The combination regimen of idarubicin and taxotere is effective against human drug-resistant leukemic cell lines.

Up-regulation of Bcl-2 protein may contribute to drug resistance, by decreasing apoptosis after treatment, in pre-B and B-cell leukemias in pediatric patients. By contrast, augmented caspase-3 activity, an effector caspase, may be indicative of drug sensitivity due to increased cellular apoptosis. We have reported the development of an in vitro human T-lymphoblastic leukemia model resistant to ara-C and/or native E. coli L-asparaginase (ASNase), mimicking the drug resistance to the Capizzi II regimen. We have investigated the potential drug synergism between Idarubicin (IDA) and Taxotere (TXR) that may be active in the ara-C and ASNase double drug-resistant cell lines. The additive or synergistic activity between IDA and TXR is drug concentration-dependent in inducing caspase-3 activation and cellular apoptosis. We exposed two human drug-resistant cell lines that do not express the MDRI phenotype, one resistant to ASNase alone (CEM/ASNase-1-3) and the other resistant to both ara-C and ASNase (CEM/ara-C/I/ASNase-0.5-2), to physiologically achievable concentrations of IDA, TXR, or their combination. Both lines showed either synergistic drug activity to the combination regimen in comparison to either drug used alone, as determined by MTT assay, or additivity as demonstrated by flow cytometry after Annexin V and propidium iodide (PI) staining. After exposure of the ASNase-resistant line to various concentrations, the intracellular levels of Bcl-2 protein decreased to near zero relative to untreated control cells. The Bcl-2 protein reductions in these cells ranged from 30% to <1%, 49% to <1%, and 27% to 3% when treated with IDA or TXR as a single drug or IDA + TXR combination, respectively. Similarly, intracellular Bcl-2 levels in the double-resistant cell line decreased with reductions ranging from 24% to <1%, 87% to <1%, and 46% to <1% of the untreated control after treatment with IDA, TXR, or their combination, respectively. Conversely, the caspase-3 activity increased in a dose-dependent manner and inversely-correlated with loss of cell viability (r= 0.91) after exposure to IDA + TXR combination in the double drug-resistant line to both ara-C and ASNase. We conclude that the combination of the IDA + TXR regimen is highly synergistic or additive in drug resistant human leukemic cell clones. The molecular mechanism of action is due to the down-regulation of Bcl-2 protein and up-regulation of caspase-3 activity. This drug combination warrants further investigation for use in the treatment of patients with ara-C and/or ASNase refractory leukemias.

Taxotere and vincristine inhibit the secretion of the angiogenesis inducing vascular endothelial growth factor (VEGF) by wild-type and drug-resistant human leukemia T-cell lines.

Recent studies have shown that angiogenesis, which is induced by VEGF, may be involved in the pathogenesis of hematopoietic malignancies. A human leukemia model consisting of T-lymphoblastic CEM/0, 7 monoclonal refractory clones resistant to both cytosine arabinoside (ara-C) and L-asparaginase (ASNase), Jurkat/E6-1 and U937, representing the leukemic blasts from relapsed patients with leukemias was investigated for secretion of VEGF before and after treatment with various agents. The T-lymphoblastic cell line, Jurkat/E6-1, was used as the negative control, which has been characterized as not expressing mRNA nor the VEGF protein, and did not secrete VEGF. With no treatment, U937, the positive control, secreted the highest VEGF concentration of 1612.7 pg/ml. The CEM/O wild type cell line and 5 other drug-resistant clones secreted VEGF at levels ranging from 180.9 to 414.2 pg/ml. Two CEM drug-resistant clones, CEM/ara-C/G/ASNase-0.5-1 and CEM/ara-C/G/ASNase-1-1, lacked VEGF production. Docetaxel (Taxotere, TXR), Vincristine (VCR), ASNase, and the Fit-1/Fc chimera, a specific inhibitor of VEGF-dependent human umbilical vein endothelial cell (HUVEC) proliferation, were tested for inhibition of VEGF secretion. Treatment of the leukemic cell lines with 2 microg/ml Flt-1/Fc chimera for 24 hours completely inhibited VEGF secretion to the detection limit of the assay (<10pg/ml). After 24 hours incubation with Flt-1/Fc chimera, the leukemic cells appeared to be undergoing apoptosis, based on microphotography examination, suggesting that VEGF could be used in an autocrine loop to promote cell survival by the leukemic cells. Treatment with 0.5, 1, and 2 microg/ml Flt-1/FC chimera for 48 hours demonstrated a 15-25% growth inhibition by MTT assay. Strong inhibition of VEGF secretion in the culture media was observed after 10 microM TXR or 0.1 microM VCR for 24 hours in the wild-type and drug-resistant clones, except CEM/ara-C/I, in comparison with controls. In contrast, treatment with 1 IU/ml ASNase, a specific T-cell protein inhibitor, in 5 cell lines for 24 hours demonstrated no inhibition of VEGF in CEM/0 3 drug-resistant clones and the myeloid U937 line. We conclude that the leukemia cell lines actively secrete VEGF, in vitro. TXR and VCR, but not ASNase, strongly inhibit the VEGF production, suggesting that inhibition of this growth factor may be a mechanism of antileukemic activity. Moreover, the leukemic cell lines examined here may constitute a useful model to study antiangiogenic drugs, alone or in combination with established drug regimens used against refractory leukemias.

Synergistic antiviral effect of PEG-asparaginase (ONCASPAR), with protease inhibitor alone and in combination with RT inhibitors against HIV-1 infected T-cells: a model of HIV-1-induced T-cell lymphoma.

We evaluated the anti-HIV-1 activity of the T-cell-specific protein inhibitor PEG-asparaginase (PEG-ASNase) in human HIV-1-infected T-cells. We further examined the drug synergism between PEG-ASNase and the protease inhibitor Saquinavir (SAQ), both alone and in combination with nucleoside analog reverse transcriptase inhibitors (NRTI). Our drug synergism studies served as a model for an HIV-induced T-cell lymphoma. Phytohemagglutinin [PHA(+)] stimulated T-cells were infected with HIV-1 and then treated with one or more drugs 90 minutes from the viral exposure. To measure inhibition of viral replication, we examined HIV-1 RT and HIV-1 RNA in the supernatant and intracellularly on day 7 post-infection and drug treatment. Last, we examined the effect of administering drugs immediately after HIV-1 infection of T-cells to simulate treatment after an accidental exposure to the virus. PEG-ASNase, even when used alone, has anti-HIV-1 activity in PHA(+)-stimulated T-cells due to inhibition of protein synthesis. When the drug was used with SAQ, the combination was synergistic in inhibiting HIV-1 RT and RNA in the supernatant and intracellularly by 2.5 log10 in comparison with controls. PEG-ASNase and SAQ were even more effective in inhibiting HIV-1 replication when combined with the NRTI inhibitors azidothymidine (AZT) and (-)-beta-2',3'-dideoxy-3'-thiacytidine (3TC, lamivudine). The addition of ribonucleotide reductase inhibitor, 2-methyl-1H-isoindole-1,3-dione (MISID), further potentiated the antiviral effect of the regimen. HIV-1 RT and RNA analyses showed that the administration of the PEG-ASNase + SAQ drug combination immediately following exposure to HIV-1 completely inhibited the infection of T-cells in our in vitro T-cell model. From these results we conclude that PEG-ASNase is a valuable T-cell-specific protein inhibitor against HIV-1 infection, when used singly or in combination with a protease inhibitor, an RT inhibitor and an RR inhibitor. Since PEG-ASNase is a drug of choice for the treatment of T-cell lymphomas, a combination regimen containing PEG-ASNase could be very effective in the treatment of HIV-1-induced T-cell lymphoma and possibly AIDS. Future studies are needed in HIV-infected and/or HIV-induced T-cell lymphoma patients to investigate these findings.