Staurosporine, a microbial alkaloid, is a strong inhibitor of protein kinases. The effects of staurosporine on the cell cycle progression and nuclear morphology of normal human lymphocytes stimulated to proliferate by phytohemagglutinin were studied and compared with the effects of this drug on human lymphocytic leukemic MOLT-4 cells. Exposure of normal lymphocytes to either 5-10 or 50-100 ng/ml of staurosporine resulted in the preferential accumulation of cells in G1 or G1 and G2 phases of the cell cycle, respectively. In contrast, regardless of the concentration (5-100 ng/ml), staurosporine arrested MOLT-4 cells initially in G2; these cells then initiated additional rounds of DNA replication, without division. Staurosporine (5-100 ng/ml) induced severe changes in the nuclear morphology of MOLT-4 cells, manifested as nuclear elongation, deep invaginations of the nuclear membrane, extensive fragmentation, and micronucleation. At concentrations of 5-10 ng/ml, staurosporine had no apparent effect on the nuclear morphology of normal lymphocytes and at 50-100 ng/ml it produced minor changes in the nuclear shapes of these cells. The data indicate that the kinase(s) involved in the regulation of cell exit from G1 and G2, respectively, in normal and leukemic lymphocytes may have different sensitivities to staurosporine, which suggests that the mechanisms controlling exit from G1 in these cells may be different. In MOLT-4 cells the staurosporine-sensitive kinase(s) appear to also be involved in phosphorylation of nuclear constituents essential for organization of gross chromatin structure. The different response of normal versus leukemic lymphocytes to staurosporine, if confirmed on clinical material, opens new strategies of tumor treatment.
Caffeine (3,7-dihydro-1,3,7,-trimethyl-1H-purine-6,6-dione; CAF) is known to potentiate the cytotoxic effects of DNA damaging agents such as ionizing radiation and alkylating agents. In contrast, however, the cytotoxic and cytostatic activity of aromatic, DNA-intercalating, DNA topoisomerase II inhibitors such as Adriamycin, ellipticine, or mitoxantrone are diminished in the presence of CAF. To resolve whether the protective effect of CAF is associated with a particular mechanism of drug interaction (e.g., intercalation into DNA, inhibition of DNA topoisomerase II), or the aromatic nature of the drug structure, per se, we have presently studied the effects of CAF on the cytostatic and cytotoxic action of camptothecin (CAM) and its less toxic but more water soluble derivative topotecan (TPT) on HL-60 human myelogenous leukemia cells: both drugs have aromatic structures but are nonintercalating inhibitors of DNA topoisomerase I. By using spectroscopy and titration microcalorimetry, we have also studied the direct interaction between CAF and TPT in solution. Low (20 nM) concentrations of CAM or TPT perturbed progression of HL-60 cells through S-phase, whereas higher concentrations (0.15 microM) of these drugs induced apoptosis; both effects were easily demonstrable after 4 h of treatment. When added simultaneously with CAM or TPT, CAF prevented both effects. The protective effect of CAF was concentration dependent and evident within the concentration range of 1-5 mM; nearly total protection was seen at a CAF concentration of 5 mM. The bathochromic and hypochromic shift in the absorption spectrum of the water soluble compound TPT upon addition of CAF indicated that CAF and TPT interact (stack) in a fashion similar to that previously observed for CAF and DNA intercalators. Microcalorimetric measurements of TPT titration with CAF indicate an exothermic reaction between these compounds (the enthalpy change was delta H degree = -4.2 kcal/mol), which is consistent with a stacking model of CAF-TPT interaction. Thus, the ability of CAF to protect HL-60 cells against the cell kinetic effects of CAM or TPT, as in the case of DNA intercalating topoisomerase II inhibitors, is most likely due to formation of complexes between CAF and these aromatic molecules, which result in reducing the effective concentration of the free form of these drugs available to the cells.
Onconase (Ranpirnase), a novel ribonuclease isolated from Rana pipiens oocytes, was reported to suppress cancer cell growth in vitro, reduce tumor size in animals, and augment cytotoxicity of several chemotherapeutic agents. Since onconase is currently in phase III clinical trials tested in treatment of mesothelioma, much emphasis has been placed on the mechanism of its anti-tumor activity. Previous studies have shown that onconase-responsive cells become arrested at the G1/S checkpoint of the cell cycle and also undergo apoptosis. A proposed mechanism for these effects is that the enzymatic activity of onconase targets cellular RNAs, in particular tRNA, with an accompanying inhibition of protein synthesis. In the present study, we have investigated the time- and dose-dependent effects of onconase on growth of Jurkat SN acute T-lymphocytic leukemia cells. Significant suppression of cell proliferation became evident after 72 and 96 h of treatment, and was most pronounced at the highest concentration (10 microg/ml; 8.3x10(-7) M) of onconase. This reduction of cell proliferation, however, was not accompanied by measurable changes in distribution of cells at different phases of the cell cycle, but was paralleled by the induction of apoptosis, as assayed by flow cytometry, and with a modest decrease in the expression of a cell cycle regulatory retinoblastoma protein (Rb). Further biochemical analysis revealed that growth suppression was closely coordinated with a down-regulation in the steady state and subcellular distribution of NF-kappaB, a transcription factor known to be functionally associated with cell survival. The reduction in expression of NF-kappaB by onconase appeared to coincide or even precede growth suppression, suggesting a causal relationship. To further test the hypothesis that cellular localization and expression of NF-kappaB may be critical to cellular response to onconase, we also studied the growth effects of onconase in Jurkat-BalphaM cells, which, unlike the parent SN T cells, contain a stably transfected dominant-negative IkappaB gene. Growth suppression by onconase in BalphaM cells was more pronounced and occurred earlier compared to SN cells, although still did not affect changes in cell cycle phase distribution. Contrary to expectation, however, diminution in NF-kappaB expression by onconase was even more pronounced in BalphaM cells, suggesting that this transcription factor, while presumably prevented from dissociation from its inhibitory protein IkappaB in these cells, is even more efficiently targeted for degradation by onconase. These results implicate NF-kappaB and its turnover as important determinants in the anti-proliferative/apoptotic effects of onconase in acute T-lymphocytic leukemia cells.
Chlorophyllin (CHL), the sodium and copper salt of chlorophyll, is capable of inhibiting the mutagenic activity of many chemical compounds. Several mechanisms have been advanced to explain the antimutagenic activity of CHL, including its antioxidant properties and its ability to form complexes with mutagens. The present study was designed to reveal whether the heterocyclic aromatic nature of a potential mutagen is essential to its sensitivity to CHL. Toward this end, the inhibitory effect of CHL on two compounds of similar chemical reactivity (mustards), that either embodied an aromatic structure (quinacrine mustard; QM) or did not (nitrogen mustard; NM), were compared. Human leukemic HL-60 and breast carcinoma MCF-7 cells were treated with QM or NM in the absence or presence of various concentrations of CHL. Both QM and NM when administered for 1-2 h at micromolar concentrations exerted similar effects; both arrested cells in G2 phase of the cell cycle, induced apoptosis and reduced the clonogenicity of MCF-7 cells. The simultaneous addition of 0.22 M CHL to cultures receiving QM virtually abolished the QM-induced inhibition of cell growth and clonogenicity. In contrast, CHL had no effect on reducing the cytostatic or cytotoxic activity of NM. CHL alone, at a concentration of 0.22 M, had minimal effect on growth of HL-60 cells slightly perturbing their progression through G2. The results are consistent with the model that explains the inhibition of the activity of mutagens or antitumor drugs with aromatic structures by CHL as mediated by its ability to sequester these molecules within heterologous mutagen:CHL complexes that are maintained by stacking interactions. Therefore, excess of chlorophyll in the diet, by sequestering aromatic mutagens (or antitumor drugs with a heterocyclic structure, if taken orally), may inhibit their accessibility to cells, thereby reducing their activity.
