NaCl胁迫对5个引自北美的树种叶肉细胞超微结构的影响

为明确美国白蜡(Fraxinus americana L.)、茶条槭(Aceginnala Maxim.)、红桤木(Alnus rubra Bong.)、水紫树(Nyssa aquatica L.)和美国皂荚(Gleditsia triacanthos L.)5个引自北美的树种的耐盐性,采用水培方法、利用透射电镜技术对0(对照)、4和8 g·L-1 NaCl胁迫处理后5个树种1年生苗叶肉细胞超微结构的变化进行了观察和比较.观察结果表明:正常条件(0g·L-1NaCl)下,5个树种叶肉细胞在叶绿体形态、嗜锇颗粒数量等方面略有差异,但均未发生质壁分离现象.经NaCl胁迫处理后,5个树种叶肉细胞中的叶绿体和细胞核受到不同程度的损伤,表现为叶绿体膜消失,类囊体片层结构肿胀,叶绿体降解,嗜锇颗粒增大或增多,细胞核的核膜消失、核染色质凝聚;且随NaCl质量浓度的提高,损伤程度均逐渐加剧.4和8g·L-1NaC1胁迫条件下,美国皂荚、茶条槭和水紫树的叶肉细胞发生质壁分离现象,而红桤木、美国白蜡和水紫树的叶肉细胞内出现环状片层.根据观察结果,推测红桤木和美国白蜡对NaCl胁迫的耐性较强,美国皂荚和茶条槭也有一定的耐性,而水紫树的耐性最弱.     

Plasmolytic behavior of the donor cell may affect protoplast response

Protoplast donor tissues (leaves of shoots in culture) from a herbaceous plant ( Solanum etuberosum ) and two woody species ( Populus alba × P. grandidentata cv. Crandon and Betula platyphylla szechuanica ) were compared during plasmolysis in a range of osmotic agents and potentials. Cells from both Solanum and Populus , species proven to be amenable to protoplast division and regeneration, plasmolyzed readily at higher osmotic potentials than cells from Betula , a species recalcitrant to prolonged culture after protoplast isolation. Betula leaf mesophyll cells exhibited persistent membrane-to-wall attachments and many failed to plasmolyze even under extreme osmolarity. Although their leaves exhibited similar photosynthetic rates, photosynthetic capacity was lost from Betula protoplasts upon isolation, and retained by Solanum protoplasts. Differential stress after isolation was not detectable through vital staining, but only Solanum and Populus gave both high protoplast yields and high plating efficiencies in continued culture.     

Factors influencing protoplast isolation from Coffea arabica cells

Cultured plant cells such as Coffea arabica L. cells, accumulate low concentration of secondary metabolites. One way to obtain high-producing plant cell cultures is to prepare single cell clones by using protoplast systems. Identification of limiting factors should facilitate the development of an isolation procedure that can generate adequate yields of intact and viable protoplasts Coffea arabica L. suspension cells. The most suitable conditions for protoplasting were as follows: 6 g of fresh tissue were plasmolysed in 100 ml of K ₃ salts (Nagy & Maliga 1976) containing 0.5 M sucrose for 1 h at 24°C. Then, 1 g of preplasmolysed cells were incubated in 10 ml of cellulase R10 (1%), macerozyme R10 (0.8%) and driselase (0.5%) in preplasmolysis medium. The protoplasts were collected and purified after 15 h of lytic reaction in the dark, at 28°C. More than 75% and 95% of the cells were converted into protoplasts when 5 and 8 day-old suspensions respectively were used for the release step. A number of viable protoplasts ranging from 3.5×10⁶ to 4.6×10⁶ P g^-1 fresh weight was obtained corresponding to an increase by a factor 10 to 15 of the protoplast yield obtained by Acuna & De Pena (1991).Abbreviations BAP 6-benzylamino purine - BSA Bovine Serum Albumin - 2,4-d 2,4-dichlorophenoxyacetic acid - FDA fluorescein diacetate - MES 2-(N-morpholino)ethanesulfonic acid - NAA naphthalene acetic acid - PI propidium iodide - PCV Packed Cell Volume - fw fresh weight     

A simple method for discriminating between cell membrane and cytosolic proteins

* Transgenic plants expressing either green fluorescent protein (GFP)-genomic DNA or GFP-cDNA fusions have been used as powerful tools to define the subcellular localization of many proteins. Because most plant cells are highly vacuolated, the cytosol is confined to a thin layer at the periphery of the cells, making it very difficult to distinguish among cell wall, cell membrane and cytosolic GFP-fusion proteins. * Plasmolysis tests inform about cell-wall localization of GFP-tagged proteins, but they do not discriminate between its cell membrane and/or cytoplasmic localization. By observing the GFP signal in transgenic protoplasts placed at a hypotonic solution, it was possible to distinguish between cell membrane and cytosolic GFP-tagged proteins. * The osmotic disruption of the protoplast vacuole in the hypotonic solution allows the diffusion of the GFP signal from the cell periphery to the central part of the cell volume when the GFP is fused to a soluble protein. By contrast, such diffusion does not occur when the protein under study is attached to the cell membrane. * The present method is easier, faster and cheaper than subcellular fractionating studies and/or immunoelectron microscopy, which have been traditionally used to discern between cell membrane and cytosolic proteins.     

Plasma membrane ultrastructure in embryogenic cultures of orchardgrass during NaCl stress

Embryogenic cultures of Dactylis glomerata L. were subjected to NaCl stress by culturing for 4 passages in Schenk and Hildebrandt (SH) medium containing 30 μM dicamba and 200 mM NaCl. Ultrastructural studies indicated invaginations and disruptions of the plasma membrane. Membrane-bound vesicles were observed in the cytoplasm of NaCl treated cells and their occurrence were increased with the culture age.     

Enhanced adventive embryogenesis resulting from plasmolysis of cultured wild carrot cells

Adventive embryogenesis in vitro-grown somatic cells of Daucus carota L. was increased three-fold by a 45 min plasmolysis pre-treatment using 1M sucrose solutions. A high degree of synchronous development also resulted from this treatment. The enhancement of embryogenesis is interpreted as an increase in the regeneration of cells which have become physiologically somewhat isolated from the tissue of their origin by the plasmolysis-caused rupture of plasmodesmata. Possible causes of the increased synchrony are discussed.     

Behaviour of plasma membrane, cortical ER and plasmodesmata during plasmolysis of onion epidermal cells

During plasmolysis of onion epidermal cells, the contracting protoplast remains connected to the cell wall by an intricate, branched system of plasma membrane (PM) ‘Hechtian strands’ which stain strongly with the fluorescent probe DiOC₆. In addition, extensive regions of the cortical endoplasmic reticulum (ER) network remain anchored to the cell wall during plasmolysis and do not become incorporated into the contracting protoplast with the other cell organelles. These ER profiles become tightly encased by the PM as the latter contracts towards the centre of the cell. Thus, although the cortical ER is left outside the main protoplast body, it is nonetheless still bound by the PM of the cell. As well as being anchored to the wall, the cortical ER remains intimately linked with plasmodesmata and retains continuity between cells via the central desmotubules which become distended during plasmolysis. The PM also remains in close contact with the plasmodesmatal pore following plasmolysis. It is suggested that plasmodesmata, although sealed, may not be broken during plasmolysis, their substructure being preserved by continuity of both ER and PM through the plasmodesmatal pore. A structural model is presented which links the behaviour of PM, ER and plasmodesmata during plasmolysis.     

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.     

Chalcone Synthase Localization in Early Stages of Plant Development. I. Immunohistochemical Use of Plasmolysis for Localizing the Enzyme in Epidermal Cell Cytoplasm of Illuminated Buckwheat Hypocotyls

Immunohistochemical methods combined with progressive plasmolysis were used to localize chalcone synthase (CHS), an important enzyme for plant metabolism of aromatics in hypocotyls of illuminated buckwheat (Fagopyrum esculentum M) seedlings. Illumination of etiolated seedlings with white light results in anthocyanin synthesis in the epidermal layer of the hypocotyl. Anthocyanin-containing epidermal peels, after fixation for 30 min in 4% paraformaldehyde, 2.5% glutaraldehyde, 0.1% caffeine, were treated with a specific rabbit anti-buckwheat CHS antibody and a 20 nm goat anti-rabbit IgG gold conjugate. CHS is specifically shown in epidermal cells as pink to dark red deposits. Progressive plasmolysis combined with our immunohistochemical method showed that CHS was located exclusively in the cytoplasm of the epidermal cells of buckwheat hypocotyls except for the guard cells, which contained no detectable CHS.