A new UV-visible confocal laser scanning microspectrofluorometer designed for spectral cellular imaging.

With the aim to perform spectroscopic studies and spectral images inside living cells, a microspectrofluorometer has been designed for two-dimensional spectral imaging in the visible and in the near-UV region. The main advantage of the device relies on its ability to scan the laser beam along one direction of the sample. This scanning is optically coupled with one direction of a bidimensional detector, allowing an instantaneous recording of a one-dimensional spectral image. The overall scanning of the sample is achieved by means of submicrometric displacements of the stage in the perpendicular direction. The main characteristics and performances of the microspectrofluorometer in terms of sensitivity (detection of a few molecules), spatial resolution (0.5 x 0.5 x 1 microm), and spectral resolution (1 nm) are presented. Finally, applications of this new apparatus concerning in situ localization and spectral characterization of two dyes are shown with Drosophila salivary glands (ethidium bromide) and T47D tumor cells (Hoechst 33342).

Characterization of intracellular pH gradients in human multidrug-resistant tumor cells by means of scanning microspectrofluorometry and dual-emission-ratio probes.

Multidrug-resistant cells are believed to contain a plasma-membrane-efflux pump which is hypothesized to expel anticancer drugs from the cytosol to the cell exterior. Many of these drugs are classified as weak bases whose binding to intracellular targets is pH-dependent. Slight alterations in intracellular pH gradients have been shown to affect accumulation, endocytosis and secretion of drugs. In this study, we developed a new method based on confocal spectral imaging analysis to determine intracellular pH gradients in sensitive and MDR tumor cells. Fluorescein isothiocyanate (FITC) and tetramethylrhodamine conjugated to dextran (FRD) and SNAFL-calcein-AM were used to determine pH in acidic compartments. Carboxy-SNARF1-AM was used to examine cytosolic pH. We observed that sensitive (HL60, K562, CEM and MCF7) cells exhibit lower acidity of the subcellular organelles than that corresponding to drug-resistant derivatives. Moreover, results obtained with carboxy-SNARF1-AM show that resistant cells display a more alkaline cytosolic pH. This results in a considerably larger pH gradient between the vesicular compartments and the cytosol of resistant cells than of sensitive cells. The lower pH gradient observed in sensitive cells may be related to a disruption in the organization of the trans-Golgi network (TGN). In drug-resistant cells, the organization of TGN appears compact. In addition, confocal microscopic analysis of cells labelled with FRD and SNAFL-calcein showed that sensitive cells contain a lower number of acidified vesicles. This suggest a diminished capacity of these cells to remove protonated drugs from the cytoplasm to secretory compartments followed by their secretion through the activity of the secretory and recycling pathways.

Confocal scanning microspectrofluorometry reveals specific anthracyline accumulation in cytoplasmic organelles of multidrug-resistant cancer cells.

We used confocal microspectrofluorometry to investigate intracellular distribution of pirarubicin or THP-DOX in parental K562, CEM, and LR73 tumor cells and their corresponding multidrug-resistant (MDR) strains. Each spectrum of a recorded image was considered as a combination of cell autofluorescence and fluorescence of the drug. In the cytoplasm of parental K562, CEM, and LR73 cells, THP-DOX fluorescence emission profile was similar to that of free drug in aqueous buffer. The (I550nm/I600nm) ratio was 0. 50 +/- 0.1. However, in the cytoplasm of resistant cells the 550-nm band profile was modified. The I550nm/I600nm ratio was 0.85 +/- 0.2 in MDR K562 cells, which is significantly different from the ratio in sensitive cells (p<0.01). This appeared first to correspond to accumulation and self-oligomerization of THP-DOX in cytoplasmic organelles of MDR cells. Transfection of LR73 cells with the mdr1 gene conferred this characteristic on the resistant LR73R cells. Bodipy-ceramide, a trans-Golgi probe, was co-localized with the typical fluorescence emission peak at 550 nm observed in the cytoplasm of MDR cells. This organelle has been shown to be more acidic in MDR cells. Moreover, this specific pattern was similar to that observed when anthracycline is complexed with sphingomyelin. The typical fluorescence emission peak at 550 nm decreased in MDR cells incubated simultaneously in the presence of the drug and quinine, verapamil, or S9788. Growth inhibitory effect and nuclear accumulation of THP-DOX data obtained on LR73R and LR73D cell lines showed that only during reversion of resistance by verapamil and S9788 was an increase of nuclear THP-DOX accumulation observed. Our data suggest that characteristics of molecular environment, such as higher pH gradient or lipid structures, would be potential mechanisms of multidrug-resistance via the sequestration of anthracyclines.

Localization and molecular interactions of mitoxantrone within living K562 cells as probed by confocal spectral imaging analysis.

Studying mechanisms of drug antitumor action is complicated by the lack of noninvasive methods enabling direct monitoring of the state and interactions of the drugs within intact viable cells. Here we present a confocal spectral imaging (CSI) technique as a method of overcoming this problem. We applied this method to the examination of localization and interactions of mitoxantrone (1, 4-dihydroxy-5, 8-bis-[([2-(2-hydroxyethyl)-amino]ethyl)amino]-9,10-anthracenedione dihydrochloride), a potent antitumor drug, in living K562 cells. A two-dimensional set of fluorescence spectra of mitoxantrone (MITOX) recorded with micron resolution within a drug-treated cell was analyzed to reveal formation of drug-target complexes and to create the maps of their intracellular distribution. The analysis was based on detailed in vitro modeling of drug-target (DNA, RNA, DNA topoisomerase II) interactions and environmental effects affecting drug fluorescence. MITOX exposed to aqueous intracellular environment, MITOX bound to hydrophobic cellular structures, complexes of MITOX with nucleic acids, as well as the naphtoquinoxaline metabolite of MITOX were simultaneously detected and mapped in K562 cells. These states and complexes are known to be immediately related to the antitumor action of the drug. The results obtained present a basis for the subsequent quantitative analysis of concentration and time-dependent accumulation of free and bound MITOX within different compartments of living cancer cells.

Quantitative confocal spectral imaging analysis of mitoxantrone within living K562 cells: intracellular accumulation and distribution of monomers, aggregates, naphtoquinoxaline metabolite, and drug-target complexes.

Confocal spectral imaging (CSI) technique was used for quantitative analysis of the uptake, subcellular localization, and characteristics of localized binding and retention of anticancer agent mitoxantrone (MITOX) within human K562 erythroleukemia cells. The CSI technique enables identification of the state and interactions of the drug within the living cells. Utilizing this unique property of the method, intracellular distributions were examined for monomeric MITOX in polar environment, MITOX bound with hydrophobic cellular structures, naphthoquinoxaline metabolite, and nucleic acid-related complexes of MITOX. The features revealed were compared for the cells treated with 2 microM or 10 microM of MITOX for 1 h and correlated to the known data on antitumor action of the drug. MITOX was found to exhibit high tendency to self-aggregation within intracellular media. The aggregates are concluded to be a determinant of long-term intracellular retention of the drug and a source of persistent intracellular binding of MITOX. Considerable penetration of MITOX in the hydrophobic cytoskeleton structures as well as growing accumulation of MITOX bound to nucleic acids within the nucleus were found to occur in the cells treated with a high concentration of the drug. These effects may be among the factors stimulating and/or accompanying high-dose mitoxantrone-induced programmed cell death or apoptosis.

Relationship between intracellular free calcium concentrations and the intracellular development of Toxoplasma gondii.

We measured intracellular free calcium concentrations ([Ca++]i) in the subcellular compartments of Toxoplasma gondii infected living cells using microspectrofluorometry and Indo-1 staining. [Ca++]i mapping was defined in infected and uninfected cells and in the neoformed parasitophorous vacuole (PV) 24 and 48 hr after parasite inoculation. At 24 hr after infection, a [Ca++]i gradient (PV/cytoplasm) was observed in favor of the PV in 72% of infected cells (p<0.001). Inside of the PV (lumen and parasites), [Ca++]i values appeared to be homogeneously distributed. At 48 hr after infection, the parasites had replicated and formed typical rosettes of more than 16 parasites. At this step, a positive [Ca++]i gradient (PV/cytoplasm) was detected in all analyzed cells (p<0.001). This result suggests that the PV (lumen and parasites) represents an individual subcellular compartment within the host cell that includes an independent [Ca++]i. Moreover, after 48 hr the cytoplasmic [Ca++]i decreased significantly (39 nM) compared with that measured from uninfected cells (53 nM) (p <0.05). Furthermore, the exit of Toxoplasma mediated by the calcium ionophore 4BrA23187 was preceded by a rise of [Ca++]i to 1 mM in the PV. The [Ca++]i rise and the liberation of parasites from their host appear to be correlated. On the basis of these observations, we suggest that the increase of [Ca++]i in the vacuole may act as a signal that triggers the egress of T. gondii.

Scanning microspectrofluorometry of rhodamine 123 in multidrug-resistant cells.

Scanning microspectrofluorometry has been developed to perform the mapping of fluorescence spectra from all locations in a living cell. This new method has been applied to study the molecular environment of rhodamine 123 (R123) in sensitive (K562, CEM) and multidrug-resistant (K562-R, CEM/VLB100) tumor cells. All cells exposed to R123 showed a similar distribution of fluorescence in the perinuclear region. A lower cytoplasmic fluorescence intensity corresponding to a reduced drug accumulation was observed in resistant cells, as expected in the multidrug resistance process. Fluorescence emission spectra of R123 are useful to probe the polarity of the R123 environment. Thus, fluorescence spectra of R123-treated cells have been analyzed as a linear combination of model spectra: R123 in water and R123 in tensio-active Triton X-100. In sensitive cells, emission spectra of R123 underwent a red shift, equivalent to those observed in isolated coupled mitochondria. This suggests the formation of a complex in hydrophobic sites. In contrast, R123 spectra were less shifted in resistant cells, showing two types of both hydrophobic and hydrophilic binding sites. This could be related to an intracellular redistribution of R123 in resistant cells.

[Characteristics of luminol chemiluminescence induced by the catalytic action of myeloperoxidase]. / Osobennosti khemiliuminestsentsii liuminola, vozbuzhdaemoi kataliticheskim deistviem mieloperoksidazy.

The effects of pH, luminol myeloperoxidase and hydrogen peroxide concentrations on the intensity of luminol chemiluminescence induced by myeloperoxidase catalysis were investigated. It was found that the intensity of luminescence is proportional to the enzyme concentration (up to 8.10(-8) M) and reaches the saturation level at higher enzyme concentrations. The dependence of chemiluminescence intensity on [H2O2] is bell-shaped: at H2O2 concentrations above 1.10(-4) M the luminescence is inhibited with a maximum at neutral values of pH. Luminol at concentrations above 5.10(-5) M inhibits this process. It was demonstrated that the effects of singlet oxygen, superoxide and hydroxyl radicals on the chemiluminescence reaction are insignificant. Luminol oxidation in the course of the myeloperoxidase reaction is induced by hypochlorite.