Reactions of yeast cells to glycerol treatment alterations to membrane structure and glycerol uptake

Summary Ultrastructural alterations to the plasmalemma and tonoplast ofSaccharomyces cerevisiae were studied after incubation in hypertonic solutions of glycerol and sorbitol. After 20 to 30 minutes incubation in glycerol, the cells had shrunk to about 40% of their original volume. Large depressions of the plasmalemma were then always found associated with the typical plasmalemma invaginations. The vacuoles of treated cells changed to an irregular form, the tonoplast intramembranous particles were clustered, and large smooth areas appeared. After 6 to 12 hours incubation, cell and vacuole volume, as well as plasmalemma and tonoplast ultrastructure, had reverted to normal. The rate of recovery was strongly temperature dependent.Protoplasts could be similarly shrunk, but no alterations to the plasmalemma ultrastructure were then observed; however, the tonoplast revealed particle clustering as observed in whole cells. Protoplasts also reverted to normal volume and ultrastructure after prolonged incubation. Cells and protoplasts treated with sorbitol showed similar phenomena, but remained shrunken.By the use of radioactive tracers, glycerol was shown to penetrate cells, protoplasts and isolated vacuoles, but no uptake of sorbitol could be demonstrated.During the glycerol permeation period (0.5 to 6 hours), numerous vesicles were found in the cytoplasm and these were possibly engulfed by the vacuole. Associated with the engulfment, patches of tonoplast intramembranous particles were found in a semicrystalline array. Osmotic stress induced alterations to membrane ultrastructure, due to the use of cryoprotective agents, are discussed.A preliminary note of the paper was given at the Sixth European Congress on Electron Microscopy, Jerusalem, 1976.     

Ultrastructural Localization of ATPase Activity in the Cells of the Apical Meristem Zone,Elongation Zone and Root Hair Zone of Tomato Roots

A comparative study on the cytochemical localization of adenosine triphosphatase (ATPase) activity reaction in the cells of the apical meristem zone, elongation zone and root hair zone of tomato roots was carried out by electron microscopic observations of lead phosphate precipitation. The following experimental results have been obtained: In the meristematic cells of tomato roots, the heavy lead phosphate deposits indicating a very high activity of ATPase were localized at plasmalemma, plasmodesmata, endoplasmic reticulum, Golgi bodies, nucleoli and chromatin (Figs. 1—2). The reaction products of ATPase activity were also observed at some sites of ground cytoplasm and cell wall, but they were not found in little vacuoles and on tonoplast. In the cells of elongation zone, the ATPase activity at plasmalemma and plasmodesmata was as high as that in the meristematic cells of root tip, while the ATPase activity at nucleoli, chromatin, endoplasmic reticulum and Golgi bodies was markedly lowered. On the other hand, the high ATPase activity was produced on the tonoplast of the developing and enlarging vacuoles (Fig. 3). In the cells of root hair zone, the high ATPase activity was shown at plasmalemma, tonoplast and intercellular spaces, but the ATPase activity at nucleoli, chromatin and endoplasmic reticulum was wholly inactivated. (Figs. 4—7). The above results indicate that the ATPase activity with membranes and organelles is altered when the functions of cells and organelles change. Therefore, it is evident that the ATPase activity may be closely related to many physiological functions.     

Plasmalemma- and tonoplast-ATPase activity in mesophyll protoplasts,vacuoles and microsomes of the Crassulacean-acid-metabolism plant Kalanchoe daigremontiana

Adenosine-triphosphatase activity on the plasmalemma and tonoplast of isolated mesophyll protoplasts, isolated vacuoles and tonoplast-derived microsomes of the Crassulacean-acid-metabolism plant Kalanchoe daigremontiana Hamet et Perr., was localized by a cytochemical procedure using lead citrate. Enzyme activity was detected on the cytoplasmic surfaces of the plasmalemma and tonoplast. The identity of the enzymes was confirmed by various treatments differentiating the enzymes by their sensitivity to inhibitors of plasmalemma and tonoplast H⁺-ATPase. Isolated vacuoles and microsomes prepared from isolated vacuoles clearly exhibited single-sided deposition on membrane surfaces.Abbveviations CAM Crassulacean acid metabolism - H⁺-ATPase proton-translocating ATPase     

Plasmalemma Invaginations in Cultured Callus of Stevia rebaudiana: Ultrastructure and Ultracytochemical Localization of Acid Phosphatase

The plasmalemma of cells within meristematic regions was observed to possess invaginations in cultured callus of Stevia rebaudiana under differentiation. The ultrastructure and acid phosphatase (AcPase) ultracytochemistry Of these invaginations were studied. The plasmalemma invaginations occurred in the cells at various stages of vacuolation. In cells with dense protoplasm, plasmalemma appeared undulated but occasionally spherical and variable in size with conspicuous invaginations that projected into the peripheral cytoplasm. In the partially vacuolated cells, plasmalemma invagination became voluminously enlarged with increased contents and structurally complexed. In vacuolated cells, the enlarged invaginations protruded into the central vacuole but were delimitted from the tonoplast by an intermembrane zone continuous with the peripheral cytoplasm. Complex accumulations of membranes consisting of vesicular and coiled membranous Structures might develop within the plasmalemma invaginations. AcPase localization demonstrated high enzymic activity in the plasmalemma and its associated invagination. It seemed likely that these invaginations were functionally analogous to the vacuoles and therefore constituted part of the lytic compartment in these cells.     

The Ultrastructure of Ion-Secreting and Non-Secreting Salt Glands of Limonium platyphyllum

The ultrastructure of salt glands in developing leaves of Limoniumplatyphyllum is described prior to exposure to 3% NaCl solution(with non-secreting glands) and after 4.5 and 18 h exposureto the salt solution. It is shown that in most glands, the transitionto active chloride transport was accompanied by the displacementof vacuoles toward the cell periphery and by the establishmentof plasmalemma contact sites with the tonoplast which appearedsimilar to gap junctions in animal epithelial cells. No evidencefor the exocytosis of vacuoles was found. It is suggested thatgland vacuoles may have a primary role in chloride secretionand that the tonoplast may be functionally asymmetrical, sothat the free part facing the hyaloplasm bears ion pumps, whereashighly permeable ion channels are active along the zone of contactwith the plasmalemma. It follows that the active step in chloridetransport in Limonium glands is the influx of ions into thevacuoles. Within the inner cup cells of the gland, vacuolescome into contact with the plasmalemma only at sites where thecell wall is adjacent to secretory and accessory cells. Suchan asymmetry appears to ensure the directed flux of ions intothis cell wall. Wall protuberances in the gland cells are rudimentaryand presumably not involved directly in NaCl secretion. Thenucleolus is activated during secretion and the frequency offree ribosomes is significantly increased, which is suggestiveof their involvement in the synthesis of membrane transportproteins. The ultrastructure of about one-third of the glandsremained unchanged in salt-treated leaves. Key words: Salt glands, ultrastructure, ion fluxes     

甜菊愈伤组织中的质膜内陷:超微结构和酸性磷酸酶细胞化学定位

对在分化条件下的甜菊 (Stevia rebaudiana)愈伤组织分生区域细胞的质膜内陷进行了超微结构和酸性磷酸酶细胞化学研究。结果表明 ,在不同液泡化状态的细胞中均有质膜内陷存在。在原生质浓密的细胞中 ,质膜呈起伏的波纹状 ,某些部位发生明显内陷 ,大小不等 ,多呈圆球状。在部分液泡化细胞中 ,质膜内陷体积增大 ,内含物增多且结构复杂。在液泡化细胞中 ,质膜内陷嵌入中央液泡 ,但彼此间以一膜间隙隔开。质膜内陷中的内含物以小泡和卷绕的膜结构形式存在。酸性磷酸酶活性定位结果显示 ,质膜及其内陷含高的酶活性。推测质膜内陷在功能上与液泡相似 ,构成了这些细胞水解空间的一部分。     

Altered ultrastructure of cells of sunflower leaves having low water potentials

Summary Desiccation-induced alterations in cell structure were investigated in sunflower (Helianthus annum L.) leaves using light and electron microscopy. Desiccation was imposed by withholding water from the tissue, and all tissue fixation was carried out under isosmotic conditions. In addition to shrinkage of the vacuoles and intercellular spaces caused by water loss, the significant features of cell desiccation were the appearance of lipid droplets and vesicles close to dictyosomes, and plasmalemma and/or tonoplast breakage in the mesophyll cells. Breakage was followed by massive loss of cell organelles except for the thylakoid membranes of the chloroplasts, which retained much of their integrity even in the air-dried state. Plasmalemma and tonoplast disruption began in a few cells at water potentials of — 15 bars (relative water contents of 47%) and went to completion below —26 bars (relative water contents less than 28%) in the leaf mesophyll. Typically in this tissue, net photosynthesis becomes zero and the tissue becomes increasingly incapable of full rehydration at water potentials below — 20 bars. By contrast, water potentials of — 26 bars had no detectable effects on the phloem tissue. Structural alterations were little influenced by the rapidity of desiccation (a few minutes to as long as four days). It was concluded that desiccation-induced changes in cell structure are tissue-specific and occur on a cell-by-cell basis rather than in all cells of a tissue at once. The concentration of the cytoplasm and the disruption of the plasmalemma and/or tonoplast seem to be central events in the alteration of cell ultrastructure by desiccation.This research was supported by NSF grant GB41314.     

General Mechanisms for Solute Transport Across the Tonoplast of Plant Vacuoles: a Patch-Clamp Survey of Ion Channels and Proton Pumps

The electrical properties of the tonoplast from a large variety of plant materials such as mesophyll cells, storage cells, tumor cells, suspension cultured cells, guard cells, coleoptile cells, and liverwort cells have been investigated using the patch-clamp technique. Whole-vacuole recordings were employed to study the dynamics of an ATP-dependent proton pump by directly measuring the electrogenic currents. The addition of Mg-ATP induced an inwardly directed current which depolarized the tonoplast (the vacuole becoming positive inside). Furthermore, voltage-dependent passive ion fluxes were analyzed using whole vacuoles and isolated membrane patches. Whole-vacuolar currents and single-channel currents were induced at hyperpolarizing potentials, whereas currents decreased at positive trans-tonoplast potentials. The electrical properties of the tonoplast of vacuoles from various plant tissues were similar and it was concluded that ion fluxes across the tonoplast follow the same general mechanisms.     

Sucrose transport at the tonoplast

Sucrose that leaked from maize scutellum slices upon transfer of slices from a hexose or hexitol solution to water or upon placing the slices in a buffered EDTA solution was considered to be cytoplasmic in origin; residual (after leakage) tissue sucrose was considered to be stored in the vacuoles. This paper presents a study of the movement of sucrose across the tonoplast between the vacuoles and the cytoplasmic compartment. It is concluded that; (a) sucrose transport into the vacuoles is directly linked to sucrose synthesis in such a way that free sucrose is not an intermediate in the coupled process, (b) cytoplasmic sucrose is not (cannot be?) stored, (c) sucrose transport out of the vacuoles is linked to the metabolic demand for sugar, and (d) the transport process removing sucrose from the vacuoles does not release free sucrose into the cytoplasm. The sucrose fluxes at the plasmalemma and at the tonoplast are calculated, and the transport processes at the two membranes are compared.     

The effect of hydrostatic pressure on structural organization of maize root cells

We analyzed the effect of hydrostatic pressure at the 2–4 MPa level on the growth and organization of maize seedlings cells. At a pressure value of 2 MPa, we observed clarification of mitochondrial matrix, clusterization of endoplasmic reticulum elements with formation of ergastoplasm sites, and an increase of the number of small vacuoles in the cytoplasm. On the trans-side of dictyosomes, we revealed accumulation of vesicles with an electron-dense content, which indicates changes of transport in the endomembranous system. A decrease in the electronic density of tonoplast was accompanied by a reduction of the osmophilic inclusion amount in vacuoles. An elevation of pressure up to 4 MPa has been shown to cause destructive alterations in the tonoplast. None of the variants showed any destruction of the plasmalemma integrity, which was confirmed by staining with Evans blue. At a fall of the pressure to an atmospheric value, the frequency of structural disturbances of the tonoplast membrane was proportional to the pressure difference: minimum at a drop from 2 to 0 MPa and maximum at a drop from 4 to 0 MPa. Thus, it was concluded that the endomembranous system was among the targets of the pressure effect on the plant cells.     

ULTRASTRUCTURE OF THE SHOOT APEX OF CHENOPODIUM ALBUM AND CERTAIN OTHER SEED PLANTS

The ultrastructure of cells of the vegetative shoot apices is described for Chenopodium album, Kalanchoë blossfeldiana and K. laxiflora, Bryophyllum daigremontianum, Nicotiana rustica, and N. tabacum (Maryland Mammoth), and Ginkgo biloba. A less intensive study was made of the last three listed. The structures and organelles usually associated with meristematic cells were observed: dictyosomes, plastids (in various stages of development), mitochondria, endoplasmic reticulum (ER), vacuoles, lipid droplets, and plasmalemma. In addition, spherosome-like structures were observed in all zones of the shoot apices. Also, multivesicular bodies were observed in C. album and B. daigremontianum. Ribosome density is greater in cells of the flank meristem. Proplastids, plastids with prolamellar bodies, or grana have a differential distribution in the apex, characteristic for a particular species. Confirmation could not be given to the concept that vacuoles arise as a series of local dilations in long extensions of the so called "smooth ER." The tonoplast and ER are distinguishable at the time of inception of a vacuole, although the tonoplast may arise from the ER. Rapid growth of a vacuole and/or fusion with other vacuoles may result in irregularly shaped prevacuoles. No vacuoles were observed to originate from cisternae of dictyosomes in the species studied.     

Kinetics of Ion Uptake in Higher Plants

Single, multiphasic mechanisms located in the plasmalemma and the tonoplast are proposed to mediate ion uptake in cells of higher plants. There are no parallel uptake mechanisms and, normally, little or no free diffusion across the plasmalemma. The plasmalemma controls the rate of uptake at low external salt concentrations, while the tonoplast may become rate-limiting at high concentrations.     

Localization of Phloem Oxidases

Among oxidases, cytochrome oxidase has been localized in mitochondria of all phloem cells, catalase has been visualized in parenchyma peroxisomes and peroxidase has been localized in cell walls and in several cell organelles. In angiosperms, peroxidase is present in all phloem cell walls; it is sensitive to cyanide inhibition excepted in sieve areas and around plasmodesmata between sieve tubes and companion cells. In some species, this cyanide resistant oxidasic activity can be localized without exogenous H₂O₂. Peroxidase is localized on ribosomes, inside vacuoles, on the tonoplast and often on the plasmalemma in companion cells and differentiating sieve elements. In young sieve cells some dictyosomes can exhibit a strong peroxidasic activity. In mature parenchyma cells peroxidase can be associated with ER cisternae but not with vacuoles.     

Immunocytochemical Localization of the Vacuolar H-ATPase in Maize Root Tip Cells

The vacuolar H⁺-ATPase of maize (Zea mays L.) root tip cells has been localized at the EM level using rabbit polyclonal antibodies to the 69 kilodalton subunit and protein A-colloidal gold. Intracellular gold particles were detected mainly on the tonoplast and Golgi membranes. Only about 27% of the vacuoles were labeled above background. The absence of gold particles on the majority of vacuoles suggests either that the tonoplast H⁺-ATPase is degraded during tissue preparation or that the small vacuoles of root tip cells are specialized with respect to H⁺-ATP ase activity. The pattern of gold particles on the labeled vacuoles ranged from uniform to patchy. Virtually all of the Golgi bodies were labeled by the antibody, but the particle densities were too low to determine whether the H⁺-ATPase was associated with specific regions, such as the trans-face. Cell wall-labeling was also observed which could be partially prevented by the inclusion of gelatin as a blocking agent. The immunocytochemical results confirm previous biochemical studies with isolated membrane fractions (A Chanson, L Taiz 1985 Plant Physiol 78: 232-240).     

Lipid phase separations and intramembranous particle movements in the yeast tonoplast

The tonoplast of Saccharomyces cerevisiae contains regions depleted of intramembranous particles as the cells enter stationary phase. Freeze-fracture studies on intact cells from this growth stage show that a dispersed particle distribution predominates if the cell temperature is raised to 40°C but that particle-depleted areas prevail at or below the cell growth temperature of 30°C. Tonoplasts of isolated vacuoles also contain particle-depleted regions. Differential thermal analyses of lipids extracted from isolated vacuoles show an endothermic transition which encompasses the cell growth temperature. These results suggest that the tonoplast at this stage contains patches of gel-phase lipid and that these patches correspond to the intramembranous particle-depleted areas of the freeze-fractured tonoplast.     

PEG-enhanced,electric field-induced fusion of tonoplast and plasmalemma of grape protoplasts

Cultured grape cells accumulate anthocyanins in vacuoles rather than secreting them into the nutrient medium. Therefore, grape cells that contain tonoplast segments in their plasmalemma should be capable of excreting anthocyanins rather than sequestering them in their vacuoles. In initial attempts to construct such novel cells, small vacuoles were fused with the plasmalemma of cultured plant cells. Protoplasts were isolated from grape calluses that produce and accumulate anthocyanins. Small vacuoles were formed by gently rupturing vacuoles isolated from grape protoplasts. Although small vacuoles and protoplasts became aligned in an AC field, the tonoplast and plasmalemma did not readily fuse when subjected to 3 DC pulses of 1200 V cm^–1 for 50 s each. Changes in the intensity, number and/or duration of the DC pulses had no effect on the fusion process. When 1.0% polyethylene glycol was added to the electrofusion buffer, however, small vacuoles and protoplasts fused within a few minutes after the DC pulses were applied. These novel grape cells remained viable for several hours.Abbreviations BSA bovine serum albumin - 2,4-D 2,4-dichloro-phenoxyacetic acid - DTT dithiothreitol - EGTA ethyleneglycol-bis-(-amino-ethyl ether)-N,N,N,N - MES 2-[N-Morpholino]ethanesulfonic acid - MOPS 3-[N-Morpholino]propanesulfonic acid - PVP polyvinylpyrrolidone     

Ultrastructural transitions associated with the development of the bladder cells of the trichomes of Atriplex

Early in development, bladder cells are characterized by the absence of a vacuole or vacuoles, the presence of autophagic vesicles, and numerous, unaggregated ribosomes. With the formation and expansion of the central vacuole, the ribosomes become aggregated and elements of rough endoplasmic reticulum become apparent. This developmental transition is probably related to the production of proteins involved in ion accumulation in the vacuole. Throughout expansion, invaginations of the tonoplast and membraneous structures are associated with the vacuole. These may be indicative of a continued lytic function for this compartment. Also, dictyosomes are continuously present and dictyosome vesicles are associated with both the plasmalemma and tonoplast, which suggest that they contribute to both membrane systems during expansion of the cell and vacuole.     

Histochemical localization of nucleoside triphosphatase activity in assimilate conducting plant tissue

Summary For the histochemical localization of nucleoside triphosphatases at the electron microscopic level, prefixed tissues were incubated with lead nitrate in addition to substrate (GOMORI reaction). While ATP and UTP as substrates gave electron-dense reaction products at the plasmalemma of sieve tubes, companion cells and phloem parenchyma cells, and at plasmodesmata in primary pitfields, AMP gave reaction products only at the tonoplast of parenchyma cells. Since electron-dense deposits also occur in cell walls and vacuoles, energy dispersive X-ray microanalysis was used to distinguish between lead deposits and lead-phosphate deposits. The latter were restricted to the symplast. Among the three plant species used, the leaf bundle phloem ofHordeum distichon showed ATPase activity largely restricted to the phloem cells, except for the thickwalled sieve tubes. Some activity also bordered the chloroplasts of the bundle sheath cells. In the C₄ plantGomphrena globosa, ATPase and UTPase activities appeared to be the greater in phloem parenchyma cells than in sieve tubes. In the phloem of youngMonstera deliciosa roots, ATPase occurred not only at the plasmalemma of sieve tubes, but also around sieve-tube plastids. When compared with AMP as substrate, it appears that nucleoside triphosphates are the natural substrates of the enzyme(s) in the plasmalemma of sieve tubes and phloem parenchyma cells.     

Isolation of intact vacuoles and proteomic analysis of tonoplast from suspension-cultured cells of Arabidopsis thaliana

A large number of proteins in the tonoplast, including pumps, carriers, ion channels and receptors support the various functions of the plant vacuole. To date, few proteins involved in these activities have been identified at the molecular level. In this study, proteomic analysis was used to identify new tonoplast proteins. A primary requirement of any organelle analysis by proteomics is that the purity of the isolated organelle needs to be high. Using suspension-cultured Arabidopsis cells (Arabidopsis Col-0 cell suspension), a method was developed for the isolation of intact highly purified vacuoles. No plasma membrane proteins were detected in Western blots of the isolated vacuole fraction, and only a few proteins from the Golgi and endoplasmic reticulum. The proteomic analysis of the purified tonoplast involved fractionation of the proteins by SDS-PAGE and analysis by LC-MS/MS. Using this approach, it was possible to identify 163 proteins. These included well-characterized tonoplast proteins such as V-type H+ -ATPases and V-type H+ -PPases, and others with functions reasonably expected to be related to the tonoplast. There were also a number of proteins for which a function has not yet been deduced.     

The proton pumps of the plasmalemma and the tonoplast of higher plants

Studies on intact cells, membrane vesicles, and reconstituted proteoliposomes have demonstrated in higher plants the existence of an ATP-driven electrogenic proton pump operating at the plasmalemma. There is also evidence of a second ATP-driven H⁺ pump localized at the tonoplast. The characteristics of both these ATP-driven pumps closely correspond to those of the plasmalemma and tonoplast proton pumps ofNeurospora and yeasts.