Reversal of cytosine arabinoside (ara-C) resistance by the synergistic combination of 6-thioguanine plus ara-C plus PEG-asparaginase (TGAP) in human leukemia lines lacking or expressing p53 protein.

BACKGROUND: Sequence-specific combinations of purine analogs, such as fludarabine or 6-mercaptopurine (6-MP), administered prior to cytosine arabinoside (ara-C) have been shown to abrogate ara-C resistance in human leukemia cells in vitro and in patients with relapsed acute myeloid or lymphoblastic leukemias. The two-drug combination of 6-MP plus ara-C results in greater cytotoxicity than that achieved with either ara-C or 6-MP alone. Further preclinical investigations have shown that the addition of PEG-asparaginase (PEG-ASNase) to the combination of 6-MP plus ara-C (6-MP + ara-C + PEG-ASNase) results in 15.6-fold synergism over that achieved with the two-drug regimen. This is due to increased DNA damage leading to apoptotic cell death. PURPOSE: Since the intravenous preparation of 6-MP is no longer available and since oral 6-thioguanine (6-TG) provides higher levels of intracellular thioguanine nucleotides than an isotoxic dose of oral 6-MP, we investigated the potential drug synergism of 6-TG plus ara-C plus PEG-ASNase (TGAP) in myeloid (HL60/S, HL60/SN3, U937) and lymphoblastic (CEM/0, CEM/ ara-C/B, CEM/ara-C/I, MOLT-4) leukemia cell lines. The CEM clones, MOLT-4 and HL60/SN3 cell lines expressed functional or measurable p53 protein, while the other cell lines did not. METHODS: The MTT and trypan blue dye exclusion assays were used to determine drug cytotoxicity. In addition, cellular apoptosis and cellular p53, p21/waf-1 and bcl-2 protein concentrations were determined by FACS analysis and ELISA assays. RESULTS: Sequential exposure to 6-TG (24 h) plus ara-C (24 h) plus PEG-ASNase (24 h) produced 1.3- to 18.3-fold drug synergism over the two-drug combination of 6-TG plus ara-C. The molecular mechanism of synergism was due to the fact that the three-drug combination was capable of downregulating bcl-2 oncoprotein levels in these cell lines even when p53 was absent. CONCLUSION: These studies strongly demonstrate that the TGAP regimen is highly synergistic in p53-null and p53-expressing leukemia cell lines. We conclude that this combination regimen is collaterally sensitive with ara-C and further evaluation in an investigational phase I trial in relapsed leukemia patients is warranted.

The synergism of 6-mercaptopurine plus cytosine arabinoside followed by PEG-asparaginase in human leukemia cell lines (CCRF/CEM/0 and (CCRF/CEM/ara-C/7A) is due to increased cellular apoptosis.

BACKGROUND: The only effective drug against ALL that inhibits protein synthesis is Asparaginase (ASNase). The drug depletes asparagine (Asn) in serum and cells and since the leukemic T-cells (thymic origin cells) lack asparagine synthetase, the amino acid starvation leads to apoptosis. When PEG-ASNase is combined with antimetabolite drugs such as ara-C, or combinations of 6-MP followed by ara-C, it augments the cytotoxic effect synergistically against human T-leukemia cells. MATERIALS AND METHODS: Synergism studies with two- or three-drug combination regimens in the human leukemia cell lines, CEM/0 and CEM/ara-C/7A have been investigated along with its effect in inducing apoptosis. RESULTS: The IC50 (approximately Dm) values of ara-C were 0.032 microM and 0.11 microM, and that of PEG-ASNase were 0.002 IU/ml and 1.52 IU/ml against CEM/0 and CEM/ara-C/7A cells, respectively. Thus, CEM/ara-C/7A cell line that is partially resistant to ara-C exhibited 681-fold cross-resistant to PEG-ASNase as compared to CEM/0. The concurrent drug exposure of ara-C and PEG-ASNase for 48 hours resulted in IC50 values of 0.56 nM for ara-C and 0.56 mIU/ml for PEG-ASNase respectively, in CEM/0 cells which represents a 57.4-fold synergism compared to ara-C alone. In the CEM/ara-C/7A cell line, the co-incubation with these two drugs resulted in IC50 value of 0.015 microM for ara-C and 0.015 IU/ml for PEG-ASNase respectively, or a 7.25-fold synergism as compared to ara-C and 101.1-fold synergism in comparison with PEG-ASNase alone. Pre-clinical studies involving three-drug combination consisting of 6-MP, ara-C and PEG-ASNase in a sequence-specific manner showed a 15.6-fold synergism against CEM/0 cell line over the two-drug combination of 6-MP followed by ara-C or approximately 160-fold syneryism over ara-C alone. CONCLUSION: The two-drug combination of ara-C and PEG-ASNase or the three-drug combination of 6-MP, ara-C and PEG-ASNase in the ara-C sensitive and resistant cell line showed significant drug synergism and CEM/ara-C/7A cells exhibited collateral sensitivity to PEG-ASNase. The three-drug combination also induced dose-dependent apoptotic DNA fragmentation which was higher than the two-drug combination of 6-MP and ara-C. We also conclude that the sequence specific use of PEG-ASNase in combination with the nucleoside analog drugs may benefit leukemia patients in early relapse.

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.