Adriamycin dose and time effects on cell cycle, cell death, and reactive oxygen species generation in leukaemia cells.

We investigate the relative importance of the different mechanisms of Adriamycin, an anthracycline, and their interrelations, in particular the link between cell cycle arrest, cell death, and generation of reactive oxygen species (ROS) that is suspected to be the origin of cardiotoxic side-effects. We introduced a lifetime fluorescence based technology and used videomicrofluorometry, two efficient analytical methods. We show that depending on the doses and time after incubation, ADR will not reach the same compartments (nucleus, mitochondria, cytosol) in the cells, having consequences on the production of ROS, growth arrest pathways and cell death pathways.

New method for the detection of reactive oxygen species in anti-tumoural activity of adriamycin: a comparison between hypoxic and normoxic cells.

Tumour hypoxia plays a role in chemoresistance in several human tumours. However, how hyperbaric oxygen leads to chemotherapeutic gain is unclear. This study investigates the relation of reactive oxygen species (ROS) generation with anti-tumoural effect of adriamycin (ADR) on CCRF-CEM cells under hypoxic (2% O(2)) and normoxic (21% O(2)) conditions. A new method was used to measure intracellular ROS variations through the fluorescence lifetime of 1-pyrenebutyric acid. At 24 h, ADR, probably via semiquinone radical, enhances ROS levels in normoxic cells compared to hypoxic cells. Long-term studies show that ROS are also generated by a second mechanism related to cell functions perturbation. ADR arrests the cell cycle progression both under hypoxia and normoxia, indicating that oxygen and ROS does not influence the DNA damaging activity of ADR. The findings reveal that moderate improvement of ADR cytotoxicity results from higher ROS formation in normoxic cells, leading to elevated induction of cell death.

Total structure and inhibition of tumor cell proliferation of laxaphycins.

From a mixed assemblage of Lyngbya majuscula rich marine cyanobacteria, we isolated a series of cell growth inhibitory cyclic peptides. The structures of the two major components, laxaphycins A (1) and B (2), and of two minor peptides, laxaphycins B2 (3) and B3 (4), were determined by spectroscopic methods and degradative analysis. Absolute configurations of natural and nonproteinogenic amino acids were determined by a combination of hydrolysis, synthesis of noncommercial residues, chemical derivatization, and HPLC analysis. The organism producing the laxaphycins was identified as the cyanobacterium Anabaena torulosa. The antiproliferative activity of laxaphycins was investigated on a panel of solid and lymphoblastic cancer cells. Our results demonstrate that in contrast to laxaphycin A, laxaphycin B inhibits the proliferation of sensitive and resistant human cancer cell lines and that this activity is strongly increased in the presence of laxaphycin A. This effect appears to be due to an unusual biological synergism.

Measurements of calcium with a fluorescent probe Rhod-5N: Influence of high ionic strength and pH.

We describe a new method for the spectroscopic determination of high calcium concentration using a fluorescent probe Rhod-5N. This method was investigated in order to be utilized in high ionic strength solution, such as seawater. The probe is fluorescent when bound to calcium, LM, but not as the free form L. The dissociation constant of the equilibrium (0.14mM) was determined at several ionic strengths, i.e. in the absence and in the presence of additional ions (0.7M NaCl). The influence of pH was studied. In order to correctly model the experimental data, we included a new fluorescent compound: LHM (calcium bound protonated probe). The first acidity constant (0.02muM) and the second dissociation constant (4.5mM) were calculated. A useful range for the determination of calcium concentration is provided. Such a method is fast and easy to carry out.

Variation of 1-pyrenebutyric acid fluorescence lifetime in single living cells treated with molecules increasing or decreasing reactive oxygen species levels.

1-Pyrenebutyric acid (PBA) is a fluorescent probe whose fluorescence lifetime depends on local oxygen and free radical concentrations. We propose to use PBA fluorescence lifetime to quantify reactive oxygen species (ROS) in biological samples. Time-resolved microfluorimetry was used to record the fluorescence decay of single living cells loaded with this probe. We measured intracellular PBA fluorescence lifetimes and reduced nicotinamide adenine dinucleotide phosphate intensities under various oxygen concentrations. To confirm the feasibility of the new method, CCRF-CEM cells were treated with drugs that are known to increase or decrease ROS production. After treatment with adriamycin, we observed a decrease of PBA fluorescence lifetime. This corresponded to an increase of ROS concentration (80%). After treatment with cysteamine, we observed a reduction of the ROS concentration by 67%. Moreover, addition of exogenous H(2)O(2) solution resulted in a decrease of PBA fluorescence lifetime due to a raising of the intracellular ROS concentration. These results support our hypothesis linking a part of PBA fluorescence lifetime variations to intracellular fluctuation of ROS.

Effect of adriamycin treatment on the lifetime of pyrene butyric acid in single living cells.

We investigated the fluorescence lifetime of pyrene butyric acid (PBA) using various O2 concentrations in cells. Both in living and freshly fixed cells, PBA lifetime decreased with oxygen concentration. We recorded decay curves in single cells and measured PBA lifetime and NAD(P)H intensity values. Under nitrogen atmosphere, the probe lifetime differences (199 and 209 ns in living and freshly fixed cells, respectively) suggest a supplemental pathway for the deactivation of the probe when the cell functions are not stopped. We propose reactive oxygen species (ROS) to be the additional quenchers that cause this decrease. We further studied the effect of drugs generating ROS the anthracycline doxorubicin (adriamycin). For living cells, PBA lifetime decreased after adriamycin (ADR) treatment (200 and 1000 ng/ml). This supports our hypothesis that under nitrogen atmosphere and for freshly fixed cells, PBA lifetimes increase to an unchanging value due to absence of quenchers.

Cytotoxic effect of Laxaphycins A and B on human lymphoblastic cells (CCRF-CEM) using digitised videomicrofluorometry.

Laxaphycin A (laxa A) and Laxaphycin B (laxa B), cyclic peptides isolated from the terrestrial blue-green alga Anabaena laxa or the marine cyanobacterium Lyngbya majuscula have antifungal and cytotoxic activities. We used numerical videomicrofluorometry and a protocol of multiple labelling with Hoescht 33342 (nuclear DNA), Rhodamine 123 (mitochondria) and Nile Red (plasma membrane) to study the cytotoxicity of these substances in human lymphoblastic cells sensitive (CEM-WT) or resistant (CEM-VLB and CEM-VM1) to anticancer agents. The results indicate a low resistance index of 2 for CEM-VLB cells treated with laxa B or laxa A + lava B. For the three cell strains, following laxa B treatment, we observed an increase of a polyploid cell subpopulation that could result from the alteration of topoisomerase-II activity. On the contrary, the simultaneous treatment by laxa A and laxa B led to a decrease of that subpopulation with increasing laxa A doses. However, the effect of laxa A was less pronounced in the CEM-VM1 cells, which present a low intrinsic topoisomerase-II activity. For CEM-VLB cells, the higher doses needed can be attributed to their MDR resistance. Though we observed a synergistic effect between laxa B and laxa A (the latter is inactive by itself), these results indicate a different mode of action for laxa B and laxa A + laxa B. A more precise study of the mode of action of these compounds is warranted.

Lifetime of fluorescent pyrene butyric acid probe in single living cells for measurement of oxygen fluctuation.

We study the fluorescence lifetime of the well-known 1-pyrene butyric acid (PBA) to assess oxygen concentrations in living cells. The behavior of the probe is first studied in water, ethanol, protein solution and liposome suspension. The Stern-Volmer plot of these solutions is linear, and the bimolecular reaction rate constant agrees with previous observations. In single living cells, the PBA lifetime decreases with oxygen concentration (185 to 55 ns). The probe lifetime differences between living cells and liposome suspension, especially under nitrogen atmosphere, suggest a supplemental pathway for the deactivation of the probe. We simplify further the complex living cells system by stopping the cell functions and studying freshly fixed cells. In this case, we obtained an increase of PBA lifetime under nitrogen atmosphere (215 ns).

Microfluorometric study of oxygen dependence of (1"-pyrene butyl)-2-rhodamine ester probe in mitochondria of living cells.

The access to oxygen concentration is of importance in various organelles of living cells, especially in mitochondria. A new probe, (1"-pyrene butyl)-2-rhodamine ester, was designed to target this organelle. We present here the properties of the probe in such an environment. Microspectrofluorometry confirms the localization of the probe in the mitochondrial environment at low doses (1 microM). At these doses, the cell toxicity experiments show no effect on the cell growth. The emission spectrum measured at an excitation wavelength of 340 nm (pyrene centered) indicates energy transfer from the pyrene to the rhodamine chromophore, as also observed in an ethanol solution. With excitation at 337 nm, the excited state decays biexponentially with lifetime decays of 6-9 ns and 90 ns. The first corresponds to the intrinsic fluorescence of the cell and the latter corresponds to the pyrene chromophore. In degassed conditions the pyrene lifetime decay increases up to 130 ns. Under an oxygen atmosphere the lifetime decays decrease to 62 ns. The lifetime changes with the oxygen concentration were compared with the range obtained during our previous study in ethanol solution (5-220 ns). The observed differences were interpreted by studying the lifetime of the probe in simplified environments, liposome suspensions and protein solutions. In this paper we show that the new probe can be used to measure the fluctuation of oxygen concentration in the surroundings of mitochondria.