Microspectrofluorometry of carcinogens in living cells

A microspectrofluorometric approach has been used to follow the changes undergone by the carcinogen benzo(a)pyrene in malignant L cells, inducible Buffalo rat liver (BRL) cells and oncogenic mouse embryo C3H/10 T 1/2, clone 8 (CCL 226) cells. Since it is known that benzo(a)pyrene (BP) is converted metabolically to at least 40 metabolites, including phenols, epoxides, quinones, dihydrodiols, diol epoxides, and water-soluble conjugates, the interpretation of blue- and red-spectral shifts in fluorescence emission observed in BP-treated cells, compared to the original BP emission, undoubtedly presents considerable difficulties, but a certain number of facts clearly emerge. The sequence of blue-red shifts expressive of intracellular interactions and detoxification of the carcinogen is accelerated in the induced BRL compared to non-induced, and it is also generally accelerated in the malignant and inducible lines compared to the oncogenic line. The detection of highly reactive molecules (? of ultimate carcinogens) representing a small fraction of bulk fluorescence, still remains elusive, but two promising approaches are described: the use of phase-specific fluorescence quenchers which enable us to probe for the presence of metabolites in aqueous, hydrophobic or membrane phases of the cell, and the matrix analysis based on plotting of excitation-emission at different wavelengths for resolution of complex spectra. The former approach has enabled some separation or enhancement of red-blue emissions, and the second has helped to differentiate between emission of BP per se and its intracellular conversion products. Finally, observations at nuclear and cytoplasmic sites open the possibility of studying carcinogen interactions at different target sites.     

Microspectrofluorometry by digital image processing: measurement of cytoplasmic pH

An interface of our microspectrofluorometer with an image processing system performs microspectrofluorometric measurements in living cells by digital image processing. Fluorescence spectroscopic parameters can be measured by digital image processing directly from microscopic images of cells, and are automatically normalized for pathlength and accessible volume. Thus, an accurate cytoplasmic "map" of various spectroscopic parameters can be produced. The resting cytoplasmic pH of fibroblasts (3T3 cells) has been determined by measuring the ratio of fluorescein fluorescence exited by two successive wavelengths (489 and 452 nm). Fluorescein-labeled dextran microinjected into the cells is used as a pH indicator, since it is trapped in the cytoplasm but is excluded from the nucleus and other organelles. The average cytoplasmic pH is 6.83 (+/- 0.38). However, cytoplasmic pH exhibits a nonunimodal distribution, the lower mean pH being 6.74 (+/- 0.23). When 3T3 cells pinocytose medium containing fluorescein dextran, pinosomes peripheral to the nucleus exhibit a lower pH than those closer to the ruffling edge of the cell. The present image processing system is analyzed for linearity of detection, light scattering artifacts, signal to noise ratio, standard curves, and spatial resolution. The results obtained from digital image analysis are shown to be comparable to the results from standard microspectrofluorometry. We also discuss several other applications of this ratio imaging technique in cell biology.     

Microspectrofluorometry of the autofluorescent flagellum in phototactic brown algal zoids

Summary Posterior flagella of zoids ofScytosiphon lomemaria andChorda filum (Phaeophyceae, Chromophyta) were isolated and subjected to microspectrofluorometry using a high sensitivity microspectrofluorometer in order to characterize the flagellar autofluorescent substances. Vigorous agitation in a Hypertonic medium yielded preparations of largely intact flagella retaining detectable green flagellar autofluorescence. Under 380–425 nm excitation light, maximum emission of flagellar autofluorescence was observed at 495 nm, whereas under 400–440 nm excitation light fluorescence shifted to around 510 nm. Comparison of these spectra with the fluorescence spectra of 4,5-cyclic FMN isolated from fertile thalli ofS. lomentaria, and of 6-carboxypterin suggested that two (or more) different fluorescent substances (presumably a flavin and a pterin) are present in the flagella.Abbreviations DTT dithiothreitol - FMN flavin mononucleotide - HEPES N-[2-hydroxyethyl]piperazine-N-[2-ethanesulfonic acid]) - PEG polyethylene glycol - PFB paraflagellar body - Tris tris(hydroxymethyl) aminomethane. Dedicated to Professors Masakazu Tatewaki and Tadao Yoshida on the occasion of their academic retirement     

Microspectrofluorometry of ultraviolet-inducible fluorescence in supravitally-stained ascites tumour cells

Synopsis Ultraviolet irradiation of tumour cells (Ehrlich tetraploid ascites tumour of mice, TO strain), supravitally stained with thiazine dyes (Azure II, Azure A, Methylene Blue, Toluidine Blue) or an oxazine dye (Brilliant Cresyl Blue), induces blue fluorescence in cytoplasmic bodies believed to be lipid droplets or lysosome-like bodies. Microspectrofluorometry of the inducible fluorescence in Ehrlich tumour cells gives bimodal excitation (340/394 nm) and emission (443/700 nm) curves.     

Microspectrofluorometry as a tool for investigation of non-calcium interactions of Indo-1.

Indo-1 is a fluorescent calcium probe used to measure intracellular free calcium concentrations. These measurements are often performed by comparing the fluorescence intensities of Indo-1-treated cells at two selected wavelengths corresponding to the maxima of the fluorescence spectra of the calcium-bound and calcium-free forms. In this study, we used an optical multichannel analyser to numerise the fluorescence emitted by a single cell. A computerised resolution of numerised spectra was used on intracellular Indo-1 fluorescence. Calculation of numerical and graphic estimators allows us to evaluate the fit of the resolution. Different sets of characteristic spectra were compared using this method. It appeared that no linear combination of the two known forms of Indo-1 and of the cell autofluorescence can fit with spectra of Indo-1-treated cells. In addition, a study of the physico-chemical properties of Indo-1 shows the existence of two other forms of the molecule: a protonated form (maximum emission at 455 nm) and a form in interaction with proteins (maximum emission at 438 nm). Taking into account the contribution of these two new forms leads to an improved spectral resolution of the fluorescence of Indo-1-treated living cells and, therefore, improves calcium measurements. Moreover, quantification of the amount of the protonated form of Indo-1 allows a measurement of intracellular pH at the same time as calcium determination.     

Microspectrofluorometry of autofluorescence emission from human leukemic living cells under oxidative stress.

Image cytometry was applied to study the intracellular localization of autofluorescence and the influence of an oxidative stress on this emission. K562 erythroleukemia cancer cells were analyzed with a microspectrofluorometer, coupled with a Argon laser (Ar+) (363 nm). From each cell, 15 x 15 emission spectra were recorded in the 400-600 nm spectral range to generate a spectral image of autofluorescence. The intracellular locations of the autofluorescence emission and of the specific mitochondrial probe rhodamine 123 (R123) were matched. Under a 363 nm excitation, all spectra from K562 cells show equivalent profiles with a 455 nm maximum emission, near of reduced nicotinamide adenine dinucleotide-(Phosphate) solution (NAD(P)H) (465 nm maximum emission). The spatial distribution of autofluorescence is homogeneous and different from the one of R123. Hydrogen peroxide (H2O2) (200 microM) and menadione (Men) (5 microM) induce a weak spectral change and a decrease in autofluorescence intensity, down to 40% of the initial emission. Doxorubicin (Dox) induces a dose-dependent decrease in autofluorescence emission and a release of intracellular free radicals. When cells were pre-treated 1 h with 1 mM glutathione (GSH), Dox induces a lower free radicals release, no significant variation of autofluorescence intensity and a lower growth inhibitory effect. Images cytometry of autofluorescence suggest that the intracellular NAD(P)H would not be restricted to mitochondrial compartments. The release of free radicals was associated with a decrease in autofluorescence intensity, mainly attributed to NAD(P)H oxidation both inside and outside mitochondria.     

Microspectrofluorometry of fluorescent photoproducts in photosensitized cells. Relationship to cellular quiescence and senescence in culture

Microspectrofluorometry of L and WI-38 cells reveals chemical/structural changes due to quiescence or senescence, i.e., lipid peroxidation, spontaneous or photosensitized by hematoporphyrin. Cells treated with hematoporphyrin and a lysosomal umbelliferone probe show a fast-rising umbelliferone emission, plus a fluorescent photoproduct. Studies in rapidly growing versus quiescent L, early passage/late passage WI-38 cells, suggest accumulation of fluorescence Schiff bases (i.e., their association with granular regions of cells in stationary phase, spectral properties, fast increase in photosensitized cells) and a possible lysosomal membrane permeabilization in quiescent or senescent cells.     

Microspectrofluorometry of the protonation state of ellipticine, an antitumor alkaloid, in single cells.

The protonation state and intracellular distribution of ellipticine were investigated in single human mammary T47D cells by confocal laser microspectrofluorimetry. In the cell nucleus, only the protonated form of ellipticine was detected as a direct consequence of its apparent pK increase upon DNA binding. Both protonated and neutral forms were present in the aqueous cytoplasm, where the pH is close to the drug pK. When cells were incubated in high concentrations of K+, a condition that depolarizes the plasma membrane potential, ellipticine cellular accumulation was reduced. In the cytoplasm, ellipticine was mainly bound to mitochondria, and its protonation equilibrium was shifted toward the neutral form. The fluorescence spectrum of ellipticine bound to mitochondria was insensitive to valinomycin, whereas it was markedly shifted toward the protonated form after carbonyl cyanide p-trifluoromethoxy-phenylhydrazone or nigericin addition. Similar studies with ellipticine bound to isolated mitochondria suggest that it behaves as a fluorescent probe of mitochondrial pH in both isolated mitochondria and single living cells.     

Microspectrofluorometry of fluorescent photoproducts in photosensitized cells: Relationship to cellular quiescence and senescence in culture

Microspectrofluorometry of L and WI-38 cells reveals chemical/structural changes due to quiescence or senescence, i.e., lipid peroxidation, spontaneous or photosensitized by hematoporphyrin. Cells treated with hematoporphyrin and a lysosomal umbelliferone probe show a fast-rising umbelliferone emission, plus a fluorescent photoproduct. Studies in rapidly growing versus quiescent L, early passage/late passage WI-38 cells, suggest accumulation of fluorescence Schiff bases (i.e., their association with granular regions of cells in stationary phase, spectral properties, fast increase in photosensitized cells) and a possible lysosomal membrane permeabilization in quiescent or senescent cells.