Heather L. Brownell

Gap junctional communication in cultured human lung carcinoma cells.

Animal tumor models have demonstrated a close correlation between gap junctional, intercellular communication (GJIC) and tumor metastasis. To examine GJIC levels in human lung carcinoma cells, a novel technique was developed: cells were grown on a glass slide, half of which was coated with electrically conductive, optically transparent, indium-tin oxide. An electric pulse which opens transient pores on the plasma membrane was applied in the presence of the fluorescent dye, Lucifer yellow, causing the dyes penetration into the cells growing on the conductive part of the slide. The migration of the dye through gap junctions to the non-electroporated cells growing on the non-conductive area was then observed microscopically under fluorescence illumination. The results show that this is a rapid, precise and highly reproducible assay for GJIC assessment in lines established from lung carcinomas or freshly explanted lung tumor cells. Out of 17 established lines only two had extensive junctional communication, while out of 16 fresh tumor specimens none displayed GJIC. On the other hand, fibroblasts isolated from the same tumors had extensive junctional permeability. The examination of GJIC in a large number of samples could establish a correlation between GJIC and metastasis which might have prognostic value.

Cellular Ras partly mediates gap junction closure by the polyoma virus middle tumor antigen

Endogenous, cellular Ras proteins (c-Ras) mediate the transforming action of the polyoma virus middle Tumor antigen (mT), which is accompanied by elimination of gap junctional, intercellular communication (GJIC). In this report we show that reducing the c-Ras content of murine C3H10T1/2 fibroblasts (10T1/2) through the expression of an anti-sense ras gene, increased GJIC by 60-80% mT totally eliminated GJIC in normal 10T1/2 cells but it reduced GJIC no more than 50% in the c-Ras deficient lines. These results indicate that endogenous c-Ras is at least partly responsible for the mT-induced gap junction closure.

Applications of electroporation of adherent cells in situ, on a partly conductive slide

Nontraumatic, simple, and reproducible procedures for the introduction of nonpermeant molecules into adherent mammalian cells byin situ electroporation are described. Ctells are grown on a glass slide, half of which is coated with electrically conductive, optically transparent, indium-tin oxide. An electric pulse is applied in the presence of the molecules to be introduced, and their effect on the cellular phenotype can be observed. The cells growing on the nonconductive side of the slide do not receive any pulse and serve as controls. Careful adjustment of electric field strength can achieve the introduction of the molecules into essentially 100% of the cells, and this treatment causes no detectable disruption to cellular metabolism. This is applied in the presence of the fluorescent dye, Lucifer yellow, causing its penetration into the cells growing on the conductive half of the slide. The migration of the dye to the nonelectroporated cells growing on the nonconductive area is microscopically observed under fluorescence illumination.

Electroporation of Adherent Cells In Situ for the Study of Signal Transduction and Gap Junctional Communication

Cultured adherent cells can be electroporated in situ, as they grow on a glass slide coated with electrically conductive, optically transparent indium-tin oxide (ITO). Although the introduction of DNA is a common use, the technique of electroporation in situ is valuable for studying many aspects of signal transduction. This is because, under the appropriate conditions, in situ electroporation can be remarkably nontraumatic, while a large variety of molecules, such as peptides, oligonucleotides, or drugs, are introduced instantly and into essentially 100% of the cells, making this technique especially suitable for kinetic studies of effector activation. Following the introduction of the material, the cells can be either extracted or biochemically analyzed, or their morphology and gene expression can be examined by immunocytochemistry. In this chapter, we describe the introduction of a peptide blocking the Src-homology 2 domain of the adaptor Grb2 to inhibit the activation of the downstream effector Erk1/2 by EGF. The setup includes nonelectroporated, control cells growing side by side with the electroporated ones on the same type of ITO-coated surface. In a modified version, this assembly can be used very effectively for studying intercellular, junctional communication: cells are grown on a glass slide half of which is ITO-coated. An electric pulse is applied in the presence of the fluorescent dye lucifer yellow, causing its penetration into the cells growing on the conductive part of the slide, and the migration of the dye to the nonelectroporated cells growing on the nonconductive area is microscopically observed under fluorescence illumination.

Dissecting Pathways; in Situ Electroporation for the Study of Signal Transduction and Gap Junctional Communication

Publisher Summary This article describes a technique where cells are grown on a glass surface coated with electrically conductive, optically transparent indium-tin oxide (ITO) at the time of pulse delivery. This coating promotes excellent cell adhesion and growth, allows direct visualization of the electroporated cells, and offers the possibility of ready examination due to their extended morphology. The instant introduction of the molecules into essentially 100% of the cells makes this technique especially suitable for kinetic studies of effector activation. Unlike other techniques of cell permeabilization, under the appropriate conditions, in situ electroporation does not affect cell morphology, the length of the G1 phase of serum-stimulated cells. The technique of in situ electroporation can be used equally effectively for large-scale biochemical experiments. Growth factors such as the epidermal growth factor (EGF) stimulate cell proliferation by binding to, and activating, membrane receptors with cytoplasmic tyrosine kinase domains. Assessment of Erk activity by Western blotting following electroporation of the Grb2-SH2 blocking peptide can reveal the involvement of this domain in growth factor-mediated Erk activation.

In situ electroporation of radioactive compounds into adherent cells

We previously developed a technique, termed in situ electroporation, where nonpermeant molecules are introduced through an electrical pulse into adherent cells, while they grow on electrically conductive, optically transparent, indium-tin oxide (ITO). Careful control of the electric field intensity results in essentially 100% of the cells taking up the introduced material, without any detectable effect upon the physiology of the cell, presumably because the pores reseal rapidly so that the cellular interior is restored to its original state. Electroporation of radioactive material is faced with two important considerations: (1) potential for exposure of personnel to irradiation, and (2) the requirement for electroporation of a large number of cells. In this report, we describe a modification in the geometry of the slides and electrodes which permits the use of inexpensive ITO-coated glass of lower conductivity that can be discarded after use, to electroporate large numbers of cells using a minimum volume of radioactive nucleotide solution. The results demonstrate that, using this assembly, the determination of the Ras-bound GTP/GTP+GDP ratios through electroporation of [alpha32P]GTP can be conducted using approximately five times lower amounts of isotope than in previous designs. Moreover, this assembly permits efficient upscaling, which makes the determination of Ras-GTP binding in cells which are deficient in Ras activity possible. In addition, we demonstrate the labeling of two viral phosphoproteins--the Simian Virus 40 Large Tumor antigen, and Adenovirus E1A--through [gamma32P]ATP electroporation using this setup. In both cases, electroporation of the nucleotide can achieve a great increase in the efficiency and specificity of labeling compared to the addition of [32P]-orthophosphate to the culture medium, presumably because the immediate phosphate donor nucleotide itself is introduced, which can directly bind to the target proteins.

The timing of insulin/c-Ras signal is critical for its effect upon the differentiation of C3H10T1/2-derived preadipocytes

The effect of the peptide hormone insulin upon the differentiation of a 10T1/2-derived preadipocytic line was found to display a potent time-dependence. Insulin addition before cell confluence strongly enhanced differentiation, while addition after confluence had no effect. In keeping with the role of c-Ras as a downstream effector of insulin, c-ras downregulation before confluence abolished differentiation, while it was ineffective once the process of differentiation was underway. These data suggest that the insulin signal is effective during an early window of time before cell confluence, while normal c-Ras levels are required for its transmission.

In Situ Electroporation of Radioactive Nucleotides: Assessment of Ras Activity or 32P Labeling of Cellular Proteins

Publisher Summary This chapter focuses on in situ electroporation of radioactive nucleotides to examine ras activity or 32p labeling of cellular proteins. Unlike other techniques of cell membrane permeabilization, such as streptolysin-O (SLO) treatment, in situ electroporation does not detectably affect cellular metabolism, presumably because the pores reseal rapidly so that the cellular interior is restored to its original state. Cells are grown on conductive and transparent glass slides, which are placed in a petri dish to maintain sterility. The cell growth area is defined by a “window” formed with an electrically insulating frame made of Teflon. The frame creates a gap between the conductive coating and the negative electrode so that current can only flow through the electroporation fluid and cells growing in the window. A large number of signal transducers are present in small amounts in the cell so that a large number of cells may be required to obtain a strong signal.