Metabolism of semisynthetic single-chain GM1 derivatives in cerebellar granule cells in culture

Semisynthetic single-chain GM1 derivatives containing N-acetyl-sphingosine (LIGA4) or N-dichloroacetyl-sphingosine (LIGA20) were recently reported to exert strong protection against glutamate-induced neuronal death in primary cultures of cerebellar granule cells. Elucidation of the molecular mechanism underlying the evoked effect requires knowledge of the metabolic fate of such molecules in the same cultured cells. For this, LIGA4 and LIGA20 were made radioactive on the long chain base moiety and added to cerebellar granule cells in culture in parallel with GM1 ganglioside. The metabolic fate was then investigated. It was found that both these molecules were easily taken up by the cells and promptly metabolized in a fashion qualitatively similar to that of control GM1. The highest amount processed was attributed to the different aggregation properties of LIGAs in solution. Among metabolites, higher accumulation of the single-chain ceramide residues was found after LIGA administration. Interestingly, sphingomyelin was generated, regardless the added compound, suggesting a recycling of the free long chain base.     

Induction of tumor cell resistance to macrophage-mediated lysis by preexposure to non-activated macrophages

Thioglycollate-elicited peritoneal exudate (non-activated) macrophages do not lyse tumor cells and in contrast to activated macrophages bind less target cells. However, a non-lethal encounter of tumor cells with non-activated macrophages resulted in a pronounced effect on the subsequent tumor cell binding to and lysis by activated macrophages. Our results have shown that binding of tumor cells by non-activated macrophages was Ca2+ and temperature dependent; had a requirement for a Pronase-sensitive structure on macrophage surface membranes; was saturable; and was 2-3X less than that observed for activated macrophages. Experiments were conducted in which syngeneic tumor cells were incubated with a monolayer of non-activated macrophages and then assayed for selective binding and sensitivity to lysis. The important observations were that as a result of a 3-hr incubation with non-activated macrophages at an EC: TC ratio of 5:1 there was an increase in the number of tumor cells that bound to both activated and non-activated macrophages; a loss of selective binding in which the ratio of tumor cells bound to activated/non-activated macrophages (normally greater than 2) was lowered to 1.0; and a concomitant decrease in the susceptibility of tumor cells to macrophage-mediated cytolysis. The induction of tumor cell resistance to macrophage kill required an exposure to an excess number of non-activated macrophages, was reversible upon culturing with or without macrophages for 24 hr and required cell-cell contact. Our results reinforce the importance of selective binding between tumor cells and activated macrophages as an initial phase in tumor cell killing and also illustrates an active role for non-activated macrophages in vivo in allowing tumor cells to escape the immune surveillance by activated macrophages.     

Morphological transformation, autonomous proliferation and colony formation by chicken heart mesenchymal cells infected with avian sarcoma, erythroblastosis and myelocytomatosis viruses

Normal chicken heart mesenchymal cells at low density in monolayer culture in plasma-containing medium have a polygonal shape and are proliferatively quiescent. The combination of epidermal growth factor and insulin at hyperphysiological concentration, an insulin-like growth factor surrogate, causes these cells to assume a fusiform shape and to increase 40-fold in number during four days of incubation. These mitogenic hormones do not, however, induce normal chicken heart mesenchymal cells to form colonies in agarose suspension culture. Chicken heart mesenchymal cells infected with the Schmidt-Ruppin or Prague-A strains of Rous sarcoma virus or with the Fujinami or Y73 avian sarcoma viruses assume spindle and round shapes, increase 50-100 fold in number during four days of monolayer culture in the absence of mitogenic hormones and form macroscopic colonies during 3-4 days of agarose suspension culture. The autonomous (mitogenic hormone-independent) proliferation, in monolayer culture, of cells infected with temperature-sensitive transformation mutants of Rous sarcoma virus (tsNY68, tsNY72, tsLA24, tsLA29) is temperature-sensitive. Chicken heart mesenchymal cells infected with avian erythroblastosis virus assume spindle shapes and proliferate in monolayer culture at a rate comparable to that of sarcoma virus-infected cells but do not, however, form colonies in agarose suspension culture. Cells infected with the myelocytomatosis virus MC29 assume stellate shapes and increase 18-fold in number during four days of monolayer culture. Cells infected with the myelocytomatosis virus MH2 assume fusiform shapes and increase fourfold in number during four days of monolayer culture. Neither MC29 nor MH2 renders chicken heart mesenchymal cells capable of colony formation in agarose suspension culture. Infection with avian leukosis viruses (RAV-1, RAV-2, RPL-42) or with transformation-defective mutants of Rous sarcoma virus (tdNY105, 107, 109) does not affect the morphology or proliferative behavior of chicken heart mesenchymal cells. Monolayer culture of chicken heart mesenchymal cells in plasma-containing medium appears, therefore, to define the ability of onc genes of acute transforming avian retroviruses to induce autonomous (mitogenic hormone-independent) cell proliferation, the essential characteristic of neoplasia. The differences in transformed morphology and rates of autonomous proliferation between cells infected with different acute transforming retroviruses probably reflects differences in the modes of action of the transforming proteins encoded by the onc genes of the respective viruses.(ABSTRACT TRUNCATED AT 400 WORDS)     

Plant transformation by microinjection techniques

Several techniques have been developed for introducing cloned genes into plant cells. Vectorless delivery systems such as PEG-mediated direct DNA uptake (e.g. Pasz-kowski et al. 1984), electroporation (e.g. Shillito et al. 1985), and fusion of protoplasts with liposomes (Deshayes et al. 1985) are routinely used in many experiments (see several chapters of this issue). A wide range of plant species, dicotyledonous as well as monocotyledonous, has been transformed by these vectorless DNA transfer systems. However, the availability of an efficient protoplast regeneration system is a prerequisite for the application of these techniques. For cells with intact cell walls and tissue explants the biological delivery system of virulent Agrobacterium species has been routinely used (for review see Fraley et al. 1986). However, the host range of Agrobacterium restricts the plant species, which can be transformed using this vector system. In addition, all these methods depend on selection systems for recovery of transformants. Therefore a selection system has to be established first for plant species to be transformed. The microinjection technique is a direct physical approach, and therefore host-range independent, for introducing substances under microscopical control into defined cells without damaging them. These two facts differentiate this technique from other physical approaches, such as biolistic transformation and macroinjection (see chapters in this issue). In these other techniques, damaging of cells and random manipulation of cells without optical control cannot be avoided so far. In recent years microinjection technology found its application in plant sciences, whereas this technique has earlier been well established for transformation of animal tissue culture cells (Capecchi 1980) and the production of transgenic animals (Brin-ster et al. 1981, Rusconi and Schaffner 1981). Furthermore, different parameters affecting the DNA transfer via microinjection, such as the nature of microinjected DNA, and cell cycle stage, etc, have been investigated extensively in animal cells (Folger et al. 1982, Wong and Capecchi 1985), while analogous experiments on plant cells are still lacking.     

The use of the nonradioactive digoxigenin chemiluminescent technology for plant genomic Southern blot hybridization: A comparison with radioactivity

A nonradioactive labelling and detection method for plant genomic DNA analysis is compared to the radioactive method. The radioisotopes are replaced by a nucleotide, digoxigenin-11-dUTP, and the signal detection is accomplished by the enzymatic reaction of alkaline phosphatase, conjugated to anti-digoxigenin antibodies, with the chemiluminescent substrate AMPPD (3-(2-spiroadamantane)-4-methoxy-4(3 phosphorytoxy) phenyl-1, 2-dioxetane). The sensitivity of the radioactive and nonradioactive methods are directly compared using identical Southern blots subjected to the radioactive and nonradioactive detection. The advantages of this nonradioactive method are discussed.     

High efficiency transient and stable transformation by optimized DNA microinjection into Nicotiana tabacum protoplasts

An efficient system has been established that allows well controlledDNA microinjection into tobacco (Nicotiana tabacum) mesophyllprotoplasts with partially regenerated cell walls and subsequentanalysis of transient as well as stable expression of injectedreporter genes in particular targeted cells or derived clones.The system represents an effective tool to study parametersimportant for the successful transformation of plant cells bymicroinjection and other techniques. Protoplasts were immobilizedin a very thin layer of medium solidified with agarose or alginate.DNA microinjection was routinely monitored by coinjecting FITC-dextranand aimed at the cytoplasm of target cells. The injection procedurewas optimized for efficient delivery of injection solution intothis compartment. Cells were found to be at the optimal stagefor microinjection about 24 h after immobilization in solidmedium. Embedded cells could be kept at this stage for up to4 d by incubating them at 4 C in the dark. Within 1 h successfuldelivery of injection, solution was routinely possible into20–40 cells. Following cytoplasmic coinjection of FITC-dextran and pSHI913,a plasmid containing the neo (neomycin phosphotransferase II)gene, stably transformed, paromomycin-resistant clones couldbe recovered through selection. Transgenic tobacco lines havebeen established from such clones. Injection solutions containingpSHI913 at a concentration of either 50 µg ml^–1or 1 mg ml^–1 have been tested. With 1 mg ml^–1 plasmidDNA the percentage of resistant clones per successfully injectedcell was determined to be about 3.5 times higher. Incubationof embedded protoplasts at 4C before microinjection was foundto reduce the percentage of resistant clones obtained per injectedcell Protoplasts were immobilized above a grid pattern and the locationof injected cells was recorded by Polaroid photography. Thefate of particular targeted cells could be observed. Isolationand individual culture of clones derived from injected cellswas possible. Following cytoplasmic coinjection of FITC-dextranand 1 mg ml^–1 plasmid DNA on average about 20% of thetargeted cells developed into microcalli and roughly 50% ofthese calli were stably transformed. Transient expression ofthe firefly luciferase gene (Luc) was nondestructively analysed24 h after injection of pAMLuc. Approximately 50% of the injectedcells that were alive at this time point expressed the Luc genetransiently. Apparently, stable integration of the injectedgenes occurred in essentially all transiently expressing cellsthat developed into clones. Key words: DNA microinjection, firefly luciferase, FITCdextran, Nicotiana tabacum, protoplast transformation