Depletion of KIN17, a human DNA replication protein, increases the radiosensitivity of RKO cells.

The human KIN17 protein is a chromatin-associated protein involved in DNA replication. Certain tumor cell lines overproduce KIN17 protein. Among 16 cell lines, the highest KIN17 protein level was observed in H1299 non-small cell lung cancer cells, whereas the lowest was detected in MeWo melanoma cells. Cells displaying higher KIN17 protein levels exhibited elevated RPA70 protein contents. High KIN17 protein levels may be a consequence of the tumorigenic phenotype or a prerequisite for tumor progression. Twenty-four hours after exposure to ionizing radiation, after the completion of DNA repair, a co-induction of chromatin-bound KIN17 and RPA70 proteins was detected. Etoposide, an inhibitor of topoisomerase II generating double-strand breaks, triggered the concentration of KIN17 into punctuate intranuclear foci. KIN17 may be associated with unrepaired DNA sites. Flow cytometry analysis revealed that 48 h after transfection the uppermost KIN17-positive RKO cells shifted in the cell cycle toward higher DNA content, suggesting that KIN17 protein induced defects in chromatin conformation. Cells displaying reduced levels of KIN17 transcript exhibited a sixfold increased radiosensitivity at 2 Gy. The KIN17 protein may be a component of the DNA replication machinery that participates in the cellular response to unrepaired DSBs, and an impaired KIN17 pathway leads to an increased sensitivity to ionizing radiation.

Distinct experimental efficacy of anti-Fas/APO-1/CD95 receptor antibody in human tumors.

Ligation of the Fas receptor (FasR) is a key step in apoptosis induction. Using a series of human tumor cells (SNB19, SNB79, 143N2, and SHEP), we observed a distinct efficacy of human anti-FasR antibody with an apparent correlation with Fas cell surface antigen expression. In contrast, all cells studied expressed detectable FasR mRNA transcripts. For all anti-FasR antibody-sensitive tumor cells, we showed a similar efficacy of Mab according to dose fractionation and injection site. We showed that, when injected into nude mice bearing human osteosarcoma 143N2, neuroblastoma SHEP, prostatic cancer PAC120, and the two glioblastomas SNB19 and SNB79, anti-FasR Mab induces significant inhibition of the growth rate of 143N2, SHEP, and PAC120 tumors, but has no efficacy on SNB19 and SNB79 tumors, with a relationship between in vitro and in vivo sensitivity to anti-FasR antibody. Altogether, these results suggest the antitumor potential of anti-FasR antibody in human neoplasms.

The peripheral benzodiazepine receptors: a review.

Peripheral benzodiazepine receptors (PBRs) have been identified in various peripheral tissues as well as in glial cells in the brain. This review describes the tissue and subcellular distribution of the PBR in mammalian tissues and analyzes its many putative endogenous ligands. It deals with the pharmacological, structural and molecular characterization of the PBR, the proteins associated with the receptor (VDAC, ANC, PRAX-1) and their roles in cell growth and differentiation, cancer, steroid biosynthesis, and other physiological roles.

Methionine depletion enhances the antitumoral efficacy of cytotoxic agents in drug-resistant human tumor xenografts.

Efficacy of chemotherapy is limited in numerous tumors by specific cellular mechanisms that inactivate cytotoxic antitumoral drugs, such as ATP-dependent drug efflux and/or drug detoxification by glutathione. In reducing ATP pools and/or glutathione synthesis, it might be possible to enhance the efficacy of drugs affected by such resistance mechanisms. Reduction of the ATP pool and glutathione content is achievable in cancer cells by depleting the exogenous methionine (Met) supply and ethionine. Thus, the rationale for the present study was to use Met depletion to decrease the ATP and glutathione pools so as to sensitize tumors refractory to cytotoxic anticancer drugs. Met depletion was achieved by feeding mice a methionine-free diet supplemented with homocysteine. The effects of Met depletion combined with ethionine and/or chemotherapeutic agents were studied using human solid cancers xenografted into nude mice. TC71-MA (a colon cancer) SCLC6 (a small cell lung cancer), and SNB19 (a glioma) were found to be refractory to cisplatin, doxorubicin, and carmustine, respectively. These three drugs are used to treat such tumors and are dependent for their activity on the lack of cellular ATP- or glutathione-dependent mechanisms of resistance. TC71-MA, SCLC6, and SNB19 were Met dependent because their proliferation in vitro and growth in vivo were reduced by Met depletion. Cisplatin was inactive in the treatment of TC71-MA colon cancer, whereas a methionine-free diet, alone or in combination with ethionine, prolonged the survival of mice by 2-fold and 2.8-fold, respectively. When all three approaches were combined, survival was prolonged by 3.3-fold. Doxorubicin did not affect the growth of SCLC6, a MDR1-MRP-expressing tumor. A Met-deprived diet and ethionine slightly decreased SCLC6 growth and, in combination with doxorubicin, an inhibition of 51% was obtained, with survival prolonged by 1.7-fold. Combined treatment produced greater tumor growth inhibition (74%) in SCLC6-Dox, a SCLC6 tumor pretreated with doxorubicin. Growth of SNB19 glioma was not inhibited by carmustine, but when it was combined with Met depletion, survival duration was prolonged by 2-fold, with a growth inhibition of 80%. These results indicate the potential of Met depletion to enhance the antitumoral effects of chemotherapeutic agents on drug-refractory tumors.

Antitumoral effects of squamocin on parental and multidrug resistant MCF7 (human breast adenocarcinoma) cell lines.

The antiproliferative effects of squamocin, one of the easiest annonaceous acetogenins to obtain, were studied in the parental (MCF7-S) and the multidrug resistant (MCF7-R) human breast adenocarcinoma cell lines. Squamocin inhibited proliferation of both cell lines identically, by blocking the cell cycle in the G1-phase. This inhibition was reversible in the long term. Squamocin decreased the ATP pool in both MCF7 cell lines, but did not seem to induce apoptosis. Cytotoxic activity of adriamycin was not restored in MCF7-R Pgp expressing cells by squamocin addition.

Effect of 1-(2-chlorophenyl)-N-methyl-N-(1-methylpropyl)-3-isoquinoline carboxamide (PK11195), a specific ligand of the peripheral benzodiazepine receptor, on the lipid fluidity of mitochondria in human glioma cells.

When human glioma cells were incubated for 24 hr in serum-free medium with nanomolar concentrations of 1-(2-chlorophenyl)-N-methyl-N(1-methylpropyl)-3-isoquinoline carboxamide (PK11195), a specific ligand of the peripheral benzodiazepine receptor (PBR), a significant increase in the membrane fluidity of mitochondria isolated from these cells was registered. These effects were not observed with a shorter incubation time (2 hr) of the cells with PK11195 nor in the presence of serum. Other significant associated changes were observed: a significant increase of 16+/-4% of [3H]thymidine incorporation into DNA was detected in cells in the presence of PK11195 in serum-free medium, and an increase of 33+/-5% as compared to controls in nonyl acridine orange uptake, as indicator of mitochondrial mass, was also registered in cells treated with 10 nM PK11195. [3H]PK11195 binding was decreased in cells incubated with PK11195; a 45% decrease compared to controls was obtained. In view of the effect of PBR ligands on DNA synthesis, changes in mitochondrial lipid metabolism through interaction with PBRs might lead to biogenesis of mitochondria to support the increased metabolic requirements for cell division, which is even higher in malignant cells.

Lonidamine triggers apoptosis via a direct, Bcl-2-inhibited effect on the mitochondrial permeability transition pore.

The molecular mode of action of lonidamine, a therapeutic agent employed in cancer chemotherapy, has been elusive. Here we provide evidence that lonidamine (LND) acts on mitochondria to induce apoptosis. LND provokes a disruption of the mitochondrial transmembrane potential which precedes signs of nuclear apoptosis and cytolysis. The mitochondrial and cytocidal effects of LND are not prevented by inhibitors of caspases or of mRNA or protein synthesis. However, they are prevented by transfection-enforced overexpression of Bcl-2, an oncoprotein which inhibits apoptosis by stabilizing the mitochondrial membrane barrier function. Accordingly, the cell death-inducing effect of LND is amplified by simultaneous addition of PK11195, an isoquinoline ligand of the peripheral benzodiazepine receptor which antagonizes the cytoprotective effect of Bcl-2. When added to isolated nuclei, LND fails to provoke DNA degradation unless mitochondria are added simultaneously. In isolated mitochondria, LND causes the dissipation of the mitochondrial inner transmembrane potential and the release of apoptogenic factors capable of inducing nuclear apoptosis in vitro. Thus the mitochondrion is the subcellular target of LND. All effects of LND on isolated mitochondria are counteracted by cyclosporin A, an inhibitor of the mitochondrial PT pore. We therefore tested the effect of LND on the purified PT pore reconstituted into liposomes. LND permeabilizes liposomal membranes containing the PT pore. This effect is prevented by addition of recombinant Bcl-2 protein but not by a mutant Bcl-2 protein that has lost its apoptosis-inhibitory function. Altogether these data indicate that LND represents a novel type of anti-cancer agent which induces apoptosis via a direct effect on the mitochondrial PT pore.

Light-induced photoactivation of hypericin affects the energy metabolism of human glioma cells by inhibiting hexokinase bound to mitochondria.

Glucose-dependent energy required for glioma metabolism depends on hexokinase, which is mainly bound to mitochondria. A decrease in intracellular pH leads to a release of hexokinase-binding, which in turn decreases glucose phosphorylation, ATP content, and cell proliferation. Thus, intracellular pH might be a target for therapy of gliomas, and a search for agents able to modulate intracellular pH was initiated. Hypericin, a natural photosensitizer, displays numerous biological activities when exposed to light. Its mechanism and site of action at the cellular level remain unclear, but it probably acts by a type II oxygen-dependent photosensitization mechanism producing singlet oxygen. Hypericin is also able to induce a photogenerated intracellular pH drop, which could constitute an alternative mechanism of hypericin action. In human glioma cells treated for 1 h with 2.5 microg/ml hypericin, light exposure induced a fall in intracellular pH. In these conditions, mitochondria-bound hexokinase was inhibited in a light- and dose-dependent manner, associated with a decreased ATP content, a decrease of mitochondrial transmembrane potential, and a depletion of intracellular glutathione. Hexokinase protein was effectively released from mitochondria, as measured by an ELISA using a specific anti-hexokinase antibody. In addition to decreased glutathione, a response to oxidative stress was confirmed by the concomitant increase in mRNA expression of gamma-glutamyl cysteine synthetase, which catalyzes the rate-limiting step in overall glutathione biosynthesis, and is subject to feedback regulation by glutathione. Hypericin also induced a dose- and light-dependent inhibition of [3H]thymidine uptake and induced apoptosis, as demonstrated by annexin V-FITC binding and cell morphology. This study confirmed the mitochondria as a primary target of photodynamic action. The multifaceted action of hypericin involves the alteration of mitochondria-bound hexokinase, initiating a cascade of events that converge to alter the energy metabolism of glioma cells and their survival. In view of the complex mechanism of action of hypericin, further exploration is warranted in a perspective of its clinical application as a potential phototoxic agent in the treatment of glioma tumors.

Potentiation of lonidamine and diazepam, two agents acting on mitochondria, in human glioblastoma treatment.

BACKGROUND: Cellular metabolism in glioblastoma multiforme, the most common primary brain tumor in humans, is characterized by a high rate of aerobic glycolysis that is dependent on mitochondria-bound hexokinase. Moreover, high levels of glucose utilization and tumor aggressiveness in glioblastoma are associated with a high density of mitochondrial benzodiazepine receptors. We sought to inhibit glioblastoma metabolism by simultaneously inhibiting hexokinase with lonidamine and binding benzodiazepine receptors with diazepam. METHODS: Cellular glioblastoma metabolism in five glioblastoma cell lines was assessed in vitro by measuring cell proliferation (by use of a tetrazolium-based colorimetric assay, measurement of DNA synthesis, and assessment of cell cycle distribution), by measuring membrane fluidity (by fluorescence polarization measurement of cells stained with a fluorescent probe), and by measuring changes in intracellular pH. Immunodeficient nude mice bearing subcutaneous xenografts of human glioblastoma cells were used to assess the antitumor activities of lonidamine and diazepam; the mice were treated twice daily with lonidamine (total daily dose of 160 mg/kg body weight) and/or diazepam (total daily dose of 1 mg/kg body weight) for 10 consecutive days. RESULTS: When used in combination, the two drugs had a stronger effect on glioblastoma cell proliferation and metabolism in vitro than did either agent used alone. In vivo, the combination of lonidamine and diazepam was significantly more effective in reducing glioblastoma tumor growth than either drug alone (two-sided P<.01, Mann-Whitney U test, comparing growth of treated tumors with that of untreated tumors); this tumor growth retardation was maintained as long as treatment was given. CONCLUSION: The combination of lonidamine and diazepam--drugs that target two distinct mitochondrial sites involved in cellular energy metabolism--potentiates the effects of the individual drugs and may prove useful in the treatment of human glioblastomas.

[Targeting the gene of glucose metabolism for the treatment of advanced gliomas]. / Ciblage de gène du métabolisme du glucose pour le traitement des gliomes avancés.

Loss of chromosomes is a recurrent event in cancer. Chromosome-10 losses occur with tumor progression and characterize advanced gliomas. This chromosome carries many genes involved in glucose metabolism. Hexokinase (HK) gene is located on chromosome-10. Hexokinase enzymatic activity is decreased in glioblastomas. Hexokinase enables glucose entry into glycolysis and is critical for these highly glycolytic tumors. These enzyme is either free in the cytosol or bound to the mitochondrial outer membrane. Disturbance of HK binding to mitochondria by lonidamine led to inhibition of cells and xenografted-glioma growth. Hexokinase bind to a mitochondrial porin which involved peripheral benzodiazepine receptors. Inhibition of HK and peripheral benzodiazepine receptors by lonidamine and diazepam led to synergistic antitumoral activity in xenografted gliomas. Co-inhibition of these two receptors will lead to a decrease in glycolysis, often elevated in these tumors, without modifying energetic metabolism of normal cells.

Gliomas are driven by glycolysis: putative roles of hexokinase, oxidative phosphorylation and mitochondrial ultrastructure.

To elucidate the reasons for glycolytic deviation commonly found in brain tumors, hexokinase (HK) activity, mitochondria-HK binding, oxidative phosphorylation and mitochondrial ultrastructure were studied in 4 human xenografted gliomas. Lactate/pyruvate ratios were increased 3-4 fold and HK activity was of 2-4 fold lower than that of normal rat brain tissue, used as the control. The mitochondria-bound HK (mHK) fraction varied considerably and represented 9 to 69% of the total HK of that normal rat brain. The respiratory activity of glioma mitochondria, assessed by polarography and spectrophotometry, was within the normal range. However, the mitochondrial content of gliomas was lower than in the rat brain tissue, as revealed by the markedly decreased, activities of two unrelated mitochondrial enzymes, cytochrome c oxidase and citrate synthase in glioma homogenates. Electron microscopical studies confirmed the reduced number of mitochondria in 3 out of the 4 gliomas. Profound alterations of mitochondrial ultrastructure, namely of cristae and matrix densities, were observed in the 4 gliomas. The intercrista space was wider in all gliomas and the crista area was larger in 3 out of the 4 gliomas than in normal rat brain. Finally, the outer membrane of glioma mitochondria interacted intimately and extensively with the rough endoplasmic reticulum (RER) and/or nuclear membrane. These results suggest that, because of the very low content of normally functioning mitochondria, gliomas shift their energy metabolism towards a high-level glycolysis to generate their cellular ATP supply, probably through RER-mitochondria interactions and transformation-dependent redistribution of particulate HK from non-mitochondrial to mitochondrial receptors.

Methionine deprivation and methionine analogs inhibit cell proliferation and growth of human xenografted gliomas.

Growth of numerous malignant tumors depends on an exogenous methionine (MET) supply, while endogenously synthesized MET supports normal cell proliferation. Because an antitumor effect should be obtained by aggravating the altered MET metabolism in gliomas, MET dependency of human xenografted gliomas was evaluated and a therapeutic approach using MET deprivation or MET analogs to induce MET starvation was applied. In vitro proliferation inhibition of glioma cell lines by MET deprivation and two MET analogs, ethionine (ETH) and trifluoromethylhomocysteine (TFH), was measured. Proliferation of 7 human glioma cell lines tested was inhibited in MET-free medium, and was poorly or not reversed by homocysteine (HCY). ETH or TFH (concentration range: 0.005-2 mg/ml) inhibited proliferation of all cell lines tested. MET analog-induced inhibition was abolished by MET and enhanced by HCY. Cell-cycle alterations due to MET deprivation were optimally assessed after 30 h of culture and bromodeoxyuridine incorporation. In MET- medium, cells were arrested in the G1-phase. ETH induced a dramatic accumulation of cells in the G2-phase. ATP contents were reduced by MET analogs only in HCY+ medium, suggesting complementary effects of MET analogs and HCY. Human glioma bearing nude mice were fed an amino acid-substituted MET- HCY-supplemented diet (MET-HCY+) and/or treated with MET analogs, injected intraperitoneally daily. Using two human xenografted tumors derived from gliomas, antitumor effects were obtained by subjecting tumor-bearing nude mice to MET starvation. TG-1-MA was more sensitive to MET depletion (40% of growth inhibition, P < 0.10) than TG-8-OZ (no growth inhibition). Antitumor effects of a MET-HCY+ diet and 200 mg/kg of ETH were potentiated when co-administered to glioma-bearing mice (77% GI, P < 0.025 and 67%, P < 0.0057 to TG-1-MA and TG-8-OZ respectively). A dose-response effect with no toxicity was obtained when the ETH dose was increased 10 fold. Potentiation of the effects of ETH and a MET-free diet indicates that they probably act on the same pathway but not the same target. In conclusion, experimentally induced MET deprivation and MET-analog treatment retarded the growth of human gliomas. Combination of MET-analog therapy with MET substitution by HCY enhanced their respective effects.

High glycolysis in gliomas despite low hexokinase transcription and activity correlated to chromosome 10 loss.

Loss of chromosome 10 was observed in 10 out of 12 xenografted glioblastomas studied. Chromosome 10 carries the gene coding the hexokinase type 1 isoenzyme (HK-I), which catalyses the first step of glycolysis, which is essential in brain tissue and glioblastomas. We investigated the relationships between the relative chromosome 10 number, the amount of HK-I mRNA, HK-I activity and its intracellular distribution, and glycolysis-related parameters such as the lactate-pyruvate ratio, lactate dehydrogenase (LDH) and ATP contents. Individual tumour HK-I mRNA amounts were 23-65% lower than that of normal human brain and reflected the relative decrease of chromosome 10 number (alpha < 0.01). Total HK activities of individual glioblastomas varied considerably but were constantly (a mean of seven times) lower than that of normal brain tissue. The mitochondria-bound HK-I fraction of individual tumours was generally over 50%, compared with that of normal brain tissue. As shown by lactate - pyruvate ratios, in all the gliomas, glycolysis was elevated to an average of 3-fold that measured in normal brain. An elevated ATP content was also constantly noted. Adaptation of glioblastoma metabolism to the chromosome 10 loss and to the HK-I transcription unit emphasises the critical role of glycolysis in their survival. We hypothesise that HK-I, the enzyme responsible for initiating glycolysis necessary for brain function, may approach its lowest limit in gliomas, thereby opening therapeutic access to pharmacological anti-metabolites affecting energy metabolism and tumour growth.

Effects of lipid supplementation of culture media on cell growth, antibody production, membrane structure and dynamics in two hybridomas.

Membrane lipid organization and membrane fluidity affect cell functions. The effects of supplementing culture media with a lipid mixture (Ex-Cyte) containing cholesterol, phospholipids and fatty acids on cell growth, antibody production and membrane composition and dynamics in two hybridoma cell lines were studied. A49 cells decreased immunoglobulin production but cell growth increased. Lipids had no effect on the cell growth rate of B9 cells but increased immunoglobulin production and productivity. The fluidity of the deep areas of the plasma membrane and cytoplasmic organelles increased in the two cell lines. There was increased fluidity of the polar regions of the plasma membrane and a decreased phosphatidylethanolamine/phosphatidylcholine ratio in A49 cells. B9 cells underwent no change in fluidity of the polar regions but the phosphatidylinositol content was increased, together with higher monoclonal antibody production. These results demonstrate that antibody production is not linked to the dynamic properties of the membrane, even though changes in the membrane phosphatidylinositol content are associated with the final step of antibody secretion, but that the action of phospholipids and fatty acids on cell growth is membrane-associated.

Intracellular pH governs the subcellular distribution of hexokinase in a glioma cell line.

Hexokinase plays a key role in regulating cell energy metabolism. Hexokinase is mainly particulate, bound to the mitochondrial outer membrane in brain and tumour cells. We hypothesized that the intracellular pH (pH1) controls the intracellular distribution of hexokinase. Using the SNB-19 glioma cell line, pH1 variations were imposed by incubating cells in a high-K+ medium at different pH values containing specific ionophores (nigericin and valinomycin), without affecting cell viability. Subcellular fractions of cell homogenates were analysed for hexokinase activity. Imposed pH1 changes were verified microspectrofluorimetrically by using the pH1-sensitive probe SNARF-1-AM (seminaphtho-rhodafluor-1-acetoxymethyl ester). Imposition of an acidic pH1 for 30 min strongly decreased the particulate/total hexokinase ratio, from 63% in the control sample to 31%. Conversely, when a basic pH1, was imposed, the particulate/total hexokinase ratio increased to 80%. The glycolytic parameters, namely lactate/pyruvate ratio, glucose 6-phosphate and ATP levels, were measured concomitantly. Lactate/pyruvate ratio and ATP level were both markedly decreased by acidic pH1 and increased by basic pH1. Conversely, the glucose 6-phosphate level was increased by acidic pH1 and decreased by basic pH1. To demonstrate that the change of hexokinase distribution was not due to altered metabolite levels of glycolysis, a pH1 was imposed for a 5 min incubation time. Modification of the hexokinase distribution was similar to that noted after a 30 min incubation, whereas metabolite levels of glycolysis were not affected. These results provide evidence that the intracellular distribution of hexokinase is highly sensitive to variations of the pH1, and regulates hexokinase activity.

Glycolytic profile in normal brain tissue and gliomas determined by a micro-method analysis.

High aerobic glycolysis is frequent in cancers. Glucose phosphorylation is under control of hexokinase which is found in the cytosol or bound to mitochondria. Glycolysis parameters (glucose, pyruvate and lactate) and hexokinase were evaluated in extracts of 15 human gliomas and of normal brain tissue. Extracts were run and analysed for glucose lactate and pyruvate content using a centrifugal automatic analyzer, Mitochondria fractions were separated from total extracts and hexokinase enzymatic activities were measured in both, using an original micro-method. Conditions of hexokinase assay were standardized in terms of substrate concentration and linearity. Mean hexokinase activity in gliomas was variable, 3 times lower than in normal tissues and mainly bound to mitochondria, although lactate/pyruvate ratios were found to be 3.5 to 5.4 times higher. Glycolytic profile of tumor tissues can be rapidly assayed and evalated glycolysis in tumors could constitute a basis for therapy using antiglycolytic strategies.

Mitochondria-bound hexokinase as target for therapy of malignant gliomas.

Hexokinase plays an important role in glucose-utilizing tissues like normal brain and cancers. In these tissues, hexokinase (HK) is mainly bound to mitochondria (mHK). Our objectives were to evaluate total HK (tHK) activity and mHK fraction in gliomas and to determine whether mHK binding could be targeted for therapy. Tumors were obtained from 26 patients and 13 were xenografted. HK, lactate and ATP were measured in cytosol and mitochondria extracts. The tHK expressed in mU/mg protein were 147 +/- 19 and 78 +/- 12, in fresh gliomas and xenografts, respectively, and of 489 in the normal brain. The mHK fraction was 76% in normal brain, 74 +/- 4% in fresh tumors and 53 +/- 6% in xenografts. Lactate/mHK ratios were higher in gliomas than in normal brain. The ATP was 10, 52 +/- 31 and 19 +/- 8 nmol/mg protein in normal brain, xenografts and fresh gliomas respectively. Loss of one copy of chromosome 10 which carries the HK1 gene, was evidenced in 11 of the 13 xenografted gliomas. The anti-tumor effect of lonidamine (LND), which affects glycolysis in interfering with mHK activity, was tested in nude mice bearing 4 gliomas. LND (125 mg/kg, given i.p., twice daily for 5 days) led to a growth inhibition of TG-7-RO of 72%, with 2-fold growth retardation, and had no effect for TG-8-OZ. Intermediate LND-sensitivities for TG-11-DU and TG-10-PY were noted. The LND-sensitivity was correlated with the mHK activity (R2 = 0.73) and mHK fraction (R2 = 0.88). HK binding to mitochondria is a key of glycolysis in malignant gliomas, and targetting this binding with appropriate agents could be an effective therapeutic approach.

Interaction of a phosphatidylcholine derivative of 1,6-diphenyl-1,3,5-hexatriene (DPH) with intact living cells: Steady-state fluorescence polarization and phase fluorometry studies.

The potential interest of DPH-PC was checked with a macrophagic cell line (P388D1). The uptake of DPH-PC was associated with a rapid increase in both fluorescence intensity and a slow decrease in anisotropy values. A flow cytometry comparative study with DPH revealed in both cases the existence of two cell subpopulations with different labeling levels. The analysis of fluorescence decay of DPH-PC showed two components. The fractional intensity of the main component (9.7 ns) is higher than 92%. The Lorentzian distribution of the main lifetime presents an important homogeneity. The observation that an increase in temperature induced a decrease in steady state anisotropy values but did not affect the lifetime suggests that the anisotropy variations effectively reflect modifications in the cohesion of probe micro-surroundings. A transmembrane diffusional phenomenon of a fraction of fluorescent phospholipids (205) was suggested by a study with a nonpermeant membrane quencher. The transmembrane diffusion was confirmed by extraction of the phospholipid analog with fatty acid free BSA. The use of inhibitors of endogenous phospholipase A2 showed a progressive hydrolysis of the fluorescent phospholipid. Nevertheless, the hydrolysis can be neglected in the case of short term interactions with cells (<30 min). Therefore, it can be assumed that DPH-PC can be used as a membrane probe.