Israel Ringel

Oxidative stress causes membrane phospholipid rearrangement and shedding from RBC membranes--an NMR study.

Nuclear Magnetic Resonance (NMR) spectroscopy was used to investigate the relationship between oxidative stress experienced by RBCs and their phospholipid content and shedding. Using 1H-NMR, we demonstrated a higher lactate/pyruvate ratio, an indicator of oxidative stress, in normal RBCs treated with oxidants (t-butylhydroxyperoxide and H2O2) as well as in beta-thalassemic RBCs. Using 31P-NMR, we found 30% more phosphatidylcholine (PC), and unexpectedly, 35% less phosphatidylserine (PS) in the thalassemic RBCs. PS was decreased by treatment with oxidants and increased by anti-oxidants (vitamin C and N-acetyl cysteine); PC showed the opposite behavior. Thalassemic RBCs incubated in phosphate buffered saline produced more PS in the supernatant than normal RBCs. Anti-oxidants reduced the PS in the supernatant while oxidants increased it. Plasma of thalassemic patients contained 2.6-fold and 1.8-fold more PS and PC, respectively, than normal plasma. These results indicate that the decreased PS in RBCs resulted from increased shedding. The nature of the shed PS was studied by purifying and analyzing membranous microparticles from the plasma and RBC supernatants. More PS was found in microparticles purified from thalassemic plasma and RBC supernatants (5.6- and 4.8-fold, respectively) than in their normal counterparts. However, the bulk (80-90%) of the shed PS was not associated with microparticles. The significance of PS shedding for RBC survival needs further clarification.

Novel anthraquinone derivatives with redox-active functional groups capable of producing free radicals by metabolism: are free radicals essential for cytotoxicity?

The mode of action of antitumour anthraquinone derivatives (i.e. mitoxantrone) is not clearly established yet. It includes, among others, intercalation and binding to DNA, bioreduction and aerobic redox cycling. A series of anthraquinone derivatives, with potentially bioreducible groups sited in the side chain, have been synthesized and biologically evaluated. Their redox and cytotoxic activities were screened. Derivatives which bear a 2-(dimethylamino)ethylamino substituent, known to confer high DNA affinity, demonstrated cytotoxicity but not redox activity (beside the anthraquinone reduction). Conversely, derivatives which showed redox activity were not cytotoxic toward the P388 cell line. The results suggest that bioreduction is not the main mode of action in the cytotoxicity of anthraquinones.

Anti-neoplastic activity of paclitaxel on experimental superficial bladder cancer: In vivo and in vitro studies

The effects of intravesical administration of paclitaxel (taxol) in a bladder tumor model in mice, as well as the drugs in vitro activity on the same tumor cells, have been studied. Two cell lines, derived from MBT‐2 cells, were employed in these experiments. The T50 line (obtained by many passages in mice) was much more aggressive in vivo than the T5 line. In vivo paclitaxel treatment for 3 days after T5 implantation resulted in a considerable retardation of tumor growth, whereas under the same conditions the T50 line was much less, although still significantly, affected. When treatment was started 1 day after tumor implantation, both tumor variants were affected by paclitaxel to the same extent. The in vitro experiments utilized the MiCK assay, which allows continuous recording of the kinetics of cell growth. These studies revealed a 39.8% inhibition of cell growth by 2.10−8M paclitaxel in the T50 line and a 30‐fold increase in concentration had only a small additional effect on the degree of inhibition. At 2.10−8M paclitaxel, growth of T5 was inhibited by 21.7%, which increased to 35.2% at 6.10−7M. The treated cells displayed bundles of microtubuli, as described for other paclitaxel‐treated cells. Int. J. Cancer, 70:297–301, 1997.

Anthraquinone intercalators as carrier molecules for second-generation platinum anticancer drugs

Summary A series of complexes PtAm2L [where Am2 = (NH3)2, ethylenediamine(en), 1,2-diaminocyclohexane (DACH) or (NH3)(c-C6H11NH2) and where L is a bidentate 1,1-dicarboxylate ligand tethered to 1-aminoanthraquinone by various spacers] was prepared and screened in vitro against P388 leukemia cells. The free ligands displayed moderate activity and the corresponding platinum complexes were tenfold more active. The nature of the linker chain does not seem to affect the potency of the complexes. The potency depends on the nature of the inert amine ligand [NH3 > DACH > en]. The low aqueous solubility of these complexes prevented any in vivo studies and the preparation of water soluble analogs is currently under way.

Oxidative Stress-Induced Membrane Shedding from RBCs is Ca Flux-Mediated and Affects Membrane Lipid Composition

Phosphatidylserine (PS), which is normally localized in the cytoplasmic leaflet of the membrane, undergoes externalization during aging or trauma of red blood cells (RBCs). A fraction of this PS is shed into the extracellular milieu. Both PS externalization and shedding are modulated by the oxidative state of the cells. In the present study we investigated the effect of calcium (Ca) flux on oxidative stress-induced membrane distribution of PS and its shedding and on the membrane composition and functions. Normal human RBCs were treated with the oxidant t-butyl hydroperoxide, and thalassemic RBCs, which are under oxidative stress, were treated with the antioxidant vitamin C or N-acetylcystein. The intracellular Ca content was modulated by the Ca ionophore A23187 and by varying the Ca concentration in the medium. Ca flux was measured by Fluo-3, PS externalization and shedding were measured by quantitative flow cytometry and membrane composition was measured by 1H-NMR analysis of the cholesterol and phospholipids. The results indicated that increasing the inward Ca flux induced PS externalization and shedding, which in turn increased the membrane cholesterol/phospholipid ratio and thereby increased the RBC osmotic resistance. In addition, these processes modulated the susceptibility of RBCs to undergo phagocytosis by macrophages; while PS externalization increased phagocytosis, the shed PS prevented it. These results indicate that PS redistribution and shedding from RBCs, which are mediated by increased calcium, have profound effects on the membrane composition and properties and, thus, may control the fate of RBCs under physiological and pathological conditions.

Multiple triphenylphosphonium cations shuttle a hydrophilic peptide into mitochondria.

A variety of diseases are related to mitochondrial dysfunction. Hence, the ability to transport drugs to mitochondria that are otherwise cell impermeable would be of great therapeutic potential. Triphenylphosphonium (TPP) cations have been shown to accumulate in mitochondria when attached to small molecules. Here we report on the consequence of increasing the number of TPP moieties that are covalently linked to a model hydrophilic peptide Hemagglutinin A (HA). By extending the HA peptide with l-lysine amino acids to which the TPPs are covalently linked through the epsilon-amine, we have systematically synthesized the HA peptide with 0-3 TPPs. All peptides were subsequently labeled with FITC at the N-terminus. Cellular uptake and mitochondrial localization of the HA-TPP conjugates in HeLa cells were profoundly augmented with increasing number of TPPs, suggesting that this approach is applicable for the delivery of peptides. Furthermore, confocal microscopy demonstrated that the peptides localize to mitochondria. Importantly, all peptide conjugates did not show apparent toxicity at concentrations that are several orders of magnitude higher than those used for HA peptide delivery.

Synthesis of aminoanthraquinone derivatives and their in vitro evaluation as potential anti-cancer drugs

Abstract Anthraquinones, monosubstituted by aminoalkylamino side chains at positions 1, 2 or disubstituted at positions 1, 5 or 1, 8 were prepared. Their in vitro cytotoxic activity ( ED 50 ) was evaluated using: 1) P388 murine leukemia cells and 2) a subline of these cells resistant to doxorubicin (P388/ADR). The results of the structure—activity relationship analysis indicated that monosubstitution in position 1 or 2 showed a decrease of the activity when compared to adryamicin. Disubstitution in positions 1, 5 by N,N -dimethyl ethylenediamine side chain led to optimal activity, whereas the presence of cyclic dialkylamino substituents in the same positions resulted in a corresponding decrease in the anti-tumor activity. Disubstitution in positions 1,8 did not show any improvement in the cytotoxic activity.

Paclitaxel-induced modification of the effects of radiation and alterations in the cell cycle in normal and tumor mammalian cells.

The cytotoxicity of paclitaxel (taxol) is associated mainly with block in G2/M phase, the most radiosensitive phase of the cell cycle. Nevertheless, taxol-induced modification of the effects of radiation may vary from clear sensitization to subadditivity. Therefore, this effect was studied in relation to drug-induced alterations in the distribution of cells in the phases of the cell cycle in tumor cells (EMT-6 and OV-1063) and normal skin fibroblasts. Cell survival was evaluated with two colorimetric assays. The cell cycle was evaluated by FACS analysis of doubly-labeled cells. The radiosensitivity of the different cells studied was similar, apart from the less radiosensitive human fibroblasts. However, their dose- and time-dependent sensitivity to taxol varied significantly. After 24 h exposure of EMT-6 cells to taxol (IC50 approximately 20 nM), the fraction of cells in G2/M phase increased, the fraction in S phase decreased, and the proportion of possibly apoptotic cells with subdiploid and subtetraploid DNA content increased; this coincided with radiosensitization. In OV-1063 cells (IC50 approximately 3 nM), the drug-induced G2/M-phase block was most pronounced, but the combined effect with radiation was merely additive. In human fibroblasts (IC50 approximately 35 nM), a minimal G2/M-phase block with no change in the S phase and a massive elevation of apoptotic cells with subdiploid DNA content was accompanied by a subadditive combined effect with radiation. Six hours of exposure to taxol increased the fraction of cells in S phase in both nonsynchronized and S-phase-synchronized human fibroblasts (G1 phase approximately 65%, S phase approximately 13%). This was accompanied by a pronounced subadditive effect of the combined treatment. However, in G1-phase synchronized human fibroblasts (G1 phase > or =90%, S phase approximately 3%), only the fraction of cells in G2/M phase was slightly elevated, with a merely additive response to the combined treatment. The differences in the response to the combined treatment between slowly and rapidly proliferating cells in relation to modifications in the cell cycle are discussed.

Hormone sensitivity is reflected in the phospholipid profiles of breast cancer cell lines.

We have found that the profiles of total phospholipids in malignant breast cancer cell lines change going from hormone sensitive to highly hormone resistant cells lines. In particular, two phospholipid components that were absent or at very low levels in hormone sensitive MCF7 cells and moderately hormone sensitive cell lines (MIII, LCC2) were found in relatively high proportions in highly hormone resistant cell lines (MB435, MB231). These two components were shown to be the alkylacylphosphatidylcholine (AAPtdC) and the unsaturated analog plasmenylphosphatidylethanolamine (plasmenyl-PtdE). Another component phosphatidylethanolamine (PtdE) increased in correlation with the degree of hormone insensitivity. This was shown using 31P NMR spectroscopy of lipid extracts of the cells, and was confirmed using HPLC analysis, as well as other techniques. The significance of these results for the metabolic characteristics of these cell lines is related to the therapeutic responsiveness of breast cancer.

Characterization of the taxol structure-activity profile for the locus of the A-ring side chain

Abstract Two series of taxol analogs with various N -acyl groups on 3′-phenylisoserine and isoserine A-ring side chains, respectively, were prepared, and their microtubule assembly acitivities and cytotoxicities toward J774.2 cells were evaluated. Biological activities were adversely affected by the structural modifications investigated, although the 3′-phenylisoserine series was significantly more active than the isoserine series.