ULTRASTRUCTURAL ASPECTS OF EARLY STAGES IN COTTON FIBER ELONGATION

Fine structural alterations associated with early stages of cotton fiber elongation in Gossypium hirsutum L. var. dunn 56 C occur rapidly following anthesis and appear to be correlated with the formation of the central vacuole, plasma membrane, and primary cell wall as well as with increased protein synthesis necessary for cell elongation. Association of dilated cisternae of the endoplasmic reticulum with the tonoplast suggests that the endoplasmic reticulum is involved in the formation of the central vacuole. Dictyosome involvement in both plasma membrane and primary cell wall formation was suggested from observations of similarities between dictyosome associated vesicles, containing fibrils appearing similar in morphology to fibrils found in the primary cell wall, and plasma membrane associated vesicles. The single nucleolus found in cotton fibers enlarges following anthesis, shows segregation of granular and fibrillar components by 1 day postanthesis, develops a large “vacuole,” thus appearing ring-shaped, and occupies much of the nuclear volume by 2 days postanthesis. Prominent nucleoli were not observed in nuclei after 10 days postanthesis.     

THE DEVELOPMENT OF MUCILAGINOUS RAPHIDE CRYSTAL IDIOBLASTS IN YOUNG LEAVES OF TYPHA ANGUSTIFOLIA L. (TYPHACEAE)

Raphide crystal idioblast initiation occurs in the uppermost region of intercalary meristems in young leaves of Typha angustifolia L., and development proceeds acropetally. Idioblast differentiation commences with a loss of stored lipids, depletion of starch from amyloplasts, enlargement of the nucleus and nucleolus, cell elongation, and the formation of a central vacuole. Crystalloplastids are formed via dedifferentiation of amyloplasts, followed by an increase in plastid number as cell volume increases with cell elongation. Crystalloplastid membranes stain intensely with periodic acid-thiocarbohydrazide-silver proteinate (PA-TCH-SP). Following crystal production within the central vacuole, crystalloplastids differentiate lobed regions, dense with plastid ribosomes, thylakoids, lamellae, and plastoglobuli. Mucilage, which stains with PA-TCH-SP, appears to be formed at the tonoplast in the central vacuole and follows differentiation of crystalloplastid lobes. Crystal chambers are surrounded by lamellae during mucilage accumulation and the crystals undergo a change in shape. Lobed crystalloplastids may be involved in vacuolar mucilage formation in these types of raphide crystal idioblasts.     

New insights into the tonoplast architecture of plant vacuoles and vacuolar dynamics during osmotic stress

Background  

The vegetative plant vacuole occupies >90% of the volume in mature plant cells. Vacuoles play fundamental roles in adjusting cellular homeostasis and allowing cell growth. The composition of the vacuole and the regulation of its volume depend on the coordinated activities of the transporters and channels localized in the membrane (named tonoplast) surrounding the vacuole. While the tonoplast protein complexes are well studied, the tonoplast itself is less well described. To extend our knowledge of how the vacuole folds inside the plant cell, we present three-dimensional reconstructions of vacuoles from tobacco suspension cells expressing the tonoplast aquaporin fusion gene BobTIP26-1::gfp.     

Nutrient Uptake Changes in Ascorbate Free Radical-Stimulated Onion Roots

Long-term treatments with ascorbate free radical-stimulated glucose, fucose, sucrose, and nitrate uptake in Allium cepa roots. Glucose and fucose showed saturation kinetics in untreated roots, but after treatment with the ascorbate free radical, uptake was linear with time. Although the rates of nitrate and sucrose uptake increased after treatment with ascorbate free radical, the kinetics were similar to those observed in the controls. Ascorbate and dehydroascorbate inhibited nutrient uptake. The uptake rates for all nutrients increased throughout the 48-h period of pretreatment with ascorbate free radical. During the treatment an increase in the vacuole volume and tonoplast surface area also occurred. These results show the relationship between an increase in vacuolar volume and stimulated nutrient uptake from ascorbate-free radical, resulting in enhanced root elongation. These results suggest that activation of a transplasma membrane redox system by ascorbate-free radical is involved in these responses.     

脱硫废弃物对碱胁迫下油葵幼叶细胞钙分布及Ca2+-ATPase活性的影响

利用脱硫废弃物改良盐碱地对于确保国家粮食安全和生态安全,发展循环经济具有重要意义。为了探索脱硫废弃物提高植物抗盐碱机理,采用盆栽试验法, 研究了施入不同量脱硫废弃物和CaSO₄对碱胁迫下油葵叶片细胞钙分布、总钙含量以及质膜和液泡膜Ca²⁺-ATPase活性的影响。结果表明:在碱胁迫下(CK),Ca²⁺与焦锑酸钾结合成黑色颗粒成团零星分布于叶绿体和液泡中,叶绿体超微结构受到不同程度的破坏。施入脱硫废弃物和CaSO₄,叶绿体结构完整,细胞间隙、细胞壁和液泡中的钙颗粒逐渐增多,同时,质膜和液泡膜Ca²⁺-ATPase活性随脱硫废弃物和纯品硫酸钙施量的增加而增加,其中液泡膜Ca²⁺-ATPase活性无论是对照(CK)还是处理的活性均高于质膜Ca²⁺-ATPase活性。叶片细胞内总钙含量也随脱硫废弃物和CaSO₄施用量的增加呈升高趋势。说明脱硫废弃物和CaSO₄通过增加Ca²⁺-ATPase活性,有利于钙通过质膜和液泡膜进入细胞内,维持膜结构的稳定性,缓解碱对油葵的胁迫。     

In vivo binding of auxin to the plasmalemma and tonoplast of parenchymal cells in the wheat coleoptile

Tritiated auxin applied by an agar block on the wheat coleoptile tip for 2 hr was covalently fixed to adjacent protein by treatment with 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride (DCC). The density of labelled auxin in the nucleus, the cell wall, the cytoplasm, and the vacuole was determined by autoradiography. Localization of tritiated auxin was studied at high resolution at the tonoplast and the plasmalemma lining the transverse (distal and proximal) and the longitudinal walls. The radioactivity along the tonoplast was always less than along the plasma membrane. The distribution of ³H-auxin was different across the longitudinal and transverse regions of the plasmalemma. The labelling was distributed asymmetrically on the longitudinal plasma membrane with a peak observed on the external surface. Tritiated auxin was distributed more symmetrically on the distal and the proximal plasma membranes. Our results are in agreement with the hypothesis that there are 2 different specific binding sites on the plasmalemma. The ratio of auxin present at the proximal and distal regions of the plasmalemma was 1.28.     

Ultrastructural Changes in Cambial Cell Derivatives during Xylem Differentiation in Poplar

Abstract: The changes in cellular structures that occur in cambial cell derivatives during xylogenesis were examined in Populus trichocarpa Torr et Gray. During dormancy, the cells of the vascular cambium are characterised by dense cytoplasm, many small vacuoles and lipid bodies. During cambial activation, cambial cells are highly vacuolated, the cytoplasm is rich in organelles and the nucleus contains distinctly enlarged nucleoli. The plasma membrane forms vesicle-filled invaginations which mediate uptake of vesicular material into the vacuole. The mitotic patterns in dividing fusiform cells are fragmentary due to their strong vacuolisation. During cell enlargement, cambial cell derivatives remain strongly vacuolated and cytoplasmic structures are similar to active fusiform cells. From the beginning of secondary cell wall formation many changes in cytoplasmic structures occur in newly-formed fibres and vessels. In fibres, the cytoplasm is characterised by components of secondary cell wall synthesis, as indicated by increased amounts of endoplasmic reticulum, vesicle-producing dictyosomes and microtubules. In contrast, vessels show a more or less distinct occurrence of these components and remain more strongly vacuolated than fibres. Similar to cambial cells, a distinct flow of vesicular material into the vacuole through invaginations of the plasma membrane is apparent in fibres, as well as in vessels. After completion of the secondary cell walls, the loss of tonoplast integrity causes the collapse of the vacuole and initiates cell death in vessels and fibres. In vessels the tonoplast exhibits unusually strong staining prior to the collapse of the vacuole, indicating subsequent cell death. Overall, our results indicate an important role for the vacuole in the xylogen differentiation of cambial derivatives.     

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.     

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.     

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.     

Changes in tonoplast protein and density with the development of pear fruit

Protoplasts isolated from pear fruit at the end of the cell‐division stage, 30 days after flowering (DAF), had already formed a large central vacuole and the vacuole occupied most of the protoplast. The changes in protein composition and density of the tonoplast (vacuolar membrane) were investigated during fruit development. After a linear sucrose density gradient centrifugation, the distribution of tonoplasts at 30 and 48 DAF was broad and began to narrow with further fruit development. This suggests that the tonoplast of young fruit is heterogeneous and becomes homogeneous with fruit development. The apparent density of the tonoplast at 30 DAF was approximately 1.12 g ml⁻¹; it decreased with fruit development and was finally 1.09 g ml⁻¹ in mature fruit. The phospholipid amount on the basis of tonoplast protein was 0.80 mg mg⁻¹ at 30 DAF. It increased with fruit development, and finally reached 7.49 mg mg⁻¹. This result indicates that the decrease in the density of the tonoplast was caused by the increase in the ratio of phospholipid to membrane protein. The protein composition of the tonoplast at each stage was quite different. The level of polypeptides of 94, 70, 61, 52, 48 and 41 kDa was low in young fruit and high in the middle or later stages of fruit development. In contrast, the level of a 76‐kDa polypeptide was high in young fruit and decreased with fruit development. Although their functions are still unclear, these tonoplast proteins may play important roles in fruit development.     

Isolation of tonoplast vesicles from tobacco protoplasts

Vacuoles were isolated from protoplasts of Nicotiana glutinosa by the method of Mettler and Leonard (Plant Physiol 1979 64: 1114-1120) with minor modifications so that the number of intact protoplasts contaminating the vacuole preparation was reduced to less than 1% (by number). Isopycnic centrifugation of a [³H]choline-labeled, sonicated vacuole preparation on linear 5 to 40% sucrose gradients indicated that tonoplast vesicles equilibrated at a density of about 1.12 grams per cubic centimeter. When tonoplast vesicles were isolated on discontinuous sucrose density gradients substrate specific ATPase activity was not found to be associated with this membrane fraction. These results are discussed in terms of the energetics of ion transport through the tonoplast membrane.     

Compartment analysis of plant cells by means of turgor pressure relaxation: I. Theoretical considerations

Summary Turgor pressure relaxation curves for individual plant cells represent an important source of information for the plant physiologist. However, the accurate interpretation of these curves is strongly dependent on the model chosen to describe the plant cell. If the compartmentation of the cell into vacuole and cytoplasm is taken into account, a theoretical analysis shows that pressure relaxation curves can be represented by the sum of two exponential functions. Givena priori assumptions about the exchange area of the tonoplast and its reflection coefficient, the hydraulic conductivities of the plasmalemma and tonoplast can be determined and the proportion of the total cell volume occupied by the cytoplasm is also obtained. Numerical solutions to the flow equations have shown that the biphasic nature of pressure relaxations is maintained even when a permeable tonoplast is assumed. Depending on the magnitude of the reflection coefficient and the permeability of the vacuolar membrane, large errors can arise in the determination of the hydraulic conductivity of the tonoplast. However, under certain conditions, even a highly permeable tonoplast may behave like a nonpermeable membrane during pressure relaxation.     

Is vacuole the richest store of IP3-mobilizable calcium in plant cells?

Inositol trisphosphate is known to mobilize calcium from internal stores in plant cells. However, with the exception of the vacuole, the largest plant cell compartment, organelles responsive to inositol trisphosphate have not been extensively identified. In this way, we have separated membrane vesicles from the same carrot microsomal fraction and identified them, both by marker enzyme activities and electron microscopy. These correspond to pure plasma membrane, pure tonoplast and mixed mitochondria, endoplasmic reticulum, Golgi membrane fractions. All the fractions accumulated calcium in a ATP-dependent manner and were tightly sealed. Inositol trisphosphate-dependent calcium releases were accurately measured only in fractions corresponding functionally and structurally to tonoplast, the vacuolar membrane. The process was dose-dependent and fairly specific for inositol trisphosphate. While highly significant, approximately 40% of the mobile calcium only may be released from tonoplast vesicles by inositol trisphosphate which remained basically intact during the release experiments. From these results it is concluded that the vacuole is the richest store of calcium directly mobilizable by inositol trisphosphate in plant cells, but inositol trisphosphate is not able to release the overall mobile vacuolar calcium.     

Newly formed vacuoles in root meristems of barley and pea seedlings have characteristics of both protein storage and lytic vacuoles

Plant cells are considered to possess functionally different types of vacuoles in the same cell. One of the papers cited in support of this concept reported that protein storage and lytic vacuoles in root tips of barley (Hordeum vulgare) and pea (Pisum sativum) seedlings were initially separate compartments that later fused to form a central vacuole during cell elongation. We have reinvestigated the situation in these two roots using immunogold electron microscopy as well as immunofluorescence microscopy of histological sections. Using antisera generated against the whole protein of alpha-tonoplast intrinsic protein (TIP) as well as specific C-terminal TIP peptide antisera against alpha-, gamma-, and delta-TIP, together with antisera against the storage proteins barley lectin and pea legumin and vicilin, we were unable to obtain evidence for separate vacuole populations. Instead, our observations point to the formation of a single type of vacuole in cells differentiating both proximally and distally from the root meristem. This is a hybrid-type vacuole containing storage proteins and having both alpha- and gamma-TIPs, but not delta-TIP, in its tonoplast. As cells differentiate toward the zone of elongation, their vacuoles are characterized by increasing amounts of gamma-TIP and decreasing amounts of alpha-TIP.     

Biochemical and immunocytochemical characterization of monoclonal antibody TOP 35 raised against purified tonoplast from cress root

The vacuolar membrane, the tonoplast, is a proteinrich membranehitherto only few proteins in it have been identified. As anapproach for the identification of tonoplast proteins by monoclonalantibodies (MABs), purified tonoplast from cress roots (Lepidiumsativum L.) were used for immunization and plasma membranesas a control membrane to test the absence of antigen. The MABTOP 35 identified a glycoprotein of about 35 kDa in purifiedtonoplast of cress roots. Triton X-114 phase separation showedthat it was a hydrophobic integral membrane protein. In immunocytochemistrythe MAB TOP 35 strongly labelled the vacuolar membrane. Theabsence of cell wall or plasma membrane labelling by TOP 35indicates a distinct biosynthetic pathway of this protein tothe vacuolar membrane in plants. Key words: Immnocytochemistry, Lepidium sativum, monoclonal antibody, secretion, vacuole     

Na+/H+ antiport activity in plasma membrane and tonoplast vesicles isolated from NaCl-treated cucumber roots

Sodium/proton antiporter activity in the plasma membrane and tonoplast of cucumber seedling roots treated with 200 mM NaCl for 24 h was determined. It was observed that plasma membrane and tonoplast antiporter activity was only present in membranes from salt-treated plants. In addition, the plasma membrane antiporter protein was present in membranes after induction with NaCl, whereas tonoplast antiporter protein was observed in control and at elevated level in NaCl-treated plants. Moreover, based on the affinity of studied antiporter proteins to sodium ions, it could be assumed that excess sodium ions are firstly translocated from the cytosol to the vacuole and then excluded to the apoplast through the plasma membrane.     

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.     

Membrane deletion during plasmolysis in hardened and non-hardened plant cells

Abstract Video recordings of interference phase contrast microscopy were used to study plasmalemma deletion during plasmolysis in hardened and non-hardened suspension cultured cells of Brassica napus, alfalfa, and cells isolated from rye seedlings. Although different hardening regimes and different cells were used, the responses to plasmolysis were consistent. Hardened cells uncoupled the volume to surface area ratio during plasmolysis both by forming a large number of strands between the cell wall and protoplast and by leaving rivulet-like networks of membranes on the cell wall surface. Tonoplast membrane was deleted as sac-like intrusions into the vacuole. Non-hardened cells produced few strands during plasmolysis. They also deleted plasmalemma and tonoplast into the vacuole as endocytotic vesicles. During deplasmolysis of hardened cells both the individual membrane strands and the rivulets of membrane material vesiculated into strings of vesicles. The vesicles were osmotically active and were re-incorporated into the expanding protoplast. Conversely, deplasmolysis in non-hardened cells resulted in few osmotically active vesicles and many broken strands. The vacuolar sac-like intrusions in hardened cells were re-incorporated into the vacuole whereas the endocytotic vesicles in non-hardened cells were not re-incorporated. Therefore, the non-hardened cells underwent expansion-induced lysis.     

The pathway of cell dismantling during programmed cell death in lace plant (Aponogeton madagascariensis) leaves

ABSTRACT: BACKGROUND: Developmentally regulated programmed cell death (PCD) is the controlled death of cells that occurs throughout the life cycle of both plants and animals. The lace plant (Aponogeton madagascariensis) forms perforations between longitudinal and transverse veins in spaces known as areoles, via developmental PCD; cell death begins in the center of these areoles and develops towards the margin, creating a gradient of PCD. This gradient was examined using both long- and short-term live cell imaging, in addition to histochemical staining, in order to establish the order of cellular events that occur during PCD. RESULTS: The first visible change observed was the reduction in anthocyanin pigmentation, followed by initial chloroplast changes and the bundling of actin microfilaments. At this stage, an increased number of transvacuolar strands (TVS) were evident. Perhaps concurrently with this, increased numbers of vesicles, small mitochondrial aggregates, and perinuclear accumulation of both chloroplasts and mitochondria were observed. The invagination of the tonoplast membrane and the presence of vesicles, both containing organelle materials, suggested evidence for both micro- and macro autophagy, respectively. Mitochondrial aggregates, as well as individual chloroplasts were subsequently seen undergoing Brownian motion in the vacuole. Following these changes, fragmentation of nuclear DNA, depolymerization of actin microfilaments and early cell wall changes were detected. The vacuole then swelled, causing nuclear displacement towards the plasma membrane (PM) and tonoplast rupture followed closely, indicating mega-autophagy. Subsequent to tonoplast rupture, cessation of Brownian motion occurred, as well as the loss of mitochondrial membrane potential (DeltaPsim), nuclear shrinkage and PM collapse. Timing from tonoplast rupture to PM collapse was approximately 20 minutes. The entire process from initial chlorophyll reduction to PM collapse took approximately 48 hours. Approximately six hours following PM collapse, cell wall disappearance began and was nearly complete within 24 hours. CONCLUSION: Results showed that a consistent sequence of events occurred during the remodeling of lace plant leaves, which provides an excellent system to study developmental PCD in vivo. These findings can be used to compare and contrast with other developmental PCD examples in plants.