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.     

Differential localisation of GFP fusions to cytoskeleton-binding proteins in animal, plant, and yeast cells

Summary.  The structure and functioning of the cytoskeleton is controlled and regulated by cytoskeleton-associated proteins. Fused to the green-fluorescent protein (GFP), these proteins can be used as tools to monitor changes in the organisation of the cytoskeleton in living cells and tissues in different organisms. Since the localisation of a specific cytoskeleton protein may indicate a particular function for the associated cytoskeletal element, studies of cytoskeleton-binding proteins fused to GFP may provide insight into the organisation and functioning of the cytoskeleton. In this article, we focused on two animal proteins, human T-plastin and bovine tau, and studied the distribution of their respective GFP fusions in animal COS cells, plant epidermal cells (Allium cepa), and yeast cells (Saccharomyces cerevisiae). Plastin-GFP localised preferentially to membrane ruffles, lamellipodia and focal adhesion points in COS cells, to the actin filament cytoskeleton within cytoplasmic strands in onion epidermal cells, and to cortical actin patches in yeast cells. Thus, in these 3 very different types of cells plastin-GFP associated with mobile structures in which there are high rates of actin turnover. Chemical fixation was found to drastically alter the distribution of plastin-GFP. Tau-GFP bound to microtubules in COS cells and onion epidermal cells but failed to bind to yeast microtubules. Thus, animal and plant microtubules appear to have a common tau binding site which is absent in yeast. We conclude that the study of the distribution patterns of microtubule- and actin-filament-binding proteins fused to GFP in heterologous systems should be a valuable tool in furthering our knowledge about cytoskeleton function in eukaryotic cells. Received January 12, 2002; accepted March 7, 2002; published online June 24, 2002 RID="*" ID="*" Correspondence and reprints (present address): Institute of Botany, University of Bonn, Kirschallee 1, 53115 Bonn, Federal Republic of Germany. Abbreviation: smRS-GFP soluble modified red-shifted GFP.     

GFP associates with microfilaments in fixed cells

The discovery of the green fluorescent protein (GFP) and its use as a marker for proteins in cells revolutionised cell biology. Among its applications are the intracellular localisation of proteins and the investigation of the organisation, regulation and dynamics of the cytoskeleton. GFP itself is considered to be an inert protein, homogeneously distributed within the cytoplasm. Here we investigated the intracellular distribution of GFP in an amphibian and in various mammalian cell lines (XTH2, CHO-K1, HaCaT, MDCK, NIH-3T3) by confocal laser scanning microscopy. After paraformaldehyde fixation GFP became associated with microfilaments in all the cell lines investigated. This interaction was not impaired by detergent treatment (1% Brij 58 for 10 min). In contrast to the F-actin binding of GFP in fixed cells, association of GFP with stress fibres was not detectable in living cells. The actin-binding property of GFP might contribute also to the interaction of fusion proteins with microfilaments. Thus, careful controls are unavoidable in investigating (weak) actin-binding proteins in fixed cells. Because no association of GFP with microfilaments was detectable in living cells, it is recommended to monitor the intracellular distribution of GFP-tagged proteins in vivo.     

RNA干扰技术抑制内源性绿色荧光蛋白的表达

目的建立稳定表达绿色荧光蛋白(GFP)的细胞株;构建短发夹RNA(shRNA)表达质粒并观察其对内源性GFP的抑制作用。方法转染pEGFP-N1至HepG2细胞,利用G418筛选获得稳定表达GFP的细胞株(HepG2.GFP);设计合成针对GFP基因的siRNA对应的DNA片段,插入转录载体pTZU6 1,构建shRNA表达载体pSHGFP,转染HepG2.GFP,荧光显微镜观察细胞荧光强度,以western blot检测GFP蛋白水平,以RT-PCR检测mRNA水平。结果利用PCR方法从HepG2.GFP细胞基因组DNA中检测到GFP基因;pSHGFP能够显著抑制该细胞中GFP的表达。结论GFP基因成功整合至HepG2细胞基因组中,pSHGFP能够显著抑制内源性GFP的表达,该系统能够用于RNA干扰机制等研究中。     

Improved silencing vector co-expressing GFP and small hairpin RNA

Small interfering RNA (siRNA) is a powerful tool for the specific silencing of gene expression. We developed an improved vector, pG-SUPER, that co-expresses green fluorescent protein (GFP) and small hairpin RNA simultaneously to facilitate analysis of silencing at the level of individual cells. As a test system, we analyzed lamin A/C knockdown in HeLa cells. The GFP signal was a reliable reporter (93%-98%) of strong knockdown (approximately 90%) over a wide range of GFP intensities. The GFP reporter made possible the application of fluorescent-activated cell sorting (FACS) to purify the knockdown cell population. Such populations facilitated Western blotting analysis to determine depletion of the target protein. pG-SUPER was also applied to evaluate gene replacement by exogenous genes rendered refractory to siRNA by introducing silent mutations. Recovery of lamin A was linearly correlated to the expression level of the rescue gene. pG-SUPER will expand plasmid-based siRNA applications through the easy and reliable detection of knockdown and rescued cells.     

Suppression of gene expression by RNA interference in cultured plant cells

Suppression by double-stranded RNA (dsRNA) of the expression of a target gene is known as RNA interference (RNAi). No quantitative analysis of the effects of RNAi on the expression of specific genes in cultured plant cells has been reported. However, as it is possible to produce populations of cultured plant cells that are uniform and divide synchronously for functional analysis of genes of interest, we performed a quantitative study of the effects of RNAi in such cells. We constructed dsRNA expression plasmids for a luciferase gene under the control of the cauliflower mosaic virus (CaMV) 35S promoter by simply connecting sense and antisense sequences in a head-to-head manner. An RNAi effect was observed 24 hours after the introduction of dsRNA expression plasmids into tobacco BY-2 cells by electroporation. The simple system for suppression of specific genes in plant cells should be useful in attempts to elucidate the roles of individual genes in plant cells.     

Mitochondria-targeted GFP highlights the heterogeneity of mitochondrial shape, size and movement within living plant cells

Little is known concerning the heterogeneity of mitochondrial shape, size, number, cytoplasmic distribution, and motility in planta. Ultrastructural studies using the electron microscope have shown a variety of mitochondrial shapes and sizes within fixed cells, however, it is not possible to dismiss the possibility that any heterogeneity observed resulted from preparation or fixation artefacts. Unambiguous demonstration of the extent and nature of mitochondrial heterogeneity in vivo necessitates the use of a truly in vivo mitochondrial detection system. Green fluorescent protein is an excellent in vivo marker for gene expression and protein localization studies. It is particularly useful for real-time spatiotemporal analysis of intracellular protein targeting and dynamics and as such is an ideal marker for analysing mitochondria in planta. Stably transformed Arabidopsis lines have been generated with GFP targeted to the mitochondria using either of two plant mitochondrial signal sequences from the beta-ATPase subunit or the mitochondrial chaperonin CPN-60. Mitochondrially targeted GFP, which is easily detectable using an epifluorescent or confocal microscope, highlights heterogeneity of mitochondrial shape, size, position, and dynamic within living plant cells.     

Membrane trafficking in higher plant cells: GFP and antibodies, partners for probing the secretory pathway.

Eukaryotic cells are characterised by the organised distribution of membrane bounded compartments in their cytoplasm. The endoplasmic reticulum (ER) and the Golgi apparatus (GA) are part of this endomembrane machinery. They are involved in protein flow, and are in charge of specific functions such as the assembly, sorting and transport of newly synthesised proteins, glycoproteins or polysaccharides to their final destination, where the macromolecules are recognised either for action, storage, deposition or degradation. The structural and functional relationship between the ER and GA in higher plants is still a matter of debate. Therefore, it was essential to develop probes that would specifically label proteins or glycoproteins of the endomembrane system in situ. Here we compare two complementary approaches to probe plant endomembranes; immunocytochemistry on fixed cells, and in vivo studies using the expression of GFP tagged chimeric proteins. The structural relationship between ER and GA as based on pharmacological approaches using the two systems is explored.     

Instrumentation and methodology for quantifying GFP fluorescence in intact plant organs

The General Fluorescence Plant Meter (GFP-Meter) is a portable spectrofluorometer that utilizes a fiber-optic cable and a leaf clip to gather spectrofluorescence data. In contrast to traditional analytical systems, this instrument allows for the rapid detection and fluorescence measurement of proteins under field conditions with no damage to plant tissue. Here we discuss the methodology of gathering and standardizing spectrofluorescence data from tobacco and canola plants expressing GFP. Furthermore, we demonstrate the accuracy and effectiveness of the GFP-Meter. We first compared GFP fluorescence measurements taken by the GFP-Meter to those taken by a standard laboratory-based spectrofluorometer, the FluoroMax-2. Spectrofluorescence measurements were taken from the same location on intact leaves. When these measurements were tested by simple linear regression analysis, we found that there was a positive functional relationship between instruments. Finally, to exhibit that the GFP-Meter recorded accurate measurements over a span of time, we completed a time-course analysis of GFP fluorescence measurements. We found that only initial measurements were accurate; however, subsequent measurements could be used for qualitative purposes.     

RNA editing in plant mitochondria

RNA editing in plant mitochondria alters nearly all mRNAs by C to U and U to C transitions. In some species more than 400 edited sites have been identified with significant effects on the encoded proteins. RNA editing occurs in higher and lower plants and presumably has evolved before the differentiation of land plants. Current research focuses on the elucidation of the biochemistry and the specificity determinants of RNA editing in plant mitochrondria.     

Cap structure of U3 small nucleolar RNA in animal and plant cells is different. gamma-Monomethyl phosphate cap structure in plant RNA.

U3 small nucleolar RNA (snoRNA) is an abundant small RNA involved in the processing of pre-ribosomal RNA of eukaryotic cells. U3 snoRNA has been previously characterized from several sources, including human, rat, mouse, frog, fruit fly, dinoflagellates, slime mold, and yeast; in all these organisms, U3 snoRNA contains trimethylguanosine cap structure. In all instances where investigated, the trimethylguanosine-capped snRNAs including U3 snoRNA, are synthesized by RNA polymerase II. However, in higher plants, the U3 snoRNA is synthesized by RNA polymerase III and contains a cap structure different from trimethylguanosine (Kiss, T., and Solymosy, F. (1990) Nucleic Acids Res. 18, 1941-1949; Marshallsay, C., Kiss, T., and Filipowicz, W. (1990) Nucleic Acids Res. 18, 3451-3458; Kiss, T., Marshallsay, C., and Filipowicz, W. (1991) Cell 65, 517-526). In this study, we present evidence that cowpea and, most likely, tomato plant U3 snoRNA contains a methyl-pppA cap structure. These data show that the same U3 snoRNA contains different cap structures in different species and suggest that the kind of cap structure that an uridylic acid-rich small nuclear RNA contains is dependent on the RNA polymerase responsible for its synthesis. In vitro synthesized plant U3 snoRNA, with pppA or pppG as its 5' end, was converted to methyl-pppA/G cap structure in vitro when incubated with extracts prepared from wheat germ or HeLa cells. These data show that the capping machinery is conserved in organisms as evolutionarily distant as plants and mammals. Nucleotides 1-45 of tomato U3 snoRNA, which are capable of forming a stem-loop structure, are sufficient to direct the methyl cap formation in vitro.     

Differential localisation of GFP fusions to cytoskeleton-binding proteins in animal,plant, and yeast cells. Green-fluorescent protein

The structure and functioning of the cytoskeleton is controlled and regulated by cytoskeleton-associated proteins. Fused to the green-fluorescent protein (GFP), these proteins can be used as tools to monitor changes in the organisation of the cytoskeleton in living cells and tissues in different organisms. Since the localisation of a specific cytoskeleton protein may indicate a particular function for the associated cytoskeletal element, studies of cytoskeleton-binding proteins fused to GFP may provide insight into the organisation and functioning of the cytoskeleton. In this article, we focused on two animal proteins, human T-plastin and bovine tau, and studied the distribution of their respective GFP fusions in animal COS cells, plant epidermal cells (Allium cepa), and yeast cells (Saccharomyces cerevisiae). Plastin-GFP localised preferentially to membrane ruffles, lamellipodia and focal adhesion points in COS cells, to the actin filament cytoskeleton within cytoplasmic strands in onion epidermal cells, and to cortical actin patches in yeast cells. Thus, in these 3 very different types of cells plastin-GFP associated with mobile structures in which there are high rates of actin turnover. Chemical fixation was found to drastically alter the distribution of plastin-GFP. Tau-GFP bound to microtubules in COS cells and onion epidermal cells but failed to bind to yeast microtubules. Thus, animal and plant microtubules appear to have a common tau binding site which is absent in yeast. We conclude that the study of the distribution patterns of microtubule- and actin-filament-binding proteins fused to GFP in heterologous systems should be a valuable tool in furthering our knowledge about cytoskeleton function in eukaryotic cells.     

Purification of GFP fusion proteins from transgenic plant cell cultures

Green fluorescence protein (GFP) has become a widely used reporter in many areas of life science. Monitoring foreign protein expression via GFP fusion is also very appealing for bioprocess applications. GFP itself has been purified from recombinant organisms by several methods, often involving unfavorable conditions (e.g., use of organic solvents and/or low pH) that may be destabilizing to some proteins. In this study, we have developed a general recovery scheme that entails a simple three-step purification procedure for GFP fusion proteins produced in tobacco suspension cells, with the intent of maximizing purity and yield under gentle conditions so as to maintain the integrity of the fusion partner. Ammonium sulfate treatment at 30% (v/v) precipitated particulate matter and removed aggregated material while simultaneously maintaining GFP solubility and increasing hydrophobicity. Hydrophobic interaction chromatography was then performed to eliminate the majority of background proteins while eluting GFP and fusions in a low ionic buffer suitable to be directly applied to an ion-exchange column as the final step. Three intracellular proteins, secreted alkaline phosphatase (SEAP), and granulocyte-macrophage colony-stimulating factor (GMCSF), each fused to GFP, as well as GFP itself, were recovered with yields exceeding 70% and purity levels over 80%. This purification scheme exploits the hydrophobic nature of GFP while maintaining a gentle environment for labile fusion partners. Although some optimization may be required, we believe this scheme may serve as a benchmark for purifying other GFP fusion proteins.