The protein storage vacuole: a unique compound organelle.

Storage proteins are deposited into protein storage vacuoles (PSVs) during plant seed development and maturation and stably accumulate to high levels; subsequently, during germination the storage proteins are rapidly degraded to provide nutrients for use by the embryo. Here, we show that a PSV has within it a membrane-bound compartment containing crystals of phytic acid and proteins that are characteristic of a lytic vacuole. This compound organization, a vacuole within a vacuole whereby storage functions are separated from lytic functions, has not been described previously for organelles within the secretory pathway of eukaryotic cells. The partitioning of storage and lytic functions within the same vacuole may reflect the need to keep the functions separate during seed development and maturation and yet provide a ready source of digestive enzymes to initiate degradative processes early in germination.     

A barley (Hordeum vulgare L.) LEA3 protein, HVA1, is abundant in protein storage vacuoles

The HVA1 protein belongs to the LEA3 group, which is expressed during the late stage of seed maturation. It is also induced by exogenous abscisic acid (ABA) and a variety of environmental stresses in germinating barley (Hordeum vulgare L.). In the present work, the potential role of HVA1 was investigated by studying its tissue distribution and subcellular localization in mature and stressed seeds by immuno-microscopic methods. In the mature seed, HVA1 protein was detected in all tissues except the non-living starchy endosperm. During germination the amount of HVA1 protein decreased but did not totally disappear. Incubation with 100 μM ABA, cold treatment or drought stress dramatically increased HVA1 expression in the germinated seed. In this work, the distribution of a LEA3 group protein was studied in a cereal seed for the first time by immuno-electron microscopy. In the scutellum and aleurone layer, HVA1 was localized both in the cytoplasm and protein storage vacuoles (PSVs). HVA1 protein was found to be threefold more abundant in PSVs than in the cytoplasm of an unstressed seed tissue. The ratio increased with ABA or stress treatments to at least ninefold. The role of HVA1 in PSVs remains unclear: a previously suggested possibility is ion sequestration to prevent precipitation during stress. On the other hand, HVA1 protein could also be degraded in PSVs. HVA1 protein does not have the signal peptide typical of proteins which are glycosylated and targeted into the vacuole via the Golgi complex. Because HVA1 is not glycosylated, it may use an alternative, ER-independent vacuolar pathway, also found in yeast cells.     

Protein storage vacuoles are transformed into lytic vacuoles in root meristematic cells of germinating seedlings by multiple, cell type-specific mechanisms

We have investigated the structural events associated with vacuole biogenesis in root tip cells of tobacco (Nicotiana tabacum) seedlings preserved by high-pressure freezing and freeze-substitution techniques. Our micrographs demonstrate that the lytic vacuoles (LVs) of root tip cells are derived from protein storage vacuoles (PSVs) by cell type-specific sets of transformation events. Analysis of the vacuole transformation pathways has been aided by the phytin-dependent black osmium staining of PSV luminal contents. In epidermal and outer cortex cells, the central LVs are formed by a process involving PSV fusion, storage protein degradation, and the gradual replacement of the PSV marker protein α-tonoplast intrinsic protein (TIP) with the LV marker protein γ-TIP. In contrast, in the inner cortex and vascular cylinder cells, the transformation events are more complex. During mobilization of the stored molecules, the PSV membranes collapse osmotically upon themselves, thereby squeezing the vacuolar contents into the remaining bulging vacuolar regions. The collapsed PSV membranes then differentiate into two domains: (1) vacuole "reinflation" domains that produce pre-LVs, and (2) multilamellar autophagosomal domains that are later engulfed by the pre-LVs. The multilamellar autophagosomal domains appear to originate from concentric sheets of PSV membranes that create compartments within which the cytoplasm begins to break down. Engulfment of the multilamellar autophagic vacuoles by the pre-LVs gives rise to the mature LVs. During pre-LV formation, the PSV marker α-TIP disappears and is replaced by the LV marker γ-TIP. These findings demonstrate that the central LVs of root cells arise from PSVs via cell type-specific transformation pathways.     

A tonoplast intrinsic protein (TIP) is present in seeds, roots and somatic embryos of Norway spruce (Picea abies)

Many plant species contain a seed-specific tonoplast intrinsic protein (TIP) in their protein storage vacuoles (PSVs). Although the function of the protein is not known, its structure implies it to act as a transporter protein, possibly during storage nutrient accumulation/breakdown or during desiccation/imbibition of seeds. As mature somatic embryos of Picea abies (L.) Karst. (Norway spruce) contain PSVs, we examined the presence of TIP in them. Both the megagametophyte and seed embryo accumulate storage nutrients, but at different times and we therefore studied the temporal accumulation of TIP during seed development. Antiserum against the seed-specific a-TIP of Phaseolus vulgaris recognized an abundant 27 kDa tonoplast protein in mature seeds of P. abies. By immunogold labeling of sectioned mature megagametophytes we localized the protein to the PSV membrane. We also isolated the membranes of the PSVs from mature seeds and purified an integral membrane protein that reacted heavily with the antiserum. A sequence of 11 amino acid residues [AEEATHPDSIR], that was obtained from a polypeptide after in-gel trypsin digestion of the purified membrane protein, showed high local identity to a-TIP of Arabidopsis thaliana and to a-TIP of P. vulgaris. The greatest accumulation of TIP in the megagametophytes occurred at the time of storage protein accumulation. A lower molecular mass band also stained from about the time of fertilization until early embryo development. The staining of this band disappeared as the higher molecular mass (27 kDa) band accumulated in the megagametophyte during seed development. Total protein was also extracted from developing zygotic embryos and from somatic embryos. In zygotic embryos low-levels of TIP were seen at all stages investigated, but stained most at the time of storage protein accumulation. The protein was also present in mature somatic embryos but not in proliferating embryogenic tissues in culture. In addition to the seed tissue material, the antiserum also reacted with proteins present in extracts from roots and hypocotyls but not cotyledons from 13-day-old seedlings.     

Distinct lytic vacuolar compartments are embedded inside the protein storage vacuole of dry and germinating Arabidopsis thaliana seeds

Plant cell vacuoles are diverse and dynamic structures. In particular, during seed germination, the protein storage vacuoles are rapidly replaced by a central lytic vacuole enabling rapid elongation of embryo cells. In this study, we investigate the dynamic remodeling of vacuolar compartments during Arabidopsis seed germination using immunocytochemistry with antibodies against tonoplast intrinsic protein (TIP) isoforms as well as proteins involved in nutrient mobilization and vacuolar acidification. Our results confirm the existence of a lytic compartment embedded in the protein storage vacuole of dry seeds, decorated by γ-TIP, the vacuolar proton pumping pyrophosphatase (V-PPase) and the metal transporter NRAMP4. They further indicate that this compartment disappears after stratification. It is then replaced by a newly formed lytic compartment, labeled by γ-TIP and V-PPase but not AtNRAMP4, which occupies a larger volume as germination progresses. Altogether, our results indicate the successive occurrence of two different lytic compartments in the protein storage vacuoles of germinating Arabidopsis cells. We propose that the first one corresponds to globoids specialized in mineral storage and the second one is at the origin of the central lytic vacuole in these cells.     

Protein mobilization in germinating mung bean seeds involves vacuolar sorting receptors and multivesicular bodies

Plants accumulate and store proteins in protein storage vacuoles (PSVs) during seed development and maturation. Upon seed germination, these storage proteins are mobilized to provide nutrients for seedling growth. However, little is known about the molecular mechanisms of protein degradation during seed germination. Here we test the hypothesis that vacuolar sorting receptor (VSR) proteins play a role in mediating protein degradation in germinating seeds. We demonstrate that both VSR proteins and hydrolytic enzymes are synthesized de novo during mung bean (Vigna radiata) seed germination. Immunogold electron microscopy with VSR antibodies demonstrate that VSRs mainly locate to the peripheral membrane of multivesicular bodies (MVBs), presumably as recycling receptors in day 1 germinating seeds, but become internalized to the MVB lumen, presumably for degradation at day 3 germination. Chemical cross-linking and immunoprecipitation with VSR antibodies have identified the cysteine protease aleurain as a specific VSR-interacting protein in germinating seeds. Further confocal immunofluorescence and immunogold electron microscopy studies demonstrate that VSR and aleurain colocalize to MVBs as well as PSVs in germinating seeds. Thus, MVBs in germinating seeds exercise dual functions: as a storage compartment for proteases that are physically separated from PSVs in the mature seed and as an intermediate compartment for VSR-mediated delivery of proteases from the Golgi apparatus to the PSV for protein degradation during seed germination.     

A unique family of proteins associated with internalized membranes in protein storage vacuoles of the Brassicaceae

The protein storage vacuole (PSV) is a specialized organelle in plant seeds that accumulates storage proteins and phytate during seed development. In many plant species, such as tomato and tobacco, the PSV contains two types of microscopically visible intra-organellar inclusions: a large crystalline lattice of membranes and proteins, the crystalloid, and one or a few large phytate crystals, the globoids. In seeds of the family Brassicaceae, the PSVs lack visible crystalloids and have many small globoids dispersed throughout. We biochemically fractionated PSVs from Brassica napus and defined a crystalloid-like fraction that contained integral membrane protein markers found in crystalloids of other plants. Protein analyses identified a previously undescribed family of proteins, the Brassicaceae PSV-embedded proteins (BPEPs), associated with 'crystalloid' and globoid fractions. The defining characteristics of the BPEPs are an N-terminal signal peptide and tandem MATH domains, which may mediate protein-protein interactions. Database analyses indicated that the BPEPs are unique to Brassicaceae. Immunofluorescence studies using anti-BPEP antibodies and antibodies to other biochemical markers to label B. napus and Arabidopsis thaliana seed sections localized the BPEPs to structures within the PSVs, whose appearance was consistent with a diffuse network of internalized membranes and globoids. These results demonstrate that Brassicaceae PSVs contain internalized membranes, and raise the possibility that BPEPs modify these internal membrane structures to yield a PSV morphology different from that of tomato or tobacco.     

Life with and without AtTIP1;1, an Arabidopsis aquaporin preferentially localized in the apposing tonoplasts of adjacent vacuoles

The Arabidopsis thaliana Tonoplast Intrinsic Protein 1;1 (AtTIP1;1) is a member of the tonoplast aquaporin family. The tissue-specific expression pattern and intracellular localization of AtTIP1;1 were characterized using GUS and GFP fusion genes. Results indicate that AtTIP1;1 is expressed in almost all cell types with the notable exception of meristematic cells. The highest level of AtTIP1;1 expression was detected in vessel-flanking cells in vascular bundles. AtTIP1;1-GFP fusion protein labelled the tonoplast of the central vacuole and other smaller peripheral vacuoles. The fusion protein was not found evenly distributed along the tonoplast continuum but concentrated in contact zones of tonoplasts from adjacent vacuoles and in invaginations of the central vacuole. Such invaginations may result from partially engulfed small vacuoles. A knockout mutant was isolated and characterized to gain insight into AtTIP1;1 function. No phenotypic alteration was found under optimal growth conditions indicating that AtTIP1;1 function is not essential to the plant and that some members of the TIP family may act redundantly to facilitate water flow across the tonoplast. However, a conditional root phenotype was observed when mutant plants were grown on a glycerol-containing medium.     

The protein-body proteins phytohemagglutinin and tonoplast intrinsic protein are targeted to vacuoles in leaves of transgenic tobacco

To demonstrate the relationship between protein-bodies in seeds and vacuoles in other tissues, we expressed the coding sequences of two bean (Phaseolus vulgaris L.) protein-body proteins in tobacco (Nicotiana tabacum L.). We chose phytohemagglutinin-L (PHA-L) and tonoplast intrinsic protein (TIP) as representatives of the protein-body contents and protein-body membrane, respectively. The location of the two proteins in the leaves of transgenic tobacco was examined by immunocytochemistry and in preparations of isolated vacuoles. Tonoplast intrinsic protein accumulates primarily in tonoplasts in tobacco leaves, whereas PHA is found exclusively in the vacuolar sap, showing that the signals that target proteins to protein-bodies and their limiting membranes in seeds are correctly recognized in leaves. This observation provides further evidence that proteinbodies of dicotyledonous seeds should be considered as protein-storage vacuoles.Abbreviations TIP tonoplast intrinsic protein - PHA phytohemagglutinin - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis This work has been supported by a grant from the U.S. Department of Agriculture Competitive Research Grants Office to Maarten J. Chrispeels. Herman Höfte is a recipient of a Postdoctoral Fellow-ship from the European Molecular Biology Organization. Craig Dickinson is a recipient of a National Institutes of Health Postdoctoral Fellowship. Loîc Faye was on leave from the Centre National de la Recherche Scientifique, UA203, Université de Rouen, Mont Saint Aignan France and supported by a cooperative CNRS — National S cience Foundation grant. The mention of vendor or product in this paper does not imply that they are endorsed or recommended by the U.S. Department of Agriculture over vendors of similar products not mentioned. We thank Jürgen Denecke for providing plasmid pDE1001, Antje von Schaewen for the plant expression cassette and Marie-Theres Hauser for the modified vacuole preparation protocol.     

A C-terminal sequence of soybean beta-conglycinin alpha' subunit acts as a vacuolar sorting determinant in seed cells

In maturing seed cells, many newly synthesized proteins are transported to the protein storage vacuoles (PSVs) via vesicles unique to seed cells. Vacuolar sorting determinants (VSDs) in most of these proteins have been determined using leaf, root or suspension-cultured cells apart from seed cells. In this study, we examined the VSD of the alpha' subunit of beta-conglycinin (7S globulin), one of the major seed storage proteins of soybean, using Arabidopsis and soybean seeds. The wild-type alpha' was transported to the matrix of the PSVs in seed cells of transgenic Arabidopsis, and it formed crystalloid-like structures. Some of the wild-type alpha' was also transported to the translucent compartments (TLCs) in the PSV presumed to be the globoid compartments. However, a derivative lacking the C-terminal 10 amino acids was not transported to the PSV matrix, and was secreted out of the cells, although a portion was also transported to the TLCs. The C-terminal region of alpha' was sufficient to transport a green fluorescent protein (GFP) to the PSV matrix. These indicate that alpha' contains two VSDs: one is present in the C-terminal 10 amino acids and is for the PSV matrix; and the other is for the TLC (the globoid compartment). We further verified that the C-terminal 10 amino acids were sufficient to transport GFP to the PSV matrix in soybean seed cells by using a transient expression system.     

An intrinsic tonoplast protein of protein storage vacuoles in seeds is structurally related to a bacterial solute transporter (GIpF).

The tonoplast mediates the transport of various ions and metabolites between the vacuole and cytosol by mechanisms that remain to be elucidated at the molecular level. The primary structure of only one tonoplast protein, the H(+)-ATPase, has been reported to date. Here we report the primary structure of tonoplast intrinsic protein (TIP), a 27-kilodalton intrinsic membrane protein that occurs widely in the tonoplasts of the protein storage vacuoles (protein bodies) of seeds [Johnson, K.D., et al. (1989). Plant Physiol. 91, 1006-1013]. Hydropathy plots and secondary structure analysis of the polypeptide predict six membrane-spanning domains connected by short loops and hydrophilic, cytoplasmically oriented N- and C-terminal regions. TIP displays significant homology with several other membrane proteins from diverse sources: major intrinsic polypeptide from bovine lens fiber plasma membrane; NOD 26, a peribacteroid membrane protein in the nitrogen-fixing root nodules of soybean; and interestingly, GIpF, the glycerol facilitator transport protein in the cytoplasmic membrane of Escherichia coli. Based on the homology between TIP and GIpF and the knowledge that the protein storage vacuolar membrane and the peribacteroid membrane are active in solute transport, we propose that TIP transports small metabolites between the storage vacuoles and cytoplasm of seed storage tissues.     

Storage globulins pass through the Golgi apparatus and multivesicular bodies in the absence of dense vesicle formation during early stages of cotyledon development in mung bean

During seed development and maturation, large amounts of storage proteins are synthesized and deposited in protein storage vacuoles (PSVs). Multiple mechanisms have been proposed to be responsible for transporting storage proteins to PSVs in developing seeds. In this study, a specific antibody was raised against the mung bean (Vigna radiata) seed storage protein 8S globulin and its deposition was followed via immunogold electron microscopy in developing mung bean cotyledons. It is demonstrated that non-aggregated 8S globulins are present in multivesicular bodies (MVBs) in early stages of cotyledon development where neither dense vesicles (DVs) nor a PSV were recognizable. However, at later stages of cotyledon development, condensed globulins were visible in both DVs and distinct MVBs with a novel form of partitioning, with the internal vesicles being pushed to one sector of this organelle. These distinct MVBs were no longer sensitive to wortmannin. This study thus indicates a possible role for MVBs in transporting storage proteins to PSVs during the early stage of seed development prior to the involvement of DVs. In addition, wortmannin treatment is shown to induce DVs to form aggregates and to fuse with the plasma membrane.     

A mitochondrion as the structural basis of the formation of a cell-type-specific organelle inDictyostelium development

Summary The mitochondrion has been mainly given attention as a self-reproductive and respiratory organelle. We report here that the mitochondrion may participate in the formation of a cell-type-specific organelle, coupling with the Golgi complex. During the development ofDictyostelium discoideum, the two types of cells, i.e., the anterior prestalk cells and the posterior prespore cells form a polarized cell mass. Prespore differentiation is characterized by the presence of unique vacuoles named PSVs (prespore-specific vacuoles) in the cytoplasm. Thus the PSV is the most essential organelle to understand the structural basis of cell differention in this organism. In differentiating prespore cells, the mitochondrion exerts a remarkable transformation to form a sort of vacuole (M-vacuole). Using a PSV specific antibody, it was immunocytochemically shown that a PSV antigen (C-10) is localized in the M-vacuole as well as in the lining membrane of PSV. Interestingly, the C-10 antigen was also noticed in the Golgi cisternae that had fused with M-vacuole. Based on these findings, we propose here a promising model which suggests how both mitochondria and Golgi cisternae may be coordinately involved in the PSV formation. This model will provide a new aspect of mitochondrial functions in cell differentiation.     

Spatial and temporal changes in lipase activity sites during oil body mobilization in protoplasts from sunflower seedling cotyledons

Hydrolysis of triacylglycerols (TAGs) catalyzed by lipase (triacylglycerol acylhydrolase; EC 3.1.1.3) action, is the principal biochemical event during oil body mobilization in germinating oilseeds. Employing a fluorescence microscopic technique developed in the author’s laboratory, a shift in the intracellular lipase activity has been demonstrated in the protoplasts of sunflower seedling cotyledons during seed germination. Lipase activity is primarily confined to protein storage vacuoles (PSVs) in 1 d old seedling cotyledons. At 2 d old stage, a relocalization of lipase activity begins and activity can be observed both on PSVs and oil bodies. At later stages of development (3–6 d), smaller PSVs coalesce into a large vegetative vacuole devoid of lipase activity. During this phase, lipase activity is confined to oil bodies only and maximum activity is detected in 4 d old seedlings, coinciding with maximum rate of lipolysis. Thus, present investigations on protoplasts from seedling cotyledons provide evidence for intracellular shift in lipase activity to sites of TAG hydrolysis (oil bodies) and also show a structural and functional reorganization of PSVs.     

Characterization of two integral membrane proteins located in the protein bodies of pumpkin seeds

Two integral membrane proteins, MP28 and MP23, were found in protein bodies isolated from pumpkin (Cucurbita sp.) seeds. Molecular characterization revealed that both MP28 and MP23 belong to the seed TIP (tonoplast intrinsic protein) subfamily. The predicted 29 kDa precursor to MP23 includes six putative membrane-spanning domains, and the loop between the first and second transmembrane domains is larger than that of MP28. The N-terminal sequence of the mature MP23 starts from residue 66 in the first loop, indicating that an N-terminal 7 kDa fragment that contains one transmembrane domain is post-translationally removed. During maturation of pumpkin seeds, mRNAs for MP28 and MP23 became detectable in cotyledons at the early stage, and their levels increased slightly until a rapid decrease occurred at the late stage. This is consistent with the accumulation of the 29 kDa precursor and MP28 in the cotyledons at the early stage. By contrast, MP23 appeared at the late stage simultaneously with the disappearance of the 29 kDa precursor. Thus, it seems possible that the conversion of the 29 kDa precursor to the mature MP23 might occur in the vacuoles after the middle stage of seed maturation. Both proteins were localized immunocytochemically on the membranes of the vacuoles at the middle stage and the protein bodies at the late stage. These results suggest that both MP28 and the precursor to MP23 accumulate on vacuolar membranes before the deposition of storage proteins, and then the precursor is converted to the mature MP23 at the late stage. These two TIPs might have a specific function during the maturation of pumpkin seeds.     

植物种子贮藏蛋白质及其细胞内转运与加工

高等植物种子成熟过程中贮存大量的贮藏蛋白质作为种子发芽和初期生长的重要营养来源。根据溶解性不同, 种子贮藏蛋白质可分为白蛋白、球蛋白、醇溶蛋白和谷蛋白4类。在种子胚发育过程中, 醇溶蛋白在粗面内质网合成后形成蛋白质聚集体, 直接出芽形成蛋白体并贮存其中。白蛋白、球蛋白和谷蛋白在粗面内质网以分子量较大的前体形式合成后, 根据各自的分选信号进入特定的运输囊泡, 经由受体依赖型运输/聚集体形式运输转运至蛋白质贮藏型液泡中, 然后经过液泡加工酶等的剪切转换为成熟型贮藏蛋白质并贮存其中。蛋白质的合成、分选、转运和加工等过程影响种子蛋白质的品质及含量。该文对种子贮藏蛋白质的分类和运输、加工以及这些过程对种子蛋白质品质和含量的影响进行了概述。     

植物种子贮藏蛋白质及其细胞内转运与加工

高等植物种子成熟过程中贮存大量的贮藏蛋白质作为种子发芽和初期生长的重要营养来源。根据溶解性不同,种子贮藏蛋白质可分为白蛋白、球蛋白、醇溶蛋白和谷蛋白4类。在种子胚发育过程中,醇溶蛋白在粗面内质网合成后形成蛋白质聚集体,直接出芽形成蛋白体并贮存其中。白蛋白、球蛋白和谷蛋白在粗面内质网以分子量较大的前体形式合成后,根据各自的分选信号进入特定的运输囊泡,经由受体依赖型运输/聚集体形式运输转运至蛋白质贮藏型液泡中,然后经过液泡加工酶等的剪切转换为成熟型贮藏蛋白质并贮存其中。蛋白质的合成、分选、转运和加工等过程影响种子蛋白质的品质及含量。该文对种子贮藏蛋白质的分类和运输、加工以及这些过程对种子蛋白质品质和含量的影响进行了概述。     

Accumulation of Vacuolar H+-Pyrophosphatase and H+-ATPase during Reformation of the Central Vacuole in Germinating Pumpkin Seeds

Protein storage vacuoles were examined for the induction of H+-pyrophosphatase (H+-PPase), H+-ATPase, and a membrane integral protein of 23 kD after seed germination. Membranes of protein storage vacuoles were prepared from dry seeds and etiolated cotyledons of pumpkin (Cucurbita sp.). Membrane vesicles from etiolated cotyledons had ATP- and pyrophosphate-dependent H+-transport activities. H+-ATPase activity was sensitive to nitrate and bafilomycin, and H+-PPase activity was stimulated by potassium ion and inhibited by dicyclohexylcarbodiimide. The activities of both enzymes increased after seed germination. On immunoblot analysis, the 73-kD polypeptide of H+-PPase and the two major subunits, 68 and 57 kD, of vacuolar H+-ATPase were detected in the vacuolar membranes of cotyledons, and the levels of the subunits of enzymes increased parallel to those of enzyme activities. Small amounts of the subunits of the enzymes were detected in dry cotyledons. Immunocytochemical analysis of the cotyledonous cells with anti-H+-PPase showed the close association of H+-PPase to the membranes of protein storage vacuoles. In endosperms of castor bean (Ricinus communis), both enzymes and their subunits increased after germination. Furthermore, the vacuolar membranes from etiolated cotyledons of pumpkin had a polypeptide that cross-reacted with antibody against a 23-kD membrane protein of radish vacuole, VM23, but the membranes of dry cotyledons did not. The results from this study suggest that H+-ATPase, H+-PPase, and VM23 are expressed and accumulated in the membranes of protein storage vacuoles after seed germination. Overall, the findings indicate that the membranes of protein storage vacuoles are transformed into those of central vacuoles during the growth of seedlings.     

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 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.