1H NMR visible lipids are induced by phosphonium salts and 5-fluorouracil in human breast cancer cells.

Cationic lipophilic phosphonium salts (CLPS) selectively accumulate in the mitochondria of neoplastic cells and inhibit mitochondrial function. The effects of the CLPS p-(triphenylphosphoniummethyl) benzaldehyde chloride (drug A), and [4-(hydrazinocarboxy)-1-butyl] tris-(4-dimethylaminophenyl) phosphonium chloride (drug B), on human breast cells of differing biological properties were assessed using growth inhibition assays and 1H NMR. Drug A and, to a lesser extent, drug B demonstrated selective growth inhibition of the highly tumorigenic DU4475 breast carcinoma cell line compared to the transformed HBL-100 human breast cell line. However, in contrast to previous studies using other cell lines, no synergistic activity was found when the drugs were used in combination. 1H NMR demonstrated significant increases in mobile lipid acyl chain resonances in both cell lines treated with cytotoxic doses (IC50, 48 h) of the drugs used either alone or in combination. Two-dimensional NMR revealed accompanying decreases in phosphocholine/Lys levels in HBL-100 cells treated with A, B, or a 1:1 combination A+B at the IC50, and in DU4475 cells treated with drug A (IC50). This was accompanied by significant increases in cho/Lys ratios with IC50 A or combination A+B treatment. Similar spectra were observed in cells treated with 5-fluorouracil but not methotrexate, indicating that mobile lipid accumulation is a general but not universal response to cytotoxic insult.

Induction of magnetic resonance-visible lipid in a transformed human breast cell line by tetraphenylphosphonium chloride.

Proton magnetic resonance spectroscopy (1H MRS) and DNA flow cytometry were used to monitor the effects of the cationic lipophilic phosphonium salt and potential antineoplastic agent tetraphenylphosphonium chloride (TPP) on the transformed human breast cell line HBL-100. TPP treatment for 48 hr was cytostatic at low concentrations and cytotoxic at higher concentrations with an IC50 of 55 microM as measured by Trypan blue exclusion. At micromolar concentrations, TPP caused a significant increase in the methylene MR signal arising from mobile lipid as measured by the ratio of the lipid CH2 peak height to either the CH3 peak height (internal referencing) or the peak height for p-aminobenzoic acid (PABA) as an external reference in a co-axial capillary within the sample. Over the same concentration range, TPP caused a slowing of passage through S phase as demonstrated by a significant depletion of cells in G2/M phase with a concurrent but non-significant increase in cells in S. Time-dependent increases in MR-visible lipid were observed with 2 microM TPP treatment, and the removal of TPP from the culture medium caused no significant reduction in mobile lipid. Two-dimensional 1H-1H COSY spectra of TPP-treated HBL-100 cells revealed concentration-dependent increases in cross-peak volume ratios arising from lipid acyl chains relative to both internal (lysine, polyamines) and external (PABA) standards. Increases in choline and glycerophosphocholine cross-peak volume ratios were observed, indicating that the catabolism or rearrangement of phospholipids may be responsible for the observed MR-visible lipid increases.

Tetraphenylphosphonium chloride induced MR-visible lipid accumulation in a malignant human breast cell line.

The effect of the cationic lipophilic phosphonium salt tetraphenylphosphonium chloride (TPP) on a human malignant breast cell line, DU4475, was monitored with proton nuclear magnetic resonance (1H MRS). TPP caused a dose- and time- dependent increase in resonances arising from MR-visible lipid as measured by the CH2/CH3 ratio in the 1-dimensional 1H MR spectrum. Two-dimensional MRS identified increases in the glycerophosphocholine/lysine cross-peak ratio and corresponding decreases in the phosphocholine/lysine ratio in a dose- dependent fashion in TPP-treated cells. Lipid metabolic changes are discussed in the light of other MR experiments, and the data indicate that accumulation of MR-visible lipids may arise from the rearrangement of phospholipids accompanying mitochondrial destruction or from the catabolism of phospholipids associated with early events in the cytotoxic process.

Suramin sodium: pronounced effects on methotrexate transport and anti-folate activity in cultured tumor cells.

Suramin is an experimental anti-neoplastic agent which has shown promising activity against prostatic carcinoma and lymphoma in clinical trials. To elucidate its mechanism of action, suramin was examined for an effect on the transport of folate compounds by tumor cells. Influx of the anti-folate methotrexate via the reduced-folate carrier system of CCRF-CEM cells was found to be highly sensitive to inhibition by suramin but not to various other arylsulfonic acids. Inhibition by suramin was competitive, and the inhibition constant Ki was 1.3 microM, a value 3-fold lower than the Kt for half-maximal influx of methotrexate. Folate binding to the membrane-associated folate-binding protein of KB cells was not affected by suramin. Growth studies revealed that the response of human CCRF-CEM, KB, PC-3 and MCF-7 cells to methotrexate was antagonized from 6- to 17-fold by pharmacological levels (10-200 microM) of suramin. Conversely, growth inhibition was additive or synergistic when suramin was combined with metoprine, a lipophilic anti-folate which enters cells by diffusion. Synergism was observed between metoprine and suramin in CCRF-CEM cells, which take up folate exclusively through the reduced-folate carrier (inhibitable by suramin), whereas additivity was observed for KB cells, which rely largely on the folate-binding protein (unaffected by suramin) for folate import. Our results indicate that inhibition of cellular transport of folate compounds may explain part of the anti-neoplastic effects of suramin on tumor cells.

Phosphonium salts exhibiting selective anti-carcinoma activity in vitro.

Tetraphenylphosphonium cation (TPP) and other phosphonium cations selectively inhibited the growth in vitro of human pancreatic carcinoma-derived cells (PaCa-2) and Ehrlich Lettre Ascites cells (ELA) when compared with untransformed monkey kidney epithelial cells (CV-1). In contrast, neither cisplatin nor cytosine arabinoside showed significant selectivity using these lines. Evidence is presented to support the conclusion that the carcinoma-selective antiproliferative activity of phosphonium salts is due to selective accumulation caused by the abnormally high membrane potentials in carcinoma cells. Inhibition of TPP uptake into PaCa-2 and ELA cells by potassium and (for PaCa-2) valinomycin demonstrates that higher membrane potentials account for the carcinoma-selective uptake and cytostatic selectivity of the cation. For TPP chloride and 16 other phosphonium chlorides with a variety of structures, selective inhibition of PaCa-2 growth relative to CV-1 was optimal for the eight falling in a narrow range of octanol/water partition coefficients (between 0.013 and 0.24). A similar optimal selectivity range was observed for ELA cells relative to CV-1. The relationship between partition coefficients and cytostatic selectivity suggests that the rates of diffusion across cytoplasmic and mitochondrial membranes are key factors in the structure/anticarcinoma selectivity relationship for delocalized phosphonium salts in vitro. The relationship could prove useful for the design of other carcinoma-selective delocalized cations.

Synthesis and properties of novel psoralen derivatives.

We have synthesized a set of new trimethylpsoralen derivatives that are characterized by a chain extending from the 4'-position of the furan ring and linked to this ring by an aminomethylene group. The nature of the side chain can be varied widely. In these derivatives, the chains contain either amino or ethylene oxide units for enhanced water solubility and allow the introduction of a thiol or amine group to nucleic acids. These compounds represent the first set of thiolated psoralen derivatives, and their usefulness is demonstrated in several nucleic acid cross-linking experiments. The reagents can be used to create both intraduplex reversible cross-links between the two single-strand partners in a DNA double helix and interduplex reversible cross-links between two DNA double helices.

Amphiphilic cationic peptides mediate cell adhesion to plastic surfaces.

Four amphiphilic peptides, each with net charges of +2 or more at neutrality and molecular weights under 4 kilodaltons, were found to mediate the adhesion of normal rat kidney fibroblasts to polystyrene surfaces. Two of these peptides, a model for calcitonin (peptide 1, MCT) and melittin (peptide 2, MEL), form amphiphilic alpha-helical structures at aqueous/nonpolar interfaces. The other two, a luteinizing hormone-releasing hormone model (peptide 3, LHM) and a platelet factor model (peptide 4, MPF) form beta-strand structures in amphiphilic environments. Although it contains only 10 residues, LHM mediated adhesion to surfaces coated with solutions containing as little as 10 pmoles/ml of peptide. All four of these peptides were capable of forming monolayers at air-buffer interfaces with collapse pressures greater than 20 dynes/cm. None of these four peptides contains the tetrapeptide sequence Arg-Gly-Asp-Ser, which has been associated with fibronectin-mediated cell adhesion. Ten polypeptides that also lacked the sequence Arg-Gly-Asp-Ser but were nonamphiphilic and/or had net charges less than +2 at neutrality were all incapable of mediating cell adhesion (Pierschbacher and Ruoslahti, 1984). The morphologies of NRK cells spread on polystyrene coated with peptide LHM resemble the morphologies on fibronectin-coated surfaces, whereas cells spread on surfaces coated with MCT or MEL exhibit strikingly different morphologies. The adhesiveness of MCT, MEL, LHM, and MPF implies that many amphiphilic cationic peptides could prove useful as well defined adhesive substrata for cell culture and for studies of the mechanism of cell adhesion.