DEVELOPMENTAL CHANGES IN THE COTYLEDONS OF LUPINUS LUTEUS L. DURING AND AFTER GERMINATION

Cotyledons of Lupinus luteus were sampled from 1 to 21 days after sowing and processed for light microscopy and sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE). Length, width, and surface area of the cotyledons increased gradually until day 10. The thickness of the cotyledons increased from day 7 to day 12 and decreased thereafter. Morphometric analyses showed that the increase in length, width, and thickness of the cotyledon was due to cell expansion, and the decrease in thickness of the cotyledon was due to the decrease in the length of abaxial cells and in the total number of cells. Mesophyll development accompanied schizogenous and lysigenous air space formation. There were two structurally distinct types of protein bodies. Protein bodies in five to six layers of cells on the abaxial side did not contain globoids, while globoids were prominent in protein bodies in the center and adaxial side. Storage protein mobilization occurred first in the abaxial side of the cotyledon and proceeded toward the adaxial side. SDS-PAGE analysis showed that proteins ranged from 97 to 14 kD. High molecular weight α- and ß-conglutinins were more abundant in the abaxial region, whereas γ-conglutinin occurred in both abaxial and adaxial regions. In addition, there were five minor bands between 97 and 43 kD unique to abaxial region and five minor bands between 43 and 14 kD unique to adaxial region in the nonreduced protein profiles. The α- and ß-conglutinins began to decrease after imbibition and disappeared by day 7 after sowing. At this stage the subunits of ribulose-l,5-bisphosphate carboxylase/oxygenase and four new minor bands appeared.     

Protein bodies of castor bean endosperm: isolation, fractionation, and the characterization of protein components

Protein bodies in the endosperm of castor bean seeds (Ricinus communis L.) contain phytin globoids and protein crystalloids embedded in an amorphous proteinaceous matrix. The protein bodies are apparently surrounded by a single membrane. The protein bodies were isolated by grinding and centrifuging in glycerol. Such isolated protein bodies were almost identical (after cytological fixation) to those observed in situ, except that the globoids were lost. However, membrane-like structures appear to have surrounded the globoids. Histochemical analysis of the isolated protein bodies showed that carbohydrates (glycoproteins) are localized only in the matrix region.     

Subcellular Organization of Developing Embryos of Bidens cernua

Anatomical and submicroscopical changes in the cotyledons and radicles of Bidens cernua L. have been studied at five developmental stages. In the subcellular structure, these two plant organs are relatively similar but each developmental stage is characterized by a distinct fine structure. Protein bodies, which occupy the bulk of the cell in dormant embryos, develop as filling products of vacuoles. Ribosomes are seen abundantly at this stage, both in the nucleus and the plasma strands. Small vesicles which are the initials of globoids can be detected in the vacuoles even of rather young cells. They later associate at the periphery of protein masses secreted in the vacuoles. Many light globoids are seen in the protein bodies of mature cells. Some amyloplasts are present in the early developmental stages but not in the dormant cells. The endoplasmic reticulum becomes filled with osmiophilic storage fat, and later many spherosomes are seen between the protein bodies. Some osmiophilic material is also found in the intercellular spaces.     

Protein Bodies from the Endosperm of Castor Bean: Subfractionation, Protein Components, Lectins, and Changes during Germination

Protein bodies from the storage endosperm of dry castor bean (Ricinus communis L.) were isolated by successive nonaqueous linear density gradient centrifugation. The isolated protein bodies were lysed by the addition of water, and the various structural components of the organelles were separated by sucrose gradient centrifugation. The matrix protein remained at the top of the gradient while the membrane, the crystalloids, and the globoids migrated to densities 1.15 g/cm³, 1.30 g/cm³, and > 1.46 g/cm³, respectively. The protein of the protein bodies was distributed evenly between the crystalloids and the matrix, and little protein was present in the globoids or the membrane.     

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.     

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     

Cloning, Expression, and Purification of Insecticidal Protein Pr596 from Locust Pathogen Serratia marcescens HR-3

A novel insecticidal protein (Pr596) produced by Serratia marcescens HR-3 was found be a metalloprotease and responsible for insecticidal activity toward locusts. Two pairs of primers were designed to amplify Pr596, a putative open reading frame (ORF) by similarity search and the N-terminal amino-acid sequence of insecticidal protein. The results revealed that the ORF consisted of 1464 nucleotides encoding a protein of 487 amino-acid residues. Pr596 was cloned into expression vector pET32a(+) and was expressed in Escherichia coli BL21 (DE3)/pLysS strain with isopropyl-β-d-thiogalactopyranoside induction. The Pr596 was found to be highly expressed as inclusion bodies by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS-PAGE). Pr596 inclusion bodies were isolated and subjected to Ni-NTA His Bind Resins (Pharmacia, Germany). Pr596 purified and refolded was revealed by SDS-PAGE and had proteolytic activity and insecticidal activity. Results suggested that there is a potential to develop this protein to be used as an alternative locus control agent.     

Energy dispersive X-ray analysis of protein bodies in Protea compacta cotyledons

Summary The elemental composition of globoids in the protein bodies of Protea compacta cotyledons was studied by means of energy dispersive X-ray analysis. The globoid crystal was rich in phosphorus and calcium with lesser amounts of magnesium and potassium suggesting the presence of phytin in these structures.Abbreviation EDX energy dispersive X-ray analysis     

Sambucus nigra agglutinin is located in protein bodies in the phloem parenchyma of the bark

The bark of some young woody stems contains storage proteins which are subject to an annual rhythm: they accumulate in the autumn and are mobilized in the spring. We show here that the bark phoem-parenchyma cells of Sambucus nigra L. contain numerous protein bodies, and that the bark lectin (S. nigra agglutinin) which undergoes an annual rhythm is localized in these protein bodies. The protein bodies in the cotyledons of legume seeds also contain lectin, indicating that lectins may be storage compounds themselves or may have a function in storage and-or mobilization processes.Abbreviations PBS phosphate-buffered saline - IgG immunoglobulin - SNA Sambucus nigra agglutinin     

Immunolocalization of avenin and globulin storage proteins in developing endosperm of Avena sativa L.

The seed storage proteins of oats (Avena sativa L.) are synthesized and assembled into vacuolar protein bodies in developing endosperm tissue. We used double-label immunolocalization to study the distribution of these proteins within protein bodies of the starchy endosperm. When sections of developing oat endosperm sampled 8 d after anthesis were stained with uranyl acetate and lead citrate, the vacuolar protein bodies consisted of light-staining regions which were usually surrounded by a darker-staining matrix. Immunogold staining of this tissue demonstrated a distinct segregation of proteins within protein bodies; globulins were localized in the dark-staining regions and prolamines were localized in the light-staining regions. We observed two additional components of vacuolar protein bodies: a membranous component which was often appressed to the outside of the globulin, and a granular, dark-staining region which resembled tightly clustered ribosomes. Neither antibody immunostained the membranous component, but the granular region was lightly labelled with the anti-globulin antibody. Anti-globulin immunostaining was also observed adjacent to cell walls and appeared to be associated with plasmodesmata. Immunostaining for both antigens was also observed within the rough endoplasmic reticulum. Based on the immunostaining patterns, the prolamine proteins appeared to aggregate within the rough endoplasmic reticulum while most of the globulin appeared to aggregate in the vacuole.Abbreviations DAA days after anthesis - IgG immunoglobulin G - M_r apparent molecular mass - RER rough endoplasmic reticulum - SDS-PAGE sodium dodecyl sulfate — polyacrylamide gel electrophoresis     

Immunogold-localization and synthesis of an oil-body membrane protein in developing soybean seeds

The synthesis of a major oil-body membrane brotein was studied in maturing soybean (Glycine max (L.) Merr.) cotyledons. The membrane contained four abundant proteins with apparent molecular mass (M_r) of 34000, 24000, 18000 and 17000. The M_r=24000 protein (mP 24) was selected for more detailed analysis. The protein was purified to apparent homogeneity by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and isolated from the gel by electroelution or chemical hydrolysis of gel crosslinks. It was then used to elicit rabbit antibodies which were judged to be specific when assayed by SDS-PAGE-immunoblot procedures. The mP 24 was localized in immature soybean cotyledon cells by indirect immunogold procedures on thin sections of Lowicryl- and LR-White-embedded tissue. Indirect labeling with the primary antiserum followed by colloidal gold-protein A showed specific labeling of the oil-body membrane and an absence of label on the other subcellular organelles including the endoplasmic reticulum (ER). Parallel tissue samples were studied by conventional transmission electron microscopy. Although segments of the ER were observed to be closely juxtaposed to the oil bodies, continuity between the two organelles was not observed. The synthesis of mP 24 was studied by in-vitro translation and in-vivo labeling with [³H]leucine followed by indirect immunoaffinity isolation of the labeled products. The SDS-PAGE fluorography results indicated that the primary translation product and the in-vivo synthesized protein have the same M_r, and this is also the same M_r as the protein in the mature membrane.Abbreviations and symbols DATD N N'-diallyltartardiamide - EM electron microscopy/scopic - ER endoplasmic reticulum - IgG immunoglobulin G - M_r apparent molecular mass - PBS phosphate-buffered saline - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - TBS Trisbuffered saline     

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     

Biochemical,immunochemical, and ultrastructural studies of protein storage in poplar(Populus × canadensis ‘robusta’) wood

The seasonal changes in protein content have been followed in the wood of Populus × canadensis Moench robusta, both biochemically and electronmicroscopically at the cellular level. In the storage-parenchyma cells of the twig wood, 4–6 g · mg^–1 DW protein were deposited in the fall, parallel to the yellowing of leaves, and mobilized completely again during the outgrowth of buds in the spring. Environmental impacts on the leaves, e.g. a fungal attack and mechanical injury by a hurricane, were found to affect protein deposition in the wood considerably. Accumulation of protein bodies in the fall and their disappearance from the cells in the spring proceeded parallel to the changes in protein content measured biochemically, proving that these organelles are the main sites of protein storage in the wood parenchyma cells. Using immunogold labelling and an anti-32-kDa poplar storage-protein antibody the protein bodies were shown to be the exclusive sites of storage of a 32-kDa polypeptide. Transient changes in protein content were also observed during fall and winter. Because these changes coincided with changes in protein-body structure and with changes in the population of vesicles and-or tubular membrane cisternae of the cells, an exchange of nitrogen compounds from the storage pool into the structural protein of membranes possibly takes place during these periods. The structural events observed during proteolysis in spring are very similar to those found in seeds. The possible roles of small cytoplasmic vesicles found within protein bodies during proteolysis and of multimembraneous vacuolar compartments during membrane retrieval are discussed.Abbreviations DW dry weight - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis Dedicated to Professor Dr. Dr. Hans Marquardt on the occasion of his 80th birthdayThe valuable technical assistance of Miss Sabine Karg and Miss Astrid Diercks is gratefully acknowledged. This work was supported by the Deutsche Forschungsgemeinschaft.     

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.     

Immunocytochemical localization of concanavalin A in developing jack-bean cotyledons

The lectin, concanavalin A (Con A), was localized in the cotyledon of developing jack beans (Canavalia ensiformis (L.) DC) by electron-microscope immunocytochemistry. In mature seeds, Con A was present in protein-storage vacuoles (protein bodies) of storage-parenchyma cells. Although protein bodies could be seen in other cell types, only protein bodies in storage-parenchyma cells contained Con A. During seed development, Con A was also localized on the endoplasmic reticulum and Golgi apparatus, presumably en route toward deposition within the protein bodies. The intensity of labeling of the endoplasmic reticulum was much greater during the developmental stage of protein-body filling (66% final seed weight) than in mature seeds.Abbreviations Con A concanavalin A - ER endoplasmic reticulum - IgG immunoglobulin G     

Stomatal myrosin cells in Caricaceae. Taxonomic implications for a glucosinolate-containing family

Jørgensen, L. B. 1995. Stomatal myrosin cells in Caricaceae. Taxonomic implications for a glucosinolate-containing family. — Nord. J. Bot. 15: 523–540. Copenhagen. ISSN 0107–055X.
Stomatal myrosin cells are shown to be present in Carica goudotiana, C. papaya, C. guercifolia and Jarilla caudata of the Caricaceae. They are found in the epidermis of all green parts, viz. leaves, stems, and immature fruits, and also of cotyledons from germinating seeds. They are structurally the same as the stomatal myrosin cells in other glucosinolate- and myrosinase-containing families, Resedaceae, Tovariaceae and Bata-ceae, and comparable to the idioblastic myrosin cells from e.g. Brassicaceae and Capparaceae. The stomatal myrosin cells have vacuoles filled with proteinaceous material and cytoplasm rich in rough endoplasmic reticulum. During embryogenesis single adaxial epidermal cells of the cotyledons can be distinguished as myrosin cells, since their protein bodies are homogeneous and without globoids and become filled with protein earlier than the protein bodies with globoids present in the other epidermal cells or the mesophyll cells of the cotyledons. This is analogous to myrosin cells in embryos from Brassicaceae. In germinating seeds the single epidermal myrosin cells divide to form precursors of guard cells, thus turning into stomatal myrosin cells in the green cotyledons. The presence of myrosin cells supports a taxonomic treatment of Caricaceae together with the majority of the other glucosinolate-containing families in the major glucosinolate clade.     

DIFFERENTIAL ACTIVITIES OF ACID PHOSPHATASE FROM ADAXIAL AND ABAXIAL REGIONS OF LUPINUS LUTEUS (FABACEAE) COTYLEDONS

Acid phosphatases of abaxial and adaxial regions in the cotyledons of the Lupinus luteus which possess structurally distinct protein bodies were examined. Acid phosphatase activity was investigated by enzyme assays and by gel electrophoresis and was localized by cytochemical methods in the cotyledons of Lupinus luteus L. during germination and seedling development. Acid phosphatase activity was significantly higher in the adaxial (heterogeneous protein body) region as compared to the abaxial (homogeneous protein body) region of the cotyledon. The pH optimum of acid phosphatase from the abaxial region and from the adaxial region was 4.5 and 5.0, respectively. There were significant differences in substrate specificity and isoenzymic composition of the enzyme between the two regions. Isoenzymic composition changed during the course of germination and seedling development. Acid phosphatase was localized in the matrix of the homogeneous protein bodies and in the globoids of the heterogeneous protein bodies at imbibition. After germination (d 3, d 4, d 7) acid phosphatase was localized primarily in the inner cell walls and intercellular spaces of both regions. These results show that different isoenzymes of acid phosphatase show differential localization and the rate of acid phosphatase activation or synthesis differs in cells from the two regions of the cotyledon.     

U bodies respond to nutrient stress in Drosophila

The neurodegenerative disease spinal muscular atrophy (SMA) is caused by mutation of the survival motor neuron 1 (SMN1) gene. Cytoplasmic SMN protein-containing granules, known as U snRNP bodies (U bodies), are thought to be responsible for the assembly and storage of small nuclear ribonucleoproteins (snRNPs) which are essential for pre-mRNA splicing. U bodies exhibit close association with cytoplasmic processing bodies (P bodies), which are involved in mRNA decay and translational repression. The close association of the U body and P body in Drosophila resemble that of the stress granule and P body in yeast and mammalian cells. However, it is unknown whether the U body is responsive to any stress. Using Drosophila oogenesis as a model, here we show that U bodies increase in size following nutritional deprivation. Despite nutritional stress, U bodies maintain their close association with P bodies. Our results show that U bodies are responsive to nutrition changes, presumably through the U body–P body pathway.     

Degradation of Protein Bodies in Germinating Seeds of Brassica campestris L. var. sarson Prain

Histochemical investigations were carried out on dry and germinatingseeds of Brassica campestris var. sarson, to study the degradationof protein bodies with globoidal inclusions. During germination,a wave of protein body degradation sets in from the radicularend of the embryo, passing through the hypocotyl and shoot apex,and ending in the cotyledons. The digestion of protein bodiesis of the internal type. The various isolated parts of the embryoshowed a similar pattern of protein body digestion to that ofthe whole embryo, except that in some cells the globoids persistedeven after complete digestion of protein bodies; the rate wasfaster in the comparatively more expanded part of the isolatedorgans. No specific factor controlling the initiation of thewave of protein body digestion could be ascertained. Brassica campestris var. sarson, yellow sarson, seed, germination, protein bodies, degradation     

The structure and composition of aleurone grains in the barley aleurone layer

Summary Cytochemical methods have been used in conjunction with light and electron microscopy to determine the nature of the inclusions in aleurone grains of barley aleurone layers. Two kinds of inclusions were found: (1) Globoids within globoid cavities which were not enclosed by a membrane: the globoids stained red with toluidin blue due to the presence of phytin, and with lipid stains; (2) Protein-carbohydrate bodies which stained green with toluidin blue. The characteristics of globoids and protein-carbohydrate bodies as seen in the electron microscope are described in detail using both glutaraldehyde- and permanganatefixed tissues. The protein-carbohydrate body was identified by silver-hexaminestaining; this was not caused by carbohydrate but by some component which stained green in toluidin blue and which also occurred in cell walls in a thin band adjacent to the cytoplasm. The characteristics of both bodies are discussed in relation to apparent confusion in their identities in previous electron-microscope studies.