the cotyledons, but the results confirm that in all parts of the embryo PHA is localized in similar structures.Abbreviations IgG immunoglobulin G - M_r relative molecular weight - PBS phosphate-buffered saline - PHA phytohemagglutinin - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis     

Nucleolin, defective for MPF phosphorylation, localizes normally during mitosis and nucleologenesis

To determine what effect maturation promoting factor (MPF, p34 ^cdc2 kinase/cyclin B) phosphorylation has on nucleolin’s distribution during mitotic nucleolar disassembly and reassembly, we altered Chinese hamster ovary (CHO) nucleolin (the N protein) such that it cannot be phosphorylated by p34 ^cdc2 . As expected, the transiently expressed epitope-tagged N protein showed no apparent defect in nucleolar localization in interphase CHO cells, even after hypotonic shock and recovery to quickly disassemble and then reassemble interphase nucleoli. In mitotic CHO cells, the N protein localized to the perichromosomal sheath and the cytoplasm, as is typical for nucleolin. Similar to epitope-tagged wild-type nucleolin, the N protein also maintained its association with persistent nucleoli characteristic of mitotic Chinese hamster lung (Dede) cells. In synchronized HeLa cells, the N protein again localized to the perichromosomal sheath and the cytoplasm as nucleoli disassembled during prophase. In HeLa cell telophase, the N protein localized normally to nucleolus-derived foci within the cytoplasm and prenucleolar bodies within reforming nuclei. The observations indicate that MPF phosphorylation is not essential for nucleolin’s localizations to the perichromosomal sheath and the cytoplasm during prophase and metaphase, and that functional MPF phosphorylation sites are not essential for nucleolin’s localizations during nucleologenesis. Accepted: 15 April 1999     

Localization of vicilin peptidohydrolase in the cotyledons of mung bean seedlings by immunofluorescence microscopy

Vicilin peptidohydrolase, the protease that hydrolyzes the reserve proteins in the cotyledons of mung bean (Vigna radiata) seedlings, has been localized intracellularly by immunofluorescence microscopy using monospecific antibodies against the enzyme and rhodamine-coupled goat-anti-rabbit immunoglobulin G's. The enzyme can first be visualized after 3 days of seedling growth and is associated with small foci within the cytoplasm of the storage parenchyma cells farthest from the vascular bundles. On the 4th day of growth, the protease is also present in the numerous large protein bodies within these cells. Vicilin peptidohydrolase is known to be synthesized de novo starting on the 3rd day of growth. Our observations are therefore consistent with the interpretation that the enzyme is synthesized in the cytoplasm and subsequently transported to the protein bodies.     

QUANTITATIVE ULTRASTRUCTURE AND PROTEIN COMPOSITION OF DATE PALM (PHOENIX DACTYLIFERA) SEEDS: A COMPARATIVE STUDY OF ENDOSPERM VS. EMBRYO

Comparative studies on the ultrastructure and protein composition of the embryo and endosperm of date palm (Phoenix dactylifera L.) were conducted. Cells of the embryo cotyledon and endosperm function in reserve storage and contained cell walls, nuclei, and cytoplasm rich in lipid and protein bodies. Morphometric analysis from light and electron micrographs showed that the cell walls of the endosperm occupied 65% of the total cell volume, but only 6% in the embryo. The protein bodies of the endosperm accounted for 11%, whereas those of the embryo occupied more than half of the total cell volume. The volume of organelles and organelle-free cytoplasm in the endosperm was negligible, suggesting that most of the extractable endosperm proteins are localized in the protein bodies. Extractable proteins in the embryo may come from cytoplasm, protein bodies, and other organelles. The endosperm contains relatively lower amounts of proteins than does the embryo. Proteins extracted from both tissues were compared using SDS-polyacrylamide gel electrophoresis, tube gel isoelectric focusing, and two-dimensional electrophoresis. Proteins of both the tissues were heterogeneous in molecular mass and charge. The majority of the proteins were similar in molecular mass and charge in the two tissues, suggesting that most of the storage proteins are probably the same. However, there were also several embryo- and endosperm-specific proteins apparent in both the first- and second-dimension gels. The endosperm-specific proteins may play an important role in germination and seedling development.     

黄瓜种子萌发过程中Ca~(2 )分布的变化

采用细胞化学方法 ,研究了黄瓜种子中贮藏Ca2 的分布特点及其在萌发过程中的变化动态。干种子的子叶细胞中贮藏有大量的蛋白体、油脂体 ,Ca2 沉淀颗粒大量分布于胞质、胞间隙以及细胞质膜上。大多数蛋白体中有 1至数个圆球形或椭圆体形含Ca2 的球状晶体。相比之下 ,胚芽和胚根细胞中Ca2 较少。种子萌发早期 ,子叶中的贮藏钙及晶体溶解释放出的Ca2 部分转运到生长发育中的胚芽和胚根中。随着萌发的继续 ,胚根和胚芽细胞中的Ca2 不会持续增多 ,反而下降     

Subcellular localization of the 2S globulin narbonin in seeds of Vicia narbonensis

Narbonin is a 2S protein from the globulin fraction of narbon bean (Vicia narbonensis L.) cotyledons. Its amino acid composition and the pattern of its regulated accumulation in developing seeds led to the suggestion that narbonin could be a storage protein. Therefore, it was expected to be present in protein bodies of the storage tissue cells. Comparison of the cDNA-derived amino acid sequence with a directly determined partial N-terminal sequence revealed that the primary translation product of narbonin mRNA lacks a transient N-terminal signal peptide (V.H. Nong et al., 1995, Plant Mol Biol 28: 61–72). Narbonin polypeptides that had been synthesized in a cell-free translation system supplemented with dog pancreas microsomes were not protected against degradation by posttranslationally added proteases (protease protection assay). In accordance with the lack of a signal peptide this indicates that the polypeptide was not cotranslationally sequestered into the microsomes. The protein-body fraction that had been isolated from mature narbon bean cotyledons by a non-aqueous gradient centrifugation procedure was free of narbonin; this was found in the soluble cell fraction. In electron micrographs, narbonin could be localized in the cytoplasm using the immuno gold-labelling technique. Previously, it had already been shown that narbonin is too slowly degraded during narbon bean germination to act as a storage protein. From all these results it has to be concluded that narbonin is a cytoplasmic protein which does not belong to the storage proteins in the restricted sense. Other possible functions are discussed. Received: 18 November 1996 / Accepted: 28 February 1997     

Accumulation of plant small heat-stress proteins in storage organs

Plant small heat-stress proteins (sHSPs) have been shown to be expressed not only after exposure to elevated temperatures, but also at particular developmental stages such as embryogenesis, microsporogenesis, and fruit maturation. This paper presents new data on the occurrence of sHSPs in vegetative tissues, their tissue-specific distribution, and cellular localization. We have found sHSPs in 1-year-old twigs of Acer platanoides L. and Sambucus nigra L. and in the liana Aristolochia macrophylla Lamk. exclusively in the winter months. In tendrils of Aristolochia, sHSPs were localized in vascular cambium cells. After budding, in spring, these proteins were no longer present. Furthermore, accumulation of sHSPs was demonstrated in tubers and bulbs of Allium cepa L., Amaryllis ( Hippeastrum hybridum hort.), Crocus albiflorus L., Hyacinthus orientalis L., Narcissus pseudonarcissus L., Tulipa gesneriana L., and Solanum tuberosum L. (potato). In potato tubers and bulb scales of Narcissus the stress proteins were localized in the central vacuoles of storage parenchyma cells. In order to obtain more information on a possible functional correlation between storage proteins and sHSPs, the accumulation of both types of protein in tobacco seeds during seed ripening and germination was monitored. The expression of sHSPs and globulins started simultaneously at about the 17th day after anthesis. During seed germination the sHSPs disappeared in parallel with the storage proteins. Furthermore, in embryos of transgenic tobacco plants, which do not contain any protein bodies or storage proteins, no sHSPs were found. Thus, the occurrence of sHSPs in perennial plant storage organs seems to be associated with the presence of storage proteins.     

Histology and histochemistry of the cotyledons of pisum arvense L. during germination

Summary The mature cotyledon of Pisum arvense L. comprises several distinct tissue regions; these are the epidermis, hypodermis, storage parenchyma and procambium. The storage parenchyma includes two zones: an outer abaxial zone and an inner adaxial zone. The cells of both zones contain abundant starch grains and protein bodies. Scattered through the storage tissue but increasing in frequency towards the periphery are certain cells which differ to a slight extent from the majority of the parenchyma cells. They have a more opaque, granular cytoplasm and a higher level of cytoplasmic RNA. the cotyledon has a complex, reticulate vascular system. Differentiation of the conducting elements from the procambium appears to begin about 12 hours and to be completed 48 hours after the commencement of imbibition. Differentiation of phloem preceeds that of xylem. The relationship between the timing of vascular differentiation and various physiological events in the cotyledon is discussed.Mobilization of the reserves in the storage parenchyma is initiated at the periphery of the cotyledon and proceeds inwards. There appears to be a correlation between the breakdown of the reserves and changes in DNA and RNA content of the cells.     

Correlated in situ hybridisation and immunochemical studies of legumin storage protein deposition in pea (Pisum sativum L.)

Legumin and vicilin are the major globulin seed storage proteins of pea. They are synthesised predominantly in the cotyledons where they are sequestered within membrane-bounded vacuolar protein bodies. In situ hybridisation histochemistry, with both biotinylated and ³⁵S-labelled cDNA probes, has been used to visualise the temporal and spatial patterns of distribution of legumin and vicilin mRNAs during seed development. These patterns have been compared with those of storage protein deposition which have been determined by immunocytochemistry. Results indicate that within the cotyledons high levels of legumin and civilin mRNAs are restricted to the storage parenchyma tissues, whilst the epidermal cells and vascular parenchyma do not show such accumulation. The tissues of the embryo axis also show differential levels of expression, although where present the levels of mRNAs appear much lower than in the cotyledons. Throughout the embryo the patterns shown by in situ hybridisation are similar to those shown by immunocytochemistry, although the transient endosperm of early seed development does not show such a correlation.     

Seasonally fluctuating bark proteins are a potential form of nitrogen storage in three temperate hardwoods

The inner bark tissues of three temperate hardwoods contain specific proteins which undergo seasonal fluctuations. Increases in particular proteins, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, occur within the bark of several Acer, Populus and Salix spp. during late summer and early autumn. These proteins are abundant in the bark throughout the winter and their levels decline the following spring. Light and electron microscopy showed that the parenchyma cells of the inner bark are packed with spherical organelles throughout the overwintering period. These organelles are rich in protein and analogous to protein bodies found in cells of mature seeds. The protein bodies of the parenchyma cells are replaced by large central vacuoles during spring and summer, presumably as a result of the mobilization of the storage protein and fusion of the protein bodies. The high levels of specific proteins in inner bark tissues and the presence of protein bodies within the parenchyma cells indicate that the living cells of the bark act as a nitrogen reserve in overwintering temperate hardwoods.Abbreviations FW fresh weight - kDa kilodalton - M _r relative molecular mass     

GIBBERELLIC ACID-INDUCED GERMINATION OF SPORES OF ANEMIA PHYLLITIDIS: NUCLEIC ACID AND PROTEIN SYNTHESIS DURING GERMINATION

The distribution and synthesis of nucleic acids and proteins during gibberellic acid-induced germination of spores of Anemia phyllitidis were studied in order to relate biochemical activity with morphogenetic aspects of germination. Germination is accompanied by the hydrolysis of storage protein granules and the localized appearance of cytoplasmic RNA, protein, and insoluble carbohydrates in a small area adjoining the spore wall and surrounding the nucleus. The protoplast of the spore enlarges in this region, the spore wall breaks and a protonemal cell is formed which contains many chloroplasts. A second division in the spore at right angles to the first yields a rhizoid cell. Autoradiography of ³H-thymidine incorporation has shown that DNA is synthesized both in the nucleus and in the immediately surrounding cytoplasm of the germinating spore until some time after the first division, although a strictly nuclear DNA synthesis is observed later. Synthesis of RNA and proteins is limited to the presumptive regions of the germinating spore which become the protonema and rhizoid, shifting to specific sites in these cells as germination proceeds. The nucleus of the spore continues to be biosynthetically active long after it ceases to divide.     

Protein storage vacuole acidification as a control of storage protein mobilization in soybeans

Soybean protease C1 (EC 3.4.21.25), the subtilisin-like serine protease that initiates the proteolysis of seed storage proteins in germinating soybean [Glycine max (L.) Merrill], was localized to the protein storage vacuoles of parenchyma cells in the cotyledons by immunoelectron microscopy. This was demonstrated not only in germination and early seedling growth as expected, but also in two stages of protein storage vacuole development during seed maturation. Thus, the plant places the proteolytic enzyme in the same compartment as the storage proteins, but is still able to accumulate those protein reserves. Since soybean protease C1 activity requires acidic conditions for activity, the hypothesis that the pH condition in the protein storage vacuole would support protease C1 activity in germination, but not in seed maturation, was tested. As hypothesized, acridine orange accumulation in the protein storage vacuole of storage parenchyma cells was detected by fluorescence confocal microscopy in seedlings before the onset of mobilization of reserve proteins as noted by SDS-PAGE. Accumulation of the dye was reversed by inclusion of the weak base methylamine to dissipate the pH gradient across the vacuolar membrane. Also as hypothesized, acridine orange did not accumulate in the protein storage vacuole of those parenchyma cells during seed maturation. These results were obtained using cells separated by pectolyase treatment and also using cotyledon slices.     

Protein metalation by metal-based drugs: reactions of cytotoxic gold compounds with cytochrome?c and lysozyme

Protein metalation processes are crucial for the mechanism of action of several anticancer metallodrugs and warrant deeper characterisation. We have explored the reactions of three cytotoxic gold(III) compounds??namely [(bipy^2Me)₂Au₂(??-O)₂][PF₆]₂ (where bipy^2Me is 6,6??-dimethyl-2,2??-bipyridine) (Auoxo6), [(phen^2Me)₂Au₂(??-O)₂][PF₆]₂ (where phen^2Me is 2,9-dimethyl-1,10-phenanthroline) (Au₂phen) and [(bipy^dmb-H)Au(OH)][PF₆] [where bipy^dmb-H is deprotonated 6-(1,1-dimethylbenzyl)-2,2??-bipyridine] (Aubipyc)??with two representative model proteins, i.e. horse heart cytochrome?c and hen egg white lysozyme, through UV?Cvisible absorption spectroscopy and electrospray ionisation mass spectrometry (ESI MS) to characterise the inherent protein metalation processes. Notably, Auoxo6 and Au₂phen produced stable protein adducts where one or more ??naked?? gold(I) ions are protein-coordinated; very characteristic is the case of cytochrome?c, which upon reaction with Auoxo6 or Au₂phen preferentially forms ??tetragold?? adducts with four protein-bound gold(I) ions. In turn, Aubipyc afforded monometalated protein adducts where the structural core of the gold(III) centre and its +3 oxidation state are conserved. Auranofin yielded protein derivatives containing the intact auranofin molecule. Additional studies were performed to assess the role played by a reducing environment in protein metalation. Overall, the approach adopted provides detailed insight into the formation of metallodrug?Cprotein derivatives and permits trends, peculiarities and mechanistic details of the underlying processes to be highlighted. In this respect, electrospray ionisation mass spectrometry is a very straightforward and informative research tool. The protein metalation processes investigated critically depend on the nature of both the metal compound and the interacting protein and also on the solution conditions used; thus, predicting with accuracy the nature and the amounts of the adducts formed for a given metallodrug?Cprotein pair is currently extremely difficult.     

Immunocytochemical localization of phaseolin and phytohemagglutinin in the endoplasmic reticulum and Golgi complex of developing bean cotyledons

Development of legume seeds is accompanied by the synthesis of storage proteins and lectins, and the deposition of these proteins in protein-storage vacuoles (protein bodies). We examined the subcellular distribution, in developing seeds of the common bean, Phaseolus vulgaris L., of the major storage protein (phaseolin) and the major lectin (phytohemagglutinin, PHA). The proteins were localized using an indirect immunocytochemical method in which ultrathin frozen sections were immunolabeled with rabbit antibodies specific for either PHA or phaseolin. Bound antibodies were then localized using goat-anti-rabbit immunoglobulin G adsorbed onto 4- to 5-nm colloidal gold particles. The sections were post-fixed with OsO₄, dehydrated, and embedded in plastic on the grids. Both PHA and phaseolin exhibited a similar distribution in the storage-parenchyma cells, being found primarily in the developing protein bodies. Endoplasmic reticulum and Golgi complexes (cisternal stacks and associated vesicles) also were specifically labeled for both proteins, whereas the cytosol and other organelles, such as mitochondria, were not. We interpret these observations as supporting the hypothesis that the transport of storage proteins and lectins from their site of synthesis, the rough endoplasmic reticulum, to their site of deposition, the protein bodies, is mediated by the Golgi complex.Abbreviations ER endoplasmic reticulum - IgG immunoglobulin G - PBS phosphate-buffered saline - PHA phytohemagglutinin