DEVELOPMENT OF PERIPHERAL VACUOLES IN PLANT CELLS

The vacuolar apparatus of various plant cells consists of two distinct features: the large central vacuole and peripheral vacuoles which are derived from invaginations of the plasma membrane. Peripheral vacuoles are conspicuous structures in both living and fixed hair or filament cells of Tradescantia virginiana. They occur as spherical structures along the inner boundary of the peripheral cytoplasm and can be recognized as projections into the central vacuole. These structures are variable in size and number within a cell and can represent a significant proportion of the volume of the vacuole. Peripheral vacuoles most frequently are observed in motion with the streaming cytoplasm although their velocity is usually somewhat slower that that of the cytoplasmic organelles. Ultrastructural studies show two closely approximated membranes, one for each vacuole, in areas where a peripheral vacuole projects into the central vacuole. These are separated by an intermembrane zone continuous with the peripheral cytoplasm. The movement of organelles over the perimeter of the peripheral vacuole is presumed to occur along this intermembrane zone. The internal area of the peripheral vacuoles may appear empty although some contain a vesicular content of unknown origin and function.     

Multiple vacuoles in impaired tonoplast trafficking3 mutants are independent organelles

Plant vacuoles are essential and dynamic organelles, and mechanisms of vacuole biogenesis and fusion are not well characterized. We recently demonstrated that Wortmannin, an inhibitor of Phosphatidylinositol 3-Kinase (PI3K), induces the fusion of plant vacuoles both in roots of itt3/vti11 mutant alleles and in guard cells of wild type Arabidopsis and Fava bean. Here we used Fluorescence Recovery After Photobleaching (FRAP) to demonstrate that the vacuoles in itt3/vti11 are independent organelles. Furthermore, we used fluorescent protein reporters that bind specifically to Phosphatidylinositol 3-Phosphate (PtdIns(3)P) or PtdIns(4)P to show that Wortmannin treatments that induce the fusion of vti11 vacuoles result in the loss of PtdIns(3)P from cellular membranes. These results provided supporting evidence for a critical role of PtdIns(3)P in vacuole fusion in roots and guard cells.     

Pinocytosis in the root cells of a salt-accumulating halophyte <Emphasis Type="Italic">Suaeda altissima</Emphasis> and its possible involvement in chloride transport

Ultrastructure of root cells in salt-accumulating halophyte Suaeda altissima (L.) Pall. was examined with transmission electron microscopy. Plants were grown hydroponically on nutrient media containing 3, 50, 250, and 500 mM NaCl. Some plants were exposed to hypersomotic salt shock by an abrupt increase in NaCl concentration from 50 to 400 mM. Growing S. altissima plants at high NaCl concentrations induced the formation of type 1 pinocytotic structures in root cells. Type 1 structures appeared as pinocytotic invaginations of two membranes, the plasmalemma and tonoplast. These invaginations into vacuoles gave rise to freely ‘floating’ multivesicular bodies (MVB) enclosed by a double membrane layer. The pinocytotic invaginations and MVB contained the plasmalemma-derived vesicles and membranes of endosome origin. The hyperosmotic salt shock led to formation of type 2 and type 3 pinocytotic structures. The type 2 structures were formed as pinocytotic invaginations of the tonoplast and gave rise to MVB in vacuoles. Unlike type 1 MVB, the type 2 MVB had only one enclosing membrane, the tonoplast. The type 3 structures appeared as the plasmalemma-derived vesicles located in the periplasmic space. The cytochemical electron-microscopy method was applied to determine the intracellular Cl^? localization. This method, based on sedimentation of electron-dense AgCl granules in tissues treated with silver nitrate, showed that the pinocytotic structures of all types contain Cl^? ions. The presence of Cl^? in pinocytotic structures implies the involvement of these structures in Cl^? transport between the apoplast, cytoplasm, and the vacuole.     

Differential Translocation of Host Cellular Materials into the Chlamydia trachomatis Inclusion Lumen during Chemical Fixation

Chlamydia trachomatis manipulates host cellular pathways to ensure its proliferation and survival. Translocation of host materials into the pathogenic vacuole (termed ‘inclusion’) may facilitate nutrient acquisition and various organelles have been observed within the inclusion, including lipid droplets, peroxisomes, multivesicular body components, and membranes of the endoplasmic reticulum (ER). However, few of these processes have been documented in living cells. Here, we survey the localization of a broad panel of subcellular elements and find ER, mitochondria, and inclusion membranes within the inclusion lumen of fixed cells. However, we see little evidence of intraluminal localization of these organelles in live inclusions. Using time-lapse video microscopy we document ER marker translocation into the inclusion lumen during chemical fixation. These intra-inclusion ER elements resist a variety of post-fixation manipulations and are detectable via immunofluorescence microscopy. We speculate that the localization of a subset of organelles may be exaggerated during fixation. Finally, we find similar structures within the pathogenic vacuole of Coxiella burnetti infected cells, suggesting that fixation-induced translocation of cellular materials may occur into the vacuole of a range of intracellular pathogens.     

The Mechanism of Food Intake in Tokophrya infusionum and Ultrastructural Changes in Food Vacuoles during Digestion*

SYNOPSIS Food intake in Tokophrya infusionum is preceded by penetration of the knob of the tentacle into the cytoplasm of the prey, Tetrahymena. Immediately thereafter, the membrane of the knob starts to invaginate into the lumen of the inner tube of the tentacle carrying with it the cytoplasm of the prey. At the proximal end of the tentacle, the invaginating membrane inflates, pinches off and forms a food vacuole. The mechanism is similar to that in amoebae during pinocytosis. The first few food vacuoles contain broken-up membranes, an indication that predigestion of prey cytoplasm takes place. This process is limited, however, to the part of cytoplasm around the knob since all food vacuoles formed later are composed of intact cytoplasmic organelles of Tetrahymena. Among them the most abundant and at the same time the most resistant to digestion are mitochondria and mucocysts. The ultrastructure of mitochondria is preserved very well during processing for electron microscopy and changes in their fine structure therefore serve conveniently as markers of the stage of digestion and of the age of food vacuoles. Digestion of mitochondria progresses over a period of several hours. They finally seem to degrade into glycogen-like particles. All components of the food vacuole reach this stage much earlier. Digestion proceeds further until the food vacuole is filled with a watery content of very low density. Digestion in such food vacuoles is completed. The complete digestion of the content of food vacuoles is of primary importance for Tokophrya, since this organism does not have a cytopyge thru which waste products could be eliminated.     

The AP-3 �� Adaptin Mediates the Biogenesis and Function of Lytic Vacuoles in Arabidopsis

Plant vacuoles are essential multifunctional organelles largely distinct from similar organelles in other eukaryotes. Embryo protein storage vacuoles and the lytic vacuoles that perform a general degradation function are the best characterized, but little is known about the biogenesis and transition between these vacuolar types. Here, we designed a fluorescent marker–based forward genetic screen in Arabidopsis thaliana and identified a protein affected trafficking2 (pat2) mutant, whose lytic vacuoles display altered morphology and accumulation of proteins. Unlike other mutants affecting the vacuole, pat2 is specifically defective in the biogenesis, identity, and function of lytic vacuoles but shows normal sorting of proteins to storage vacuoles. PAT2 encodes a putative β-subunit of adaptor protein complex 3 (AP-3) that can partially complement the corresponding yeast mutant. Manipulations of the putative AP-3 β adaptin functions suggest a plant-specific role for the evolutionarily conserved AP-3 β in mediating lytic vacuole performance and transition of storage into the lytic vacuoles independently of the main prevacuolar compartment-based trafficking route.     

From Storage Compartment to Lytic Organelle: The Metamorphosis of the Aleurone Protein Storage Vacuole

Protein storage vacuoles are found in a variety of tissues butare especially abundant in the storage organs of fruits andseeds. In this review, we focus on the protein storage vacuolesof cereal aleurone. In the mature grain, these organelles arerepositories for reserve nitrogen, carbon and minerals. Followingimbibition, protein storage vacuoles of cereal aleurone changefrom storage compartments to lytic organelles. Changes in proteinstorage vacuole structure and enzymatic activity during thistransition are discussed. It is emphasized that protein storagevacuoles are poised for reserve mobilization, and that gibberellinperception by the aleurone cell initiates a signalling cascadethat promotes acidification of the vacuole lumen and activationof enzymes and transporters.Copyright 1998 Annals of BotanyCompany Protein storage vacuole, cereal aleurone, gibberellin, abscisic acid, protein body, endosperm reserves.     

Adjustment of Host Cells for Accommodation of Symbiotic Bacteria: Vacuole Defunctionalization,HOPS Suppression,and TIP1g Retargeting in Medicago

In legume–rhizobia symbioses, the bacteria in infected cells are enclosed in a plant membrane, forming organelle-like compartments called symbiosomes. Symbiosomes remain as individual units and avoid fusion with lytic vacuoles of host cells. We observed changes in the vacuole volume of infected cells and thus hypothesized that microsymbionts may cause modifications in vacuole formation or function. To examine this, we quantified the volumes and surface areas of plant cells, vacuoles, and symbiosomes in root nodules of Medicago truncatula and analyzed the expression and localization of VPS11 and VPS39, members of the HOPS vacuole-tethering complex. During the maturation of symbiosomes to become N₂-fixing organelles, a developmental switch occurs and changes in vacuole features are induced. For example, we found that expression of VPS11 and VPS39 in infected cells is suppressed and host cell vacuoles contract, permitting the expansion of symbiosomes. Trafficking of tonoplast-targeted proteins in infected symbiotic cells is also altered, as shown by retargeting of the aquaporin TIP1g from the tonoplast membrane to the symbiosome membrane. This retargeting appears to be essential for the maturation of symbiosomes. We propose that these alterations in the function of the vacuole are key events in the adaptation of the plant cell to host intracellular symbiotic bacteria.     

Inhibition of lysosomal fusion with symbiont-containing vacuoles in Paramecium bursaria

Paramecium bursaria harbors several hundred intracellular Chlorella symbionts which remain undigested at the same time that the host cell phagocytizes and digests other organisms. Using electron microscopy and thorotrast labelling, we have shown that secondary lysosomes fuse with food vacuoles, but do not fuse with vacuoles containing symbiotic algae. From these and other data we suggest that the symbiotic algae alter the membrane of the vacuole which surrounds them, thus inhibiting fusion with secondary lysosomes.     

Isolation of Vacuoles from Root Storage Tissue of Beta vulgaris L

Morphologically intact and osmotically active vacuoles were isolated from root storage tissue of the red beet Beta vulgaris L., and the factors influencing both yield and stability of the vacuoles were determined. Successful isolation depended upon slicing the tissue in an apparatus specifically designed to cut open plant cells without the use of high shear forces and to liberate cellular organelles into an undisturbed reservoir of osmoticum. The resulting brei was centrifuged at 2,000g for 10 min to yield a pellet which contained many vacuoles but which also contained tissue fragments, nuclei, mitochondria, and plastids. The vacuoles were further purified by accelerated flotation through a Metrizamide step gradient. Biochemical assays, light microscopy, and electron microscopy confirmed that there was only trace contamination of the final vacuole preparation by other organelles. Isolated vacuoles were intact and retained their in vivo coloration.     

DIGESTION AND THE DISTRIBUTION OF ACID PHOSPHATASE IN BLEPHARISMA

Suspensions of Blepharisma intermedium were fed latex particles for 5 min and then were separated from the particles by filtration. Samples were fixed at intervals after separation and incubated to demonstrate acid phosphatase activity. They were subsequently embedded and sectioned for electron microscopy. During formation of the food vacuole, the vacuolar membrane is acid phosphatase-negative. Within 5 min, dumbbell-shaped acid phosphatase-positive bodies, possibly derived from the the acid phosphatase-positive Golgi apparatus, apparently fuse with the food vacuole and render it acid phosphatase-positive. A larger type of acid phosphatase-positive, vacuolated body may also fuse with the food vacuole at later stages. At about 20 min after formation, acid phosphatase-positive secondary pinocytotic vesicles pinch off from the food vacuoles and approach a separate system of membrane-bounded spaces. By 1 hr after formation, the food vacuole becomes acid phosphatase-negative, and the undigested latex particles are voided into the membrane-bounded spaces. The membrane-bounded spaces are closely associated with the food vacuole at all stages of digestion and are generally acid phosphatase-negative. Within the membrane-bounded spaces, dense, pleomorphic, granular bodies are found, in which are embedded mitochondria, paraglycogen granules, membrane-limited acid phosphatase-containing structures, and Golgi apparatuses. The granular bodies may serve as vehicles for the transport of organelles through the extensive, ramifying membrane-bounded spaces.     

Differentiation of Non-articulated Laticifers in Poinsettia (Euphorbia pulcherrima Willd.)

Differentiation of non-articulated laticifers in poinsettia(Euphorbia pulcherrima Willd.) was studied ultra-structurally.Growing laticifers show: (1) a multinucleate apical region containingabundant ribosomes but few other differentiated organelles and(2) a sub-apical zone where the cytoplasm is dominated by vacuolesof diverse morphology with latex particles. These particlesappear first within narrow tubular vacuoles developed especiallyin the peripheral cytoplasm. During vacuolation of the laticifer,portions of cytoplasm, including some of the nuclei, becomeisolated by the enlarging and fusing vacuoles; eventually thesebecome lysed, except the latex particles which remain in thecentral vacuole. During differentiation of a laticifer branch,the cytoplasm contains the usual organelles, including a fewmicrobodies and coated vesicles. The plastids that lie withinthe peripheral cytoplasm differentiate into amyloplasts witha single elongated starch grain. Towards the end of differentiationthe cytoplasm becomes restricted to a thin parietal layer, withthe remaining organelles reduced or degenerate, surroundinga central vacuole filled with latex particles. Euphorbia pulcherrima Willd, poinsettia, ultrastructure, differentiation, laticifers     

ULTRASTRUCTURAL STUDIES PLASMA MEMBRANE RELATED SECONDARY VACUOLES IN CULTURED CELLS

The plasma membrane of cultured cells of several plant species was observed to possess invaginations, or secondary vacuoles, of variable size in the adjacent cytoplasm. These structures, which occurred in cells at different phases in vacuolation, were very numerous in thin sections of some cells but fewer in others. In vacuolated cells enlarged secondary vacuoles protrude into the primary vacuole but are delimited from the tonoplast by an intermembrane zone of variable width. The plasma membrane at the orifice of an invagination may fuse and detach the secondary vacuole from the membrane to form in the cytoplasm a structure bounded by a single membrane. Complex accumulations of membranes consisting of spherical, tubular, and laminar structures, possibly containing cytoplasm, may develop within secondary vacuoles. Contents of many of these vacuoles arise from folds along its limiting membrane which pinch off into the interior of the secondary vacuole. A fibrous substance, possibly derived from the wall, is present in some secondary vacuoles. Observed folding of the plasma membrane and measurements of membrane width of various organelles and cytomembranes support an interpretation that endocytosis occurs in cultured cells.     

AP180-Mediated Trafficking of Vamp7B Limits Homotypic Fusion of Dictyostelium Contractile Vacuoles

Clathrin-coated vesicles play an established role in endocytosis from the plasma membrane, but they are also found on internal organelles. We examined the composition of clathrin-coated vesicles on an internal organelle responsible for osmoregulation, the Dictyostelium discoideum contractile vacuole. Clathrin puncta on contractile vacuoles contained multiple accessory proteins typical of plasma membrane–coated pits, including AP2, AP180, and epsin, but not Hip1r. To examine how these clathrin accessory proteins influenced the contractile vacuole, we generated cell lines that carried single and double gene knockouts in the same genetic background. Single or double mutants that lacked AP180 or AP2 exhibited abnormally large contractile vacuoles. The enlarged contractile vacuoles in AP180-null mutants formed because of excessive homotypic fusion among contractile vacuoles. The SNARE protein Vamp7B was mislocalized and enriched on the contractile vacuoles of AP180-null mutants. In vitro assays revealed that AP180 interacted with the cytoplasmic domain of Vamp7B. We propose that AP180 directs Vamp7B into clathrin-coated vesicles on contractile vacuoles, creating an efficient mechanism for regulating the internal distribution of fusion-competent SNARE proteins and limiting homotypic fusions among contractile vacuoles. Dictyostelium contractile vacuoles offer a valuable system to study clathrin-coated vesicles on internal organelles within eukaryotic cells.     

Subcellular Localization of Anthocyanin Methyltransferase in Flowers of Petunia hybrida

The subcellular localization of the enzyme anthocyanin-methyltransferase was studied in cells (protoplasts) obtained from the upper epidermis of petals of Petunia hybrida Hort. Vacuoles were isolated from protoplasts to ascertain the possible presence of the enzyme in these organelles. The recovery of methyltransferase activity in vacuole-enriched fractions equalled that of the cytosolic marker enzyme glucose-6-phosphate dehydrogenase. The relative activity of methyltransferase in the vacuole fraction was one tenth of that in the protoplast. Neither whole protoplasts nor isolated vacuoles contained inhibitors of methyltransferase activity. Examination of fractions obtained by differential centrifugation of a protoplast lysate showed that the major part of the methyltransferase activity was cytosolic. Activity found in a 130,000g pellet was due to nonspecific adhesion to membranes. The results indicate that terminal steps of anthocyanin biosynthesis take place in the cytosol. They do not lend support to the notion that the vacuole might be involved in (part of) this process.     

Characterization of a Novel Prevacuolar Compartment in Neurospora crassa

Using confocal microscopy, we observed ring-like organelles, similar in size to nuclei, in the hyphal tip of the filamentous fungus Neurospora crassa. These organelles contained a subset of vacuolar proteins. We hypothesize that they are novel prevacuolar compartments (PVCs). We examined the locations of several vacuolar enzymes and of fluorescent compounds that target the vacuole. Vacuolar membrane proteins, such as the vacuolar ATPase (VMA-1) and the polyphosphate polymerase (VTC-4), were observed in the PVCs. A pigment produced by adenine auxotrophs, used to visualize vacuoles, also accumulated in PVCs. Soluble enzymes of the vacuolar lumen, alkaline phosphatase and carboxypeptidase Y, were not observed in PVCs. The fluorescent molecule Oregon Green 488 carboxylic acid diacetate, succinimidyl ester (carboxy-DFFDA) accumulated in vacuoles and in a subset of PVCs, suggesting maturation of PVCs from the tip to distal regions. Three of the nine Rab GTPases in N. crassa, RAB-2, RAB-4, and RAB-7, localized to the PVCs. RAB-2 and RAB-4, which have similar amino acid sequences, are present in filamentous fungi but not in yeasts, and no function has previously been reported for these Rab GTPases in fungi. PVCs are highly pleomorphic, producing tubular projections that subsequently become detached. Dynein and dynactin formed globular clusters enclosed inside the lumen of PVCs. The size, structure, dynamic behavior, and protein composition of the PVCs appear to be significantly different from those of the well-studied prevacuolar compartment of yeasts.     

Ultrastructural and cytochemical studies on the developing adhesive disc of Boston Ivy tendrils

Summary Ultrastructural observations of the immature adhesive disc from tendrils of Boston Ivy showed that the peripheral cells, which are the presumptive contact layer, contain vacuoles of varied sizes which are filled with electron-dense aggregates. In small vacuoles, these deposits were appressed to the tonoplast and fusion of these small vacuoles with the large vacuoles apparently occurs. Cells from the central zone were largely parenchymatous. The vacuoles of many of these parenchyma cells contained electron-dense spheres and hemispheres of material either appressed to the tonoplast or within the vacuole lumen. In these cells, the vacuole-cytoplasm interface was characterized by a filiform network of interconnected membranes. Positive reactions with reagents for the identification of polyphenols indicate that the vacuoles of nearly all the peripheral cells and scattered cells of the central zone contain tanniniferous substances. Insoluble carbohydrates also occur in the vacuoles of the peripheral cells, but they contain little or no protein or lipid.     

Autophagic tubes: vacuolar invaginations involved in lateral membrane sorting and inverse vesicle budding

Many intracellular compartments of eukaryotic cells do not adopt a spherical shape, which would be expected in the absence of mechanisms organizing their structure. However, little is known about the principles determining the shape of organelles. We have observed very defined structural changes of vacuoles, the lysosome equivalents of yeast. The vacuolar membrane can form a large tubular invagination from which vesicles bud off into the lumen of the organelle. Formation of the tube is regulated via the Apg/Aut pathway. Its lumen is continuous with the cytosol, making this inverse budding reaction equivalent to microautophagocytosis. The tube is highly dynamic, often branched, and defined by a sharp kink of the vacuolar membrane at the site of invagination. The tube is formed by vacuoles in an autonomous fashion. It persists after vacuole isolation and, therefore, is independent of surrounding cytoskeleton. There is a striking lateral heterogeneity along the tube, with a high density of transmembrane particles at the base and a smooth zone devoid of transmembrane particles at the tip where budding occurs. We postulate a lateral sorting mechanism along the tube that mediates a depletion of large transmembrane proteins at the tip and results in the inverse budding of lipid-rich vesicles into the lumen of the organelle.     

Superoxide dismutase of plant cell vacuoles

Metal-dependent superoxide dismutases (SOD; EC 1.15.1.1) are present in many cell compartments (mitochondria, plastids, nuclei, peroxisomes, endoplasmic reticulum, cell wall and cytosol). We have established that SOD is also localized in the central vacuole. Cyanide-sensitive Cu, Zn-SOD was found in the fraction of isolated vacuoles of red beet roots (Beta vulgaris L.). The enzyme was represented by three isoforms. Comparison of isoenzyme composition and the level of SOD activity in vacuoles, nuclei, plastids and mitochondria isolated from root cells has shown that Cu, Zn-SOD is present in vacuoles and nuclei, two SOD forms (Cu, Zn- and Fe-SOD) are present in plastids, and two SOD forms (Cu, Zn- and Mn-SOD) are present in mitochondria. Cu, Zn-SOD of organelles, unlike vacuolar Cu, Zn-SOD, had only one isoform. The level of enzyme activity from the vacuolar fraction was twice higher than the level of SOD activity from the fractions of isolated organelles. Previously it has been suggested that Cu, Zn-SOD may be localized on the vacuolar membrane or in the near-membrane space from the side of cytoplasm. Our tests have revealed the Cu, Zn-SOD activity in water-soluble extracts of isolated vacuole fractions in the absence of detergent, which may confirm localization of the enzyme inside the organelles.