RNA synthesis in activated macrophages I. Poly(I) X poly(C)-induced triggering of cytolytic activity is associated with decrease in RNA synthesis

The effects of polyinosinic, polycytidylic acid [poly(I) X poly(C)] on the activation and RNA metabolism in murine peritoneal macrophages (M phi) elicited by proteose-peptone (pM phi) was investigated. Poly(I) X poly(C) triggered the cytolytic activity of pM phi and augmented their glucose oxidation. In contrast, a profound depression of [3H]uridine incorporation into RNA was observed in poly(I) X poly(C)-activated pM phi. The degree of depression of RNA labeling paralleled the dose of poly(I) X poly(C) used to activate the pM phi and the expression of tumoricidal activity. This decrease in [3H]uridine incorporation into M phi RNA could not be accounted for by decreased permeability of the activated M phi to [3H]uridine, or by instability of the labeled RNA. Moreover, analysis of the specific activity of the intracellular uridine triphosphate (UTP) pool and studies on the labeling of M phi RNA with [32P] orthophosphate indicated that the decreased RNA labeling was not due to changes in the specific activity of UTP. We concluded that poly(I) X poly(C)-activated pM phi exhibit a depressed rate of RNA synthesis. We suggest that the rate of RNA synthesis may be investigated as a potential new indicator for M phi activation

Lymphokines inhibit macrophage RNA synthesis

The effects of lymphokine (LK) preparations on the incorporation of [3H]uridine into macrophage RNA were investigated. Supernatants from murine spleen cells activated in vitro by alloantigens or Con A, and shown to contain macrophage-activating factor (MAF), were used as the source of LK. It was observed that such LK preparations contain factor(s) causing a profound inhibition of [3H]uridine incorporation into the RNA of proteose-peptone-elicited peritoneal macrophages. Such RNA-labeling inhibitory factor (RIF) was absent in control supernatants from nonstimulated cultures, and showed activation curves similar to that of MAF. RIF activity was not due to altered permeability of macrophages to [3H]uridine nor to the changes in the specific activity of the pool of RNA precursors, but rather reflected an altered metabolism of RNA. The inhibition of RNA synthesis was dependent upon the presence of nanogram amounts of LPS as a costimulator. Moreover, the response to RIF appeared to be genetically controlled since macrophages from C3H/HeJ mice were not affected by RIF, while C3H/HeN mice were fully responsive. In parallel cultures of macrophages, LK were also tested for their MAF activity, and a strong similarity between the biological conditions in which MAF and RIF activities were expressed could be demonstrated. The assay for RIF provides a new and convenient parameter for measuring macrophage-sensitive LK activity that might be very useful for monitoring purification or for screening of T-cell hybridoma supernatants

Capillary Electrophoresis of Tropane Alkaloids and Glycoalkaloids Occurring in Solanaceae Plants

This chapter examines the role of capillary electrophoresis (CE) in the separation of tropane alkaloids, glycoalkaloids, and closely related compounds that have either pharmaceutical value or toxicological effects on humans. The latest significant developments in CE analysis have been selected and critically discussed. When the conventional CE mode was found unable to provide an acceptable selectivity towards the analytes, the addition of either an organic solvent, a chiral selector, or a surfactant to the running buffers was exploited. Likewise, nonaqueous CE (NACE) was also employed to increase solute solubilities and for a better compatibility of this media with mass spectrometry. It turns out that, upon selecting the most appropriate experimental conditions, the CE separation of tropane alkaloids and steroidal glycoalkaloids of Solanaceae plants was successfully accomplished. All major steps involved in the separation and detection of these secondary metabolites in complex samples are described and the relevant aspects of each application are examined with emphasis on the main aspects entailed a typical assay. More applications have yet to be developed in order to encourage more labs to exploit the tremendous potential of capillary electrophoresis