Immunochemical studies on the role of the Golgi complex in protein-body formation in rice seeds

Antibodies raised against purified glutelins and prolamines were employed as probes to study the cellular routes by which these proteins are deposited into protein bodies of rice (Oryza sativa L.) endosperm. Three morphologically distinct protein bodies, large spherical, small spherical, and irregularly-shaped, were observed, in agreement with existing reports. Immunocytochemical studies showed the presence of glutelins in the irregularly-shaped protein bodies while the prolamines were found in both the large and small spherical protein bodies. Both the large and small spherical protein bodies, distinguishable by electron density and gold-labeling patterns, appear to be formed by direct deposition of the newly formed proteins into the lumen of the rough endoplasmic reticulum (ER). In contrast, glutelin protein bodies are formed via the Golgi apparatus. Small electron-lucent vesicles are often found at one side of the Golgi. Electron-dense vesicles, whose contents are labeled by glutelin antibody-gold particles, are commonly observed at the distal side of the Golgi apparatus and fuse to form the irregularly shaped protein bodies in endosperm cells. These observations indicate that the transport of rice glutelins from their site of synthesis, the ER, to the site of deposition, the protein bodies, is mediated by the Golgi apparatus.Abbreviations BSA bovine serum albumin - Da dalton - DAF days after flowering - ER endoplasmic reticulum - GL irregularly shaped - L large spherical - S small spherical (protein bodies) - PBS phosphate-buffered saline - PTA phosphotungstic acid     

Immunocytochemical Localization of Wheat Storage Proteins in Endosperm Cells 30 Days After Anthesis

Antisera against seven different wheat (Triticum aestivum L.)storage protein subfractions were characterized using (1) ELISAwith gliadins and low- and high-molecular weight glutenin subunitsand (2) electrophoresis (SDS-PAGE and acidic buffer PAGE) andimmunoblotting. The specificities of these antisera (polyclonalantibodies) and 13 monoclonal antibodies covered various patternsof reactivity with alpha-, beta-, gamma- and omega-gliadinsand low- and high-molecular weight glutenins. The antisera andantibodies were applied to ultrathin sections of wheat endospermtissue, from kernels fixed 30 d after anthesis, and were detectedby secondary antibodies tagged with either 5 or 15 nm gold particlesusing transmission electron microscopy. Labelling was denserwhen the small gold particles were used but irrespective ofgold particle size, labelling of polyclonal antisera predominatedwhen the endosperm cells were subjected to both mono- and polyclonalantibodies. Each of the antisera and monoclonal antibodies thatlabelled the protein bodies, labelled them more or less uniformly.This indicates that only one kind of protein body, containingall gliadin and glutenin subfractions, exists during this stageof grain development. Electron-dense globular inclusions foundin many protein bodies were not labelled. Label was also foundon protein-like material present in the lumen of the rough endoplasmicreticulum and on vesicles of the Golgi apparatus. Thus concentrationof storage proteins takes place both at the site of synthesis,the lumen of the rough endoplasmic reticulum, and at the siteof processing and transport, the vesicles of the Golgi apparatus.Fusions between these proteinaceous materials give rise to largerprotein bodies and ultimately to the protein matrix. Key words: Wheat, immunocytochemistry, protein bodies, rough endoplasmic reticulum, Golgi apparatus     

The N- and C-terminal regions regulate the transport of wheat gamma-gliadin through the endoplasmic reticulum in Xenopus oocytes.

Following sequestration into the endoplasmic reticulum (ER), wheat storage proteins are naturally either retained and packaged into protein bodies within this organelle or exported to the Golgi apparatus. To identify protein domains that control the sorting of wheat storage proteins within the ER, a wild-type gamma-gliadin storage protein as well as two of its deletion mutants, each bearing either of the two autonomous N- and C-terminal regions, were expressed in Xenopus oocytes. Our results demonstrated that the N-terminal region of the gliadin, which is composed of several tandem repeats of the consensus sequence PQQPFPQ, was entirely retained within the ER and accumulated in dense protein bodies. In contrast, the C-terminal autonomous region was efficiently secreted to the medium. The wild-type gamma-gliadin, containing both regions, was secreted at a lower rate and less efficiently than its C-terminal region. These results suggest that sorting of the wheat gamma-gliadin within the ER may be determined by a balance between two opposing signals: one functions in the retention and packaging of the storage protein within the ER, while the second renders the protein competent for export from this organelle to the Golgi apparatus.     

Protein accumulation in developing endosperm of a high-protein line of Triticum dicoccoides

Abstract. Endosperm tissue from developing grains of a line of wheat ( Triticum dicoccoides ) which accumulates up to 30% protein in the mature grain, was examined by electron microscopy to establish the ontogeny of the storage protein bodies. Ultrastructural evidence suggests that storage proteins of wheat may be transported from their site of synthesis on the rough endoplasmic reticulum (ER) to protein bodies by two different routes within the endomembrane system. The first route, which probably functions throughout protein deposition, involves the transport of protein from the cisternal rough ER to the protein vacuoles via the Golgi apparatus. The second route, observed 20 d after anthesis, appears to lead directly from dilated regions of the rough ER to protein vacuoles, bypassing the dictyosomes. Phytin inclusions are found in protein vacuoles of starchy endosperm cells adjacent to the aleurone layer of developing grain.     

Formation of protein storage bodies during embryogenesis in cotyledons of Sinapis alba L.

An electron microscopic investigation of fine structural changes in post-meristematic cotyledon mesophyll cells during the period of storage protein accumulation (16–32 d after pollination) showed that the rough ER, the Golgi apparatus and the developing vacuome are intimately involved in the formation of storage protein bodies (aleurone bodies). At the onset of storage protein accumulation (16–18 d after pollination) storage protein-like material appears within Golgi vesicles and preformed vacuoles. At a later stage (24 d after pollination) similar material can also be detected within vesicles formed directly by the rough endoplasmic reticulum (ER). It is concluded that there are two routes for storage protein transport from its site of synthesis at the ER to its site of accumulation in the vacuome. The first route involves the participation of dictyosomes while the second route bypasses the Golgi apparatus. It appears that the normal pathways of membrane flow in the development of central vacuoles in post-meristematic cells are used to deposit the storage protein within the protein bodies. Thus, the protein body can be regarded as a transient stage in the process of vacuome development of these storage cells.Abbreviation ER endoplasmic reticulum     

Immunogold localization of chymotrypsin inhibitor-2, a lysine-rich protein,in developing barley endosperm

Chymotrypsin inhibitor-2, a lysine-rich protein in the barley endosperm, has been localized at the ultrastructural level by immunocytochemistry in developing barley endosperm cells 14 days post anthesis. The protein is deposited in the protein bodies. Two morphologically distinct types of protein bodies, small spherical and large irregularly shaped, are present. Golgi-apparatus-derived vesicles whose content is labelled by chymotrypsin inhibitor-2 antibody-gold particles are observed at the Golgi complex and around the vacuoles. These observations indicate that the transport of the protein to the site of deposition is mediated by the Golgi apparatus.Abbreviations CI chymotrypsin inhibitor - DPA days post anthesis - ER endoplasmic reticulum The authors wish to thank Dr. V.R. Franceschi (Department of Botany, Washington State University, Pullman, USA) for many helpful discussions and advice during the work, and the staff at the Electron Microscope Center at Washington State University for technical assistance.     

Distribution of Acid Phosphatase in Paramecium caudatum: Its Relations with the Process of Digestion

SYNOPSIS. The distribution of acid phosphatase was investigated at the ultrastructural level in Paramecium caudatum. Acid phosphatase occurs in endoplasmic reticulum, Golgi apparatus, food vacuoles, autophagic vesicles, vacuolar and dense bodies. Some slight deposits are also seen in the mitochondria.
These observations point out that this hydrolase activity is related to digestive processes. The enzyme, originating from the endoplasmic reticulum and Golgi apparatus reaches the food vacuole or autophagic vesicle likely via the reticulum. The digestion of the bacteria or of the enclosed organelle gives rise to electronopaque material which is later found in dense bodies. These dense bodies are likely secondary lysosomes and it is possible that they may fuse with the young food vacuole or with autophagic vesicles.     

Native and Artificial Reticuloplasmins Co-Accumulate in Distinct Domains of the Endoplasmic Reticulum and in Post-Endoplasmic Reticulum Compartments

We compared the subcellular distribution of native and artificial reticuloplasmins in endosperm, callus, and leaf tissues of transgenic rice (Oryza sativa) to determine the distribution of these proteins among endoplasmic reticulum (ER) and post-ER compartments. The native reticuloplasmin was calreticulin. The artificial reticuloplasmin was a recombinant single-chain antibody (scFv), expressed with an N-terminal signal peptide and the C-terminal KDEL sequence for retrieval to the ER (scFvT84.66-KDEL). We found that both molecules were distributed in the same manner. In endosperm, each accumulated in ER-derived prolamine protein bodies, but also in glutelin protein storage vacuoles, even though glutelins are known to pass through the Golgi apparatus en route to these organelles. This finding may suggest that similar mechanisms are involved in the sorting of reticuloplasmins and rice seed storage proteins. However, the presence of reticuloplasmins in protein storage vacuoles could also be due to simple dispersal into these compartments during protein storage vacuole biogenesis, before glutelin deposition. In callus and leaf mesophyll cells, both reticuloplasmins accumulated in ribosome-coated vesicles probably derived directly from the rough ER.     

Immunogold localization of prolamines in developingHaynaldia villosa endosperm

Summary Haynaldia villosa is a wild grass belonging to the tribe Triticeae, which includes important crops such as wheat, barley, and rye. The alcohol-soluble proteins ofH. villosa have extensive immunological relatedness with wheat prolamines as visualized by Western blot analysis. Amorphous protein inclusions surrounded by a limiting membrane are commonly found in the vacuoles of endosperm and subaleurone layers ofH. villosa seeds. A layer of cells just beneath the aleurone layer is rich in ER. Unlike that in other cell types, the ER in these cells is highly dilated and contains materials at its swollen distal ends. These materials are structurally similar to substances found in the protein bodies. Protein A-gold immunocytochemical localization studies employing antibodies against wheat prolamine confirmed that the inclusions found in the lumen of the ER do not contain prolamines. This observation indicates that the ER does not act as the site of prolamine accumulation inH. villosa. Protein bodies found in the vacuoles and the vesicles associated with the Golgi complexes were specifically labeled. This suggests that Golgi complexes mediate the transport of prolamines into vacuoles ofH. villosa endosperm cells, in a fashion analogous to that of other vacuolar proteins of dicotyledonous plants.     

The Golgi apparatus in developing endosperm of wheat (Triticum aestivum L.)

The ultrastructure and distribution of the Golgi apparatus in developing wheat endosperm was investigated using a zinc iodide-osmium tetroxide staining complex in conjunction with low and high voltage electron microscopy. Dictyosomes were numerous in starchy endosperm and aleurone at 15 days after anthesis, and during the period of rapid storage protein deposition 25 d after anthesis. Fewer dictyosomes were seen in maturing endosperm. Two types of vesicles were associated with the dictyosomes; small, heavily-stained vesicles were sited at the ends of fine tubules which extend from the cisternae, and larger less-stained vesicles were associated with the periphery of the cisternae. Stereo-pairs of micrographs up to 1 m thick were taken to demonstrate the interconnections between cisternal and tubular endoplasmic reticulum. Elements of tubular ER were closely associated with dictyosomes, but connections were not observed. These results are discussed in relation to the transport of endosperm storage proteins from their site of synthesis on the cisternal ER to their site of storage, the protein bodies.     

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     

The small GTPase Rab5a is essential for intracellular transport of proglutelin from the Golgi apparatus to the protein storage vacuole and endosomal membrane organization in developing rice endosperm

Rice (Oryza sativa) glutelins are synthesized on the endoplasmic reticulum as larger precursors, which are then transported via the Golgi to the protein storage vacuole (PSV), where they are processed into acidic and basic subunits. Three independent glutelin precursor mutant4 (glup4) rice lines, which accumulated elevated levels of proglutelin over the wild type, were identified as loss-of-function mutants of Rab5a, the small GTPase involved in vesicular membrane transport. In addition to the plasma membrane, Rab5a colocalizes with glutelins on the Golgi apparatus, Golgi-derived dense vesicles, and the PSV, suggesting that Rab5a participates in the transport of the proglutelin from the Golgi to the PSV. This spatial distribution pattern was dramatically altered in the glup4 mutants. Numerous smaller protein bodies containing glutelin and α-globulin were evident, and the proteins were secreted extracellularly. Moreover, all three independent glup4 allelic lines displayed the novel appearance of a large dilated, structurally complex paramural body containing proglutelins, α-globulins, membrane biomarkers for the Golgi apparatus, prevacuolar compartment, PSV, and the endoplasmic reticulum luminal chaperones BiP and protein disulfide isomerase as well as β-glucan. These results indicate that the formation of the paramural bodies in glup4 endosperm was due to a significant disruption of endocytosis and membrane vesicular transport by Rab5a loss of function. Overall, Rab5a is required not only for the intracellular transport of proglutelins from the Golgi to the PSV in rice endosperm but also in the maintenance of the general structural organization of the endomembrane system in developing rice seeds.     

The subcellular localization of apomucin and nonreducing terminal N-acetylgalactosamine in porcine submaxillary glands

Antibodies prepared against enzymatically deglycosylated porcine submaxillary gland mucin (apomucin), which were unreactive with native mucin and its partially deglycosylated derivatives, were used to immunolocalize apomucin in situ. Electron microscopy of sections of Lowicryl K4M-embedded tissue reacted successively with antibodies and protein A-gold complexes showed apomucin exclusively in mucous cells within the rough endoplasmic reticulum, transitional elements of the endoplasmic reticulum, and vesicles at the cis side of the Golgi apparatus. The Golgi apparatus, forming mucous droplets, and mucous droplets contained no apomucin. Although the rough endoplasmic reticulum contained most of the apomucin in mucous cells, some cisternae of the endoplasmic reticulum and the nuclear envelope were devoid of apomucin. Examination of tissue sections treated with the glycosidases used to prepare apomucin revealed immunolabel for apomucin throughout the secretory pathway. Colloidal gold coated with Helix pomatia lectin was used to detect nonreducing N-acetylgalactosamine residues. In mucin-producing cells lectin-gold was found in the mucous droplets, the forming mucous droplets, and throughout the Golgi apparatus but mostly in the cis portion of this organelle. In tissue sections reacted successively with lectin-gold and anti-apomucin/protein A-gold, both types of gold complex could be found in the cis side of the Golgi apparatus. These data indicate that the O-glycosylation of mucin is a posttranslational event that occurs in the Golgi apparatus and begins in the cis side of the Golgi apparatus.     

RNA targeting to a specific ER sub-domain is required for efficient transport and packaging of α-globulins to the protein storage vacuole in developing rice endosperm

Studies focusing on the targeting of RNAs that encode rice storage proteins, prolamines and glutelins to specific sub-domains of the endoplasmic reticulum (ER), as well as mis-localization studies of other storage protein RNAs, indicate a close relationship between the ER site of RNA translation and the final site of protein deposition in the endomembrane system in developing rice endosperm. In addition to prolamine and glutelin, rice accumulates smaller amounts of α-globulins, which are deposited together with glutelin in the protein storage vacuole (PSV). In situ RT-PCR analysis revealed that α-globulin RNAs are not distributed to the cisternal ER as expected for a PSV-localized protein, but instead are targeted to the protein body-ER (PB-ER) by a regulated process requiring cis-sorting sequences. Sequence alignments with putative maize δ-zein cis-localization elements identified several candidate regulatory sequences that may be responsible for PB-ER targeting. Immunocytochemical analysis confirmed the presence of α-globulin on the periphery of the prolamine protein bodies and packaging in Golgi-associated dense vesicles, as well as deposition and storage within peripheral regions of the PSV. Mis-targeting of α-globulin RNAs to the cisternal ER dramatically alters the spatial arrangement of α-globulin and glutelin within the PSV, with the accompanying presence of numerous small α-globulin particles in the cytoplasm. These results indicate that α-globulin RNA targeting to the PB-ER sub-domain is essential for efficient transport of α-globulins to the PSV and its spatial arrangement in the PSV. Such RNA localization prevents potential deleterious protein-protein interactions, in addition to performing a role in protein targeting.     

Immunocytochemical evidence for the involvement of golgi apparatus in the deposition of seed lectin ofBauhinia purpurea (Leguminosae)

Summary The seed lectin of the tree legume,Bauhinia purpurea alba, was localized by electron microscopic immunocytochemistry. The pattern of lectin deposition and site of intracellular localization was examined in mid- to late-maturation seeds. The seed tissue was embedded in Lowicryl K4M, the use of which with seed tissues is discussed. Immunocytochemical labeling was accomplished with colloidal gold coupled to a second antibody. The immunocytochemical reaction was specific and sensitive. Protein bodies, Golgi apparatus and Golgi secretion vesicles were densely labeled. Golgi apparatus was oriented such that Golgi secretion vesicles were in close proximity to the protein bodies. The entire Golgi apparatus was labeled with no concentration gradient across the Golgi stack. These observations indicate that the final site of lectin deposition is the protein body, and that the Golgi apparatus plays an essential role in the deposition process.     

Developing prolamine protein bodies are associated with the cortical cytoskeleton in rice endosperm cells

 The mRNAs that encode the prolamine storage proteins in rice (Oryza sativa L.) endosperm cells are enriched on the surface of the prolamine protein bodies (PBs), a subcellular structure consisting of a prolamine intracisternal granule surrounded by rough endoplasmic reticulum membrane. Previous biochemical studies (D.G. Muench et al., 1998, Plant Physiol. 116: 559–569) have shown that prolamine mRNAs may be anchored to the PB surface via the cytoskeleton. To better understand the mechanism and role of mRNA localization in rice endosperm cells, we studied the subcellular development of prolamine PBs and their relationship with the cytoskeleton in rice endosperm cells. Confocal microscopy of endosperm cells showed that, unlike the glutelin PBs, the developing prolamine PBs are not randomly distributed within the cell, but instead are often enriched in the cortical region of the cell only a few micrometers beneath the plasma membrane. In addition, the peripheral prolamine PBs are closely associated with the cortical microtubule and actin filament networks. The cortical enrichment of rice prolamine protein bodies represents a unique example of endoplasmic reticulum subdomain localization in plant cells. The interaction of this endoplasmic reticulum subdomain with the cytoskeleton provides new insights on the possible mechanism and role of mRNA localization in plants. Received: 30 September 1999 / Accepted: 12 November 1999     

Golgi apparatus partitioning during cell division

This review discusses the mitotic segregation of the Golgi apparatus. The results from classical biochemical and morphological studies have suggested that in mammalian cells this organelle remains distinct during mitosis, although highly fragmented through the formation of mitotic Golgi clusters of small tubules and vesicles. Shedding of free Golgi-derived vesicles would consume Golgi clusters and disperse this organelle throughout the cytoplasm. Vesicles could be partitioned in a stochastic and passive way between the two daughter cells and act as a template for the reassembly of this key organelle. This model has recently been modified by results obtained using GFP- or HRP-tagged Golgi resident enzymes, live cell imaging and electron microscopy. Results obtained with these techniques show that the mitotic Golgi clusters are stable entities throughout mitosis that partition in a microtubule spindle-dependent fashion. Furthermore, a newer model proposes that at the onset of mitosis, the Golgi apparatus completely loses its identity and is reabsorbed into the endoplasmic reticulum. This suggests that the partitioning of the Golgi apparatus is entirely dependent on the partitioning of the endoplasmic reticulum. We critically discuss both models and summarize what is known about the molecular mechanisms underlying the Golgi disassembly and reassembly during and after mitosis. We will also review how the study of the Golgi apparatus during mitosis in other organisms can answer current questions and perhaps reveal novel mechanisms.     

Effects of brefeldin A on the Golgi apparatus, the nuclear envelope, and the endoplasmic reticulum in a green alga,Scenedesmus acutus

Summary The effects of brefeldin A (BFA) on the structure of the Golgi apparatus, the nuclear envelope, and the endoplasmic reticulum (ER), and on the thiamine pyrophosphatase (TPPase) activity in these organelles were examined in a green alga,Scenedesmus acutus, to obtain evidence for the existence of a retrograde transport from the Golgi apparatus to the ER via the nuclear envelope. InScenedesmus, Golgi bodies are situated close to the nuclear envelope throughout the cell cycle and receive the transition vesicles not directly from the ER, but from the nuclear envelope. BFA induced the disassembly of Golgi bodies and an increase in the ER cisternae at the trans-side of decomposed Golgi bodies in interphase cells and multinuclear cells before septum formation. The accumulated ER cisternae connected to the nuclear envelope at one part. TPPase activity was detected in all cisternae of Golgi bodies, but not in the nuclear envelope or the ER in nontreated cells. On the contrary, in BFA-treated cells, TPPase activity was detected in the nuclear envelope and the ER in addition to the decomposed Golgi bodies. When septum-forming cells were treated with BFA, the disassembly of Golgi bodies was less than that in interphase cells, and TPPase activity was detected in the Golgi cisternae but not in the nuclear envelope or the ER. These results suggest mat BFA blocks the anterograde transport from the nuclear envelope to the Golgi bodies but does not block the retrograde transport from the Golgi bodies to the nuclear envelope in interphase and multinuclear cells.Abbreviations BFA brefeldin A - ER endoplasmic reticulum - TPPase thiamine pyrophosphatase     

Elektronenmikroskopische Untersuchungen von Differenzierungsvorgängen bei Moosen

Summary In meristematic cells of the gemma of Riella helicophylla and in young bud cells from the protonema of Funaria hygrometrica the cell plate is formed by fusion of small vesicles originating from the Golgi apparatus. These spherical vesicles of about 0.1 m diameter have an electron dense centre, probably consisting of pectic substances or their precursors. The endoplasmic reticulum producing multivesicular bodies participate in cell plate formation too. Another cytoplasmic component forming the cell plate are coated vesicles, the origin of which is the Golgi apparatus and perhaps also the endoplasmic reticulum. In view of these observations the question of whether the endoplasmic reticulum or the Golgi apparatus forms the cell plate must be answered in this way: both endoplasmic reticulum and Golgi apparatus supply material for growth of the cell plate. Multivesicular bodies, coated vesicles and other small vesicles of unknown nature participate in the formation of the primary wall.

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Zum Teil finanziert mit Sondermitteln des Landes Niedersachsen an Prof. Dr. M. Bopp.     

Early Stages in Wheat Endosperm Formation and Protein Body Initiation

The early stages of endosperm formation and protein body initiationare described for hard red winter wheat using light and transmissionelectron microscopy. Two days after flowering (DAF) the endospermwas a thin layer of coenocytic cytoplasm lining the embryo sac.By 4 DAF the endosperm had cellularized and completely filledthe embryo sac. Enough differentiation had occurred by 6 DAFto distinguish cells destined to become the aleurone layer,sub-aleurone region and central endosperm. Protein bodies wereinitiated at about 6–7 DAF and were first found near theGolgi apparatus. Wheat was ready for combine harvest at 34 DAF.Enlargement of the small protein bodies near the Golgi apparatusoccurred by several mechanisms: (1) fusion with one or moreof the dense Golgi vesicles or fusion with other protein bodies,(2) fusion with small electron-lucent Golgi-derived vesicles,(3) pinocytosis of a portion of the adjacent cytoplasm intothe developing protein body and (4) fusion of large proteinbodies with one another at later stages of grain development.Of the four mechanisms described, the pinocytotic vesicles andfusion of protein bodies were the most frequent and consistentprocesses observed. Direct connections between rough endoplasmicreticulum (RER) and protein bodies were not observed. The resultssuggest a rôle for the Golgi apparatus in the initiationof protein bodies. Also, the lack of RER derived vesicles suggestsa soluble mode of secretion of storage proteins involved inthe enlargement of protein bodies. Triticum aestivum, wheat endosperm, protein bodies Golgi apparatus