A New Fluorescent Test for Cell Vitality Using Calcofluor White M2R

The fluorescent fabric-brightener dye, Calcofluor white M2R (CFW), can be used to distinguish between living and dead cells from a variety of animal and plant sources. CFW does not stain living mouse fibroblasts or trout red blood cells and stains only the cell walls in living cells from the epidermis of onion bulb scale, staminal hairs of Tradescantia, and longitudinal sections of broad bean stems and roots. Heat-killed plant or animal cells are recognized by their lightly stained cytoplasm and brightly stained nuclei. The optimum staining concentrations were very low (0.01% to 0.03%) and nontoxic. Using onion scale epidermis in which some cells had been killed by heating as a test system, and the plasmolysisdeplasmolysis rection as the ultimate test for cell vitality, results from CFW staining correctly predicted cell vitality for about 98% of the cells tested. This success rate was comparable to those for Evans blue, uranin or neutral red in this test system.     

Model system for plant cell biology: GFP imaging in living onion epidermal cells.

The ability to visualize organelle localization and dynamics is very useful in studying cellular physiological events. Until recently, this has been accomplished using a variety of staining methods. However, staining can give inaccurate information due to nonspecific staining, diffusion of the stain or through toxic effects. The ability to target green fluorescent protein (GFP) to various organelles allows for specific labeling of organelles in vivo. The disadvantages of GFP thus far have been the time and money involved in developing stable transformants or maintaining cell cultures for transient expression. In this paper, we present a rapid transient expression system using onion epidermal peels. We have localized GFP to various cellular compartments (including the cell wall) to illustrate the utility of this method and to visualize dynamics of these compartments. The onion epidermis has large, living, transparent cells in a monolayer, making them ideal for visualizing GFP. This method is easy and inexpensive, and it allows for testing of new GFP fusion proteins in a living tissue to determine deleterious effects and the ability to express before stable transformants are attempted.     

用于植物基因研究的mCherry表达载体构建及定位表达

荧光蛋白在生物学研究中具有广泛的应用和重要的作用,其中红色荧光蛋白mCherry因其颜色和良好的特性,对于植物基因研究具有重要的使用价值,本研究将mCherry基因构建到pBI121植物表达载体系统中,构建了pBI121MCS-mCherry载体。利用基因枪转化法转入洋葱表皮进行表达验证,显微镜观察结果显示整个洋葱细胞具有红色荧光,证明该载体能够在植物细胞中表达红色荧光蛋白。利用双酶切连接法将转录因子BpMYB4基因构建到该载体上,得到融合表达载体pBI121MCS-mCherry-BpMYB4,在洋葱表皮中表达,结果显示细胞核具有红色荧光,证明该载体能够准确表达融合蛋白,进行亚细胞定位。同时融合基因时不再需要中间载体,构建简便,引入的KpnⅠ酶切位点,增加了可选择性。因此该载体可用于植物基因表达定位及转基因植株筛选研究中,为今后的白桦基因组学研究提供了材料。     

A Rapid,Highly Efficient and Economical Method of Agrobacterium-Mediated In planta Transient Transformation in Living Onion Epidermis

Transient transformation is simpler, more efficient and economical in analyzing protein subcellular localization than stable transformation. Fluorescent fusion proteins were often used in transient transformation to follow the in vivo behavior of proteins. Onion epidermis, which has large, living and transparent cells in a monolayer, is suitable to visualize fluorescent fusion proteins. The often used transient transformation methods included particle bombardment, protoplast transfection and Agrobacterium-mediated transformation. Particle bombardment in onion epidermis was successfully established, however, it was expensive, biolistic equipment dependent and with low transformation efficiency. We developed a highly efficient in planta transient transformation method in onion epidermis by using a special agroinfiltration method, which could be fulfilled within 5 days from the pretreatment of onion bulb to the best time-point for analyzing gene expression. The transformation conditions were optimized to achieve 43.87% transformation efficiency in living onion epidermis. The developed method has advantages in cost, time-consuming, equipment dependency and transformation efficiency in contrast with those methods of particle bombardment in onion epidermal cells, protoplast transfection and Agrobacterium-mediated transient transformation in leaf epidermal cells of other plants. It will facilitate the analysis of protein subcellular localization on a large scale.     

Development of the Hypodermal Casparian Band in Corn and Onion Roots

A hypodermal Casparian band develops 40–50 mm from theroot tip in corn and 30–40 mm from the root tip in onion.In both plants, the endodermal Casparian band matures about20 mm closer to the root tip than the hypodermal Casparian band.Using the apoplastic fluorescent dye, Calcofluor white M2R (CFW),a permeability barrier could be distinguished in the radialwalls of the hypodermis 40–50 mm from the root tip incorn and onion. In progressively younger regions of the roots,CFW was first excluded from the outer tangential hypodermalwalls and the inner tangential epidermal walls, then the radialepidermal walls so that in very young regions only the outertangential epidermal walls were permeated. In contrast to CFW,the symplastic fluorescent dye, uranin, was translocated fromthe epidermis into the stele at all distances tested (5.0–50mm from the root tips). CFW and uranin at a concentration of0.01% proved nontoxic to corn and onion roots on the basis ofroot growth tests. Key words: Zea mays, Casparian band, Hypodermis, Allium cepa     

A rapid analytical technique for flow cytometric analysis of cell viability using calcofluor white M2R

Analysis of dead versus live cells is shown to be possible using Calcoflour White M2R (CFW), a fluorescent brightener. Comparison of CFW with both propidium iodide (PI) and fluorescein diacetate (FDA) was performed on a FACS 440 dual laser flow cytometer on several populations of cultured rat and mouse cell lines, peripheral leukocytes, splenocytes, diatoms, and plant protoplasts. As a measure of cell viability, staining results with CFW were strongly associated with PI (correlation coefficient of 0.9886) and FDA (inverse correlation coefficient of 0.9647). With plant and algal cells, controls are necessary as CFW does stain live cells to some extent. CFW (excitation: UV, emission max: 435 nm) can be used in conjunction with two-color immunofluorescence analysis using fluorochromes excited at 488 nm with no interference.     

Monoclonal antibodies against plant proteins recognise animal intermediate filaments

Four monoclonal antibodies were raised against polypeptides present in a high-salt detergent-insoluble fraction from cells of Chlamydomonas reinhardtii. Indirect immunofluorescence microscopy of fibroblasts and epithelial cells grown in culture using these plant antibodies revealed staining arrays identical to those obtained with well characterised antibodies to animal intermediate filaments. Immunofluorescence microscopy of Chlamydomonas with these monoclonal antibodies and a monoclonal antibody that recognises all animal intermediate filaments (anti-IFA) gave a diffuse, patchy cytoplasmic staining pattern. Both the plant antibodies and anti-IFA stained interphase onion root tip cells in a diffuse perinuclear pattern. In metaphase through to telophase, the labelling patterns colocalised with those of microtubules. Labelling of the phragmoplast was also detected but not staining of the preprophase band. On Western blots of various animal cell lines and tissues, all the antibodies labelled known intermediate filament proteins. On Western blots of whole Chlamydomonas proteins, all the antibodies labelled a broad band in the 57,000 Mr range, and three antibodies labelled bands around 66,000 and 140,000 Mr but with variable intensities. On Western blots of whole onion root tip proteins, all the antibodies labelled 50,000 Mr (two to three bands) polypeptides and a diffuse band around 60,000 Mr and three of the antibodies also labelled several polypeptides in the 90,000-200,000 Mr range. The consistent labelling of these different bands by several different monoclonal antibodies recognising animal intermediate filaments makes these polypeptides putative plant intermediate filament proteins.     

家蚕消化管内桑叶的银染法研究

通过银染法对家蚕整体染色,结果表明:家蚕消化管内的桑叶由叶表皮、叶肉和叶脉组成。叶表皮包括上表皮和下表皮。上表皮细胞可分为三种:钟乳体细胞、绿色表皮细胞和黄色表皮细胞;下表皮内含有气孔;叶肉组织内含有晶体,其中海绵组织内的最多。家蚕消化管由前向后可分为前肠、中肠和后肠,由外向内依次为肌层、底膜、上皮细胞层、内膜。中肠最为发达,其发达的上皮细胞向内表面突起形成许多大的指突形皱褶;上皮细胞层内有圆筒形细胞、杯形细胞两种细胞,两者在形状、功能以及嗜银性等方面有所差异。家蚕消化管对桑叶不同组织的消化吸收效率有差异,上表皮吸收效率最高,下表皮和栅栏组织次之,最低的是海绵组织。采用动物细胞染色方法对植物细胞进行染色,并与常规植物学染色方法进行了比较;依据细胞嗜银性的不同,可将桑叶的上表皮细胞分为两种亚型。     

Simultaneous visualization of peroxisomes and cytoskeletal elements reveals actin and not microtubule-based peroxisome motility in plants

Peroxisomes were visualized in living plant cells using a yellow fluorescent protein tagged with a peroxisomal targeting signal consisting of the SKL motif. Simultaneous visualization of peroxisomes and microfilaments/microtubules was accomplished in onion (Allium cepa) epidermal cells transiently expressing the yellow fluorescent protein-peroxi construct, a green fluorescent protein-mTalin construct that labels filamentous-actin filaments, and a green fluorescent protein-microtubule-binding domain construct that labels microtubules. The covisualization of peroxisomes and cytoskeletal elements revealed that, contrary to the reports from animal cells, peroxisomes in plants appear to associate with actin filaments and not microtubules. That peroxisome movement is actin based was shown by pharmacological studies. For this analysis we used onion epidermal cells and various cell types of Arabidopsis including trichomes, root hairs, and root cortex cells exhibiting different modes of growth. In transient onion epidermis assay and in transgenic Arabidopsis plants, an interference with the actin cytoskeleton resulted in progressive loss of saltatory movement followed by the aggregation and a complete cessation of peroxisome motility within 30 min of drug application. Microtubule depolymerization or stabilization had no effect.     

Mobile and immobile endoplasmic reticulum in onion bulb epidermis cells: short- and long-term observations with a confocal laser scanning microscope

The endoplasmic reticulum (ER) of onion bulb scale epidermis cells consists of long, tubular strands lying deep in the cytoplasm which move quickly and a less mobile peripheral network of tubules and cisternae that change in position, shape and size but that also have immobile, fixed, sites (IFSs). IFSs occur in junctions, at vertexes and at blind endings of tubules as well as at the edges and the surface of cisternae. They are regularly arranged in helicoidal rows and may be knot- or ring-like in structure. They become enlarged by treatment with oryzalin but not with colchicine. They persist for long times (for more than 30 min); together with pulling forces, the surface tension and other factors, they determine the configuration and motion of the peripheral network. New polygons of the network are mainly formed by the development of new tubules that become joined with other parts of the network. Polygons disappear by contraction and fusion of tubules. The inner, rapidly moving ER tubules remain connected with the peripheral network over longer distances by sliding junctions. Cytochalasin D causes an accumulation of the ER into patches, a fusion of tubules into cisternae and changes in shape, which indicate the loss of pulling forces. In contrast to animal cells (but like the movement of the inner tubular strands), the latter is dependent upon the actomyosin system; microtubules are not involved. Despite the differences in the organizing components, the peripheral ER in onion bulb scale epidermis cells and that of the borders of cultured animal cells are similar in morphology and motility.     

Immobilization of microbial cells on inner epidermis of onion bulb scale for biosensor application

Inner epidermis of onion bulb scales was used as a natural support for immobilization of microbial cells for biosensor application. A bacterium Sphingomonas sp. that hydrolyzes methyl parathion into a chromophoric product, p-nitrophenol (PNP), has been isolated and identified in our laboratory. PNP can be detected by electrochemical and colorimetric methods. Whole cells of Sphingomonas sp. were immobilized on inner epidermis of onion bulb scale by adsorption followed by cross-linking methods. Cells immobilized onion membrane was directly placed in the wells of microplate and associated with the optical transducer. Methyl parathion is an organophosphorus pesticide that has been widely used in the field of agriculture for insect pest control. This pesticide causes environmental pollution and ecological problem. A detection range 4-80 μM of methyl parathion was estimated from the linear range of calibration plot of enzymatic assay. A single membrane was reused for 52 reactions and was found to be stable for 32 days with 90% of its initial hydrolytic activity. The applicability of the cells immobilized onion membrane was also demonstrated with spiked samples.     

Caged probes: a novel tool in studying symplasmic transport in plant tissues

Summary. Caged probes offer a novel approach to study plant cell-to-cell communication. Instead of introducing fluorescent molecules into cells by microinjection, their caged counterparts can be preloaded into the tissue by diffusion. Following spatially controlled photoactivation, movement of the uncaged fluorochrome can be followed in time and direction by confocal laser scanning microscopy. In the onion bulb scale epidermis used as a model system, symplasmic transport of the tracer out of a target cell was followed. Transport via the symplasmic pathway was challenged by plasmolysing the tissue. The experiments confirmed the symplasmic nature of tracer transport.Correspondence and reprints: Department of Plant Biology, Royal Veterinary and Agricultural University, Thorvaldsensvej 40, 1871 Frederiksberg C. Denmark. E-mail: hjm@kvl.dk     

Glycosyltransferases in plant and animal tissues effects of fixation and lead on enzyme activity.

As the initial step toward the cytochemical localization of glycosyl-transferases in situ, biochemical determinations of these enzyme activities from onion root tips and L1210 cells were performed before and after fixation as well as in the presence of lead ions. Glycosyltransferase activity from roots fixed in buffered formaldehyde or glutaraldehyde before homogenization decreased as the concentration of the fixative or fixation time was increased. Formaldehyde fixation was less inhibitory than glutaraldehyde; 35% of the glycosyltransferase activity was retained after 30 min fixation in 2% formaldehyde while 25% of the enzyme activity remained after a similar fixation in glutaraldehyde. Substantially higher levels of L1210 cell glycosyltransferase activity were retained after a 30 min 2% formaldehyde fixation (60% sialyltransferase; 82% galactosyltransferase), but inhibition by glutaraldehyde was similar to that observed for onion root galactosyltransferase. Glycosyltransferase from formaldehyde-fixed roots was inhbited 35% by lead nitrate, but sialytransferase from formaldehyde-fixed L1210 cells was unaffected by lead ions. These findings are encouraging for further studies aimed at the development of cytochemical technique to localize glycosyltransferase in plant and animal tissues.     

A plasmolytic cycle: The fate of cytoskeletal elements

Summary In most plant cells, transfer to hypertonic solutions causes osmotic loss of water from the vacuole and detachment of the living protoplast from the cell wall (plasmolysis). This process is reversible and after removal of the plasmolytic solution, protoplasts can re-expand to their original size (deplasmolysis). We have investigated this phenomenon with special reference to cytoskeletal elements in onion inner epidermal cells. The main processes of plasmolysis seem to be membrane dependent because destabilization of cytoskeletal elements had only minor effects on plasmolysis speed and form. In most cells, the array of cortical microtubules is similar to that found in nonplasmolyzed states except that longitudinal patterns seen in some control cells were never observed in plasmolyzed protoplasts of onion inner epidermis. As soon as deplasmolysis starts, cortical microtubules become disrupted and only slowly regenerate to form an oblique array, similar to most nontreated cells. Actin microfilaments responded rapidly to the plasmolysis-induced deformation of the protoplast and adapted to its new form without marked changes in organization and structure. Both actin microfilaments and microtubules can be present in Hechtian strands, which, in plasmolyzed cells, connect the cell wall to the protoplast. Anticytoskeletal drugs did not affect the formation of Hechtian strands.Abbreviations DIC differential interference contrast - DiOC₆(3) 3,3-dihexyloxacarbocyanine iodide Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

洋葱鳞茎表皮Actin细胞骨架的Rh—Ph荧光和光学显微镜观察

洋葱鳞茎内表皮细胞经Triton X-100处理和多聚甲醛固定之后用Rh-Ph(Rhodamine-Phalloidin)染色,细胞质内可见较丰富的、直径为100—300nm的F-actin束。较粗的F-actin束沿细胞的长轴平行排列,并纵裂成较细的“分枝”,纵裂成的分枝又纵裂成更细的“分枝”。各种大小的F-actin束相互交织在一起构成一个三维的纤丝网络,并且与细胞膜、细胞核和其它细胞器相连。经同样方法处理和固定的细胞用考马斯亮兰R_(250)(Coomassie brilliant blue R_(250))染色之后,细胞质内可见直径为200—300nm的纤丝,形态特征和排列方式和上述在荧光显微镜下看到的F-actin束相同。本研究结果表明洋葱鳞茎内表皮的细胞骨架包含较丰富的F-actin系统;Pena的考马斯亮兰染色法(1980)所显示的结构主要代表F-actin束。     

Some new observations and interpretations on the vital staining of leaf epidermal tissue by neutral red

Summary The lower leaf epidermis from 5 plant species was stained with neutral red at 2 pH's (7.1 and 5.6) in the light and dark when the stomata were open or closed. At pH 5.6 no globule (= droplet) formation was observed in the guard cells whether the stomata were open or closed and cell walls possessed a high affinity for the stain. At pH 7.1 globules appeared in guard cells of open stomata, but not closed stomata, within 15 minutes. Anaerobic conditions prevented this globule formation. InZea mays, globules also appeared in subsidiary cells when the stomata were closed and in certain epidermal cells. Where globule formation did not occur increased diffuse staining of certain epidermal cells was considered to be the indication of cell integrity. In old leaf material very large numbers of dark blue globules appeared in epidermal cells ofCommelina diffusa, C. communis andSenecio odoris and this was associated with cell senescence.The staining characteristics were discussed in terms of cellular K⁺, Cl^–, tannin and flavonoid content and vacuolar pH.     

Effects of Phosfon-D and of low temperature on the morphology of cell protoplasts

Summary The adventitious roots of onion (Allium cepa L.) or onion bulb scales were treated either with growth retardant Phosfon-D (2,4-dichlorobenzyltributylphosfonium chloride), or with low temperature (5° C). Low temperature, likewise Phosfon-D treatment, resulted in the appearance of membranous structures within the cytoplasm of the root cells fixed in chromaceto-formalin (CrAF) and in the occurrence of minute vacuoles in the living onion bulb scale cells. The cytochemical analysis revealed the membrane-like elements to contain basic and acid proteins as well as nucleic acids.It seems that the observed effect of Phosfon-D and that of low temperature were due to the local accumulation of protein resulting in changes of the physical properties of the cytoplasm. The fact that membranous structures do contain nucleic acid may suggest their important, metabolic role especially in the process of cold acclimation of plant tissue.This work was partly supported by Grant No. FG-PO-225 from U.S. Department of Agriculture, Agricultural Research Program, Public Law 480.     

Eosinophilic granule cells in Carassius auratus scale epidermis

Eosinophilic granule cells (EGCs) were characterized in Carassius auratus scale epidermis in situ and in explants. Live EGCs were readily identified by the presence of numerous large cytoplasmic granules observed with DIC microscopy. Histochemical staining with toluidine blue and alcian blue yielded granule metachromasia and pale blue granules, respectively, both consistent with mammalian mast cell staining. However, EGCs also share some features with mammalian basophils as neutral red dye was selectively incorporated into EGC granules. EGCs within scale epidermis were actively motile, displaying average speeds of 16 μm/min and maximum speeds of greater than 40 μm/min and showing morphological plasticity during migration. The predominant motile phenotype was elongate with a well‐developed leading lamella, while a broader body motile morphology was observed to a lesser extent. A trailing, relatively unchanged uropod was associated with every motile EGC and invariably contained one or a few granules. A rounded EGC shape without a leading‐edge or trailing uropod was also observed and was generally associated with static cells. Individual cells readily switched between the three major shapes during motility; static cells could abruptly develop a polarized morphology, and actively motile cells switched between elongate and broad‐bodied shapes or the static, rounded shape.     

Evaluation of Dermal Substitute in a Novel Co-Transplantation Model with Autologous Epidermal Sheet

The development of more and more new dermal substitutes requires a reliable and effective animal model to evaluate their safety and efficacy. In this study we constructed a novel animal model using co-transplantation of autologous epidermal sheets with dermal substitutes to repair full-thickness skin defects. Autologous epidermal sheets were obtained by digesting the basement membrane (BM) and dermal components from rat split-thickness skins in Dispase II solution (1.2 u/ml) at 4°C for 8, 10 and 12 h. H&E, immunohistochemical and live/dead staining showed that the epidermal sheet preserved an intact epidermis without any BM or dermal components, and a high percentage of viable cells (92.10±4.19%) and P63 positive cells (67.43±4.21%) under an optimized condition. Porcine acellular dermal matrixes were co-transplanted with the autologous epidermal sheets to repair full-thickness skin defects in Sprague-Dawley rats. The epidermal sheets survived and completely re-covered the wounds within 3 weeks. Histological staining showed that the newly formed stratified epidermis attached directly onto the dermal matrix. Inflammatory cell infiltration and vascularization of the dermal matrix were not significantly different from those in the subcutaneous implantation model. Collagen IV and laminin distributed continuously at the epidermis and dermal matrix junction 4 weeks after transplantation. Transmission electron microscopy further confirmed the presence of continuous lamina densa and hemidesmosome structures. This novel animal model can be used not only to observe the biocompatibility of dermal substitutes, but also to evaluate their effects on new epidermis and BM formation. Therefore, it is a simple and reliable model for evaluating the safety and efficacy of dermal substitutes.