Chromatin fluorescence after carmine staining

Colorimetric quantitation of in vitro cell density using carmine, a chromosome-specific stain

Cell number is usually evaluated during in vitro studies to estimate metabolic or pharmacological effects of specific compounds. However, estimation of in vitro cell density by direct cell counting is a laborious and time-consuming task, whereas indirect methods for cell quantitation have serious disadvantages such as environmental costs or inaccuracies derived from non-specific interferences. We developed a new method for in vitro cell density quantitation which employs carmine, a natural dye widely used for chromosome staining in cytological studies. Normal or transformed murine fibroblasts, avian normal fibroblasts, human epithelial HeLa cells, and insect cells, inoculated at a range of cell densities, were fixed with 4% formaldehyde/PBS and stained with 0.4% alcoholic-HCl carmine. The stain retained in cell monolayers was extracted with 0.01 M NaOH and spectrophotometrically measured at 531 nm. Invariably, high correlation coefficients between cell number and absorbance were obtained for each cell type, within a range of 5 x 10(3) to 5 x 10(5) cells. Moreover, identical cell growth curves were obtained when cell number was estimated over several days of culture by both direct cell counting and carmine staining methods. Our results show that the carmine staining method represents an easy, precise and reliable alternative for in vitro cell quantitation, avoiding interferences caused by cell components modulable by culture treatments, and over a wide range of cell types and cell densities.

Microscopical and spectroscopic studies on the fluorescence of a daunomycin-aluminum complex

In this study, the spectroscopic features and microscopical applications of the fluorescent daunomycin-Al3+ complex have been analyzed. In the presence of Al3+, the absorption spectrum of daunomycin showed a deep bathochromic shift and new peaks at 529 and 566 nm, whereas the fluorescence emission was considerably modified. The emission of daunomycin alone (peak at 560 nm under optimal excitation at 470 nm) decreased continuously from 0.5 to 24h after addition of Al3+ ions, and a new emission peak appeared at 580 nm (optimal excitation at 530 nm). Under the fluorescence microscope using green exciting light, nuclei from chicken blood smears and paraffin sections of rat embryos stained with daunomycin showed a weak emission, which greatly increased after treatment with Al3+ ions. The bright and stable fluorescence of chromatin DNA induced by daunomycin-Al3+ could be a valuable labelling method in fluorescence microscopy and DNA cytochemistry.