RIP3 is downregulated in human myeloid leukemia cells and modulates apoptosis and caspase-mediated p65/RelA cleavage.

The receptor-interacting protein kinase 3 (RIP3) associates with RIP1 in a necrosome complex that can induce necroptosis, apoptosis, or cell proliferation. We analyzed the expression of RIP1 and RIP3 in CD34+ leukemia cells from a cohort of patients with acute myeloid leukemia (AML) and CD34+ cells from healthy donors. RIP3 expression was significantly reduced in most AML samples, whereas the expression of RIP1 did not differ significantly. When re-expressed in the mouse DA1-3b leukemia cell line, RIP3 induced apoptosis and necroptosis in the presence of caspase inhibitors. Transfection of RIP3 in the WEHI-3b leukemia cell line or in the mouse embryonic fibroblasts also resulted in increased cell death. Surprisingly, re-expression of a RIP3 mutant with an inactive kinase domain (RIP3-kinase dead (RIP3-KD)) induced significantly more and earlier apoptosis than wild-type RIP3 (RIP3-WT), indicating that the RIP3 kinase domain is an essential regulator of apoptosis/necroptosis in leukemia cells. The induced in vivo expression of RIP3-KD but not RIP3-WT prolonged the survival of mice injected with leukemia cells. The expression of RIP3-KD induced p65/RelA nuclear factor-κB (NF-κB) subunit caspase-dependent cleavage, and a non-cleavable p65/RelA D361E mutant rescued these cells from apoptosis. p65/RelA cleavage appears to be at least partially mediated by caspase-6. These data indicate that RIP3 silencing in leukemia cells results in suppression of the complex regulation of the apoptosis/necroptosis switch and NF-κB activity.

GILZ inhibits the mTORC2/AKT pathway in BCR-ABL(+) cells.

The malignant phenotype of chronic myeloid leukemia (CML) is due to the abnormal tyrosine kinase activity of the BCR-ABL oncoprotein, which signals several downstream cell survival pathways, including phosphoinositide 3-kinase/AKT, signal transducer and activator of transcription 5 and extracellular signal-regulated kinase 1/2. In patients with CML, tyrosine kinase inhibitors (TKIs) are used to suppress the BCR-ABL tyrosine kinase, resulting in impressive response rates. However, resistance can occur, especially in acute-phase CML, through various mechanisms. Here, we show that the glucocorticoid-induced leucine zipper protein (GILZ) modulates imatinib and dasatinib resistance and suppresses tumor growth by inactivating the mammalian target of rapamycin complex-2 (mTORC2)/AKT signaling pathway. In mouse and human models, GILZ binds to mTORC2, but not to mTORC1, inhibiting phosphorylation of AKT (at Ser473) and activating FoxO3a-mediated transcription of the pro-apoptotic protein Bim; these results demonstrate that GILZ is a key inhibitor of the mTORC2 pathway. Furthermore, CD34(+) stem cells isolated from relapsing CML patients underwent apoptosis and showed inhibition of mTORC2 after incubation with glucocorticoids and imatinib. Our findings provide new mechanistic insights into the role of mTORC2 in BCR-ABL(+) cells and indicate that regulation by GILZ may influence TKI sensitivity.

BCR-ABL mutants spread resistance to non-mutated cells through a paracrine mechanism.

Patients with chronic myeloid leukemia who become resistant to the Abl kinase inhibitor imatinib can be treated with dasatinib. This sequential treatment can lead to BCR-ABL mutations conferring broad resistance to kinase inhibitors. To model the evolution of resistance, we exposed the mouse DA1-3b BCR-ABL(+) leukemic cell line to imatinib for several months, and obtained resistant cells carrying the E255K mutation. We then exposed these cells to dasatinib, and obtained dasatinib-resistant cells with composite E255K+T315I mutations. Subcloning isolated a minor clone also carrying V299L. In co-culture, mutated cells were able to spread resistance to non-mutated cells through overexpression of interleukin 3, activation of MEK/ERK and JAK2/STAT5 pathways, and downregulation of Bim. Even the presence of less than 10% of mutated cells was sufficient to protect non-mutated cells. Blocking JAK2 and MEK1/2 inhibited the protective effect of co-culture. Mutated cells were also sensitive to JAK2 inhibition, but blocking MEK1/2 alone, or in association with kinase inhibitors, had little effect. These data indicate that sequential Abl kinase inhibitor therapy can generate sub-populations of mutated cells, which may coexist with non-mutated cells and protect them through a paracrine mechanism. Targeting JAK2 could eliminate both populations.

Gamma-irradiation enhances transgene expression in leukemic cells.

The majority of immunotherapy-based gene therapy protocols consist of ex vivo gene transfer in tumor cells. To prevent further in vivo growth, modified cells must be irradiated before reinjection into patients. The present study examines the effects of gamma-irradiation on transgene expression in transduced leukemic cells. Human and murine leukemic cells were transfected with retroviral vectors or plasmids carrying beta-galactosidase, GM-CSF or CD80 genes. Fresh leukemic cells from patients with acute myeloid leukemia (AML) were transfected with AdZ.F(pK7) adenoviral vector. gamma-irradiation at various lethal doses enhanced transgene expression in leukemic cell lines and fresh AML cells when the gene of interest was under CMV promoter but not when SV40 promoter was used. Oxidative stress also enhanced transgene expression and both irradiation and oxidative stress effects were inhibited by addition of N-acetyl-L-cysteine, a thiol anti-oxidant, indicating the involvement of reactive oxygen species. Transgene expression was also enhanced in vivo 48 and 120 h after subcutaneous injection of irradiated leukemic cells in syngeneic mice. These results show that a cell vaccine protocol using ex vivo gene transfer of transduced cells might be feasible in acute leukemia even if leukemic cells must be irradiated at lethal doses prior to reinjection to patients.

Gene transfer of CD154 and IL12 cDNA induces an anti-leukemic immunity in a murine model of acute leukemia.

IL12 is an essential cytokine for the generation of T helper 1 response, natural killer (NK) cells and cytotoxic T lymphocyte (CTL) stimulation. CD154 triggers CD40 on antigen-presenting cells, thus inducing antigen presentation to the immune system and production of IL12. As IL12 and CD154 share several pathways mediating immune response, we investigated in an aggressive murine model of acute leukemia the relative antileukemic efficiency of IL12, CD154 and IL12 + CD154 gene transfer. Live leukemic cells transduced by IL12, CD154, and IL12 + CD154 showed reduced leukemogenicity but CD154 protective effect was reduced when 10(6) leukemic cells were injected. Vaccines with lethally irradiated IL12-transduced cells were able to cure mice previously injected with 10(4) leukemic cells and adoptive transfer of IL12-induced antileukemic immunity protected recipient mice. NK cytotoxicity was enhanced in mice vaccinated with leukemic cells transduced by IL12, CD154, and CD154 + IL12. IL12 transduced cells induced IFN-gamma mRNA in CD4(+) and CD8(+) T cells isolated from the spleen of vaccinated animals, however, in vivo depletion experiments showed that IL12 vaccine effect was CD4(+) but not CD8(+) T cell dependent. We conclude that IL12 gene is a more potent candidate than CD154 for gene therapy of acute leukemia.

Gene transfer of GM-CSF, CD80 and CD154 cDNA enhances survival in a murine model of acute leukemia with persistence of a minimal residual disease.

Gene transfer of various cytokines and co-stimulatory molecules has been reported to induce a potent antileukemic immunity in murine models, however, the relative efficiency and possible synergistic effects between candidate genes have not been extensively investigated. We analyzed in a murine model of BCR/ABL acute leukemia whether gene transfer of CD154, CD80 or GM-CSF as a single agent or combination of CD154 + GM-CSF, CD80 + CD154 and GM-CSF + CD80 in leukemic cells could enhance survival. We observed that CD154 gene transfer induced a marked inhibition of leukemogenicity, and also that CD154 and combination of GM-CSF and CD80 gene transfer protected mice against subsequent challenge with leukemic cells and had a therapeutic effect for a pre-established leukemia disease. We also found minimal residual leukemic disease by RT-PCR for 6 to 12 months in 0 to 25% of animals injected with transduced leukemic cells and surviving the challenge without evidence of disease, except in the control empty plasmid group where very few mice survived the challenge but all of those were positive by RT-PCR. These findings suggest that leukemic cell vaccination by gene transfer can induce a tumor dormancy phenomenon compatible with long-term survival.

gamma-ray irradiation induces B7.1 expression in myeloid leukaemic cells.

Expression of B7 molecules provides co-stimulatory signals to T lymphocytes, which prevent the induction of anergy. It has been previously reported that B7.1 gene transfer in a murine leukaemia model induced a potent antileukaemic immunity and that relative expression of B7.1 and B7.2 in human acute myeloid leukaemia (AML) had prognostic significance. As ex vivo engineering of leukaemic cells for immunotherapy protocols would require prior irradiation of these cells before reinjection to the patient, we investigated in murine and leukaemic cell lines and in 20 ex vivo primary cultured acute myeloid leukaemic cells the effect of gamma-irradiation on the expression of B7 molecules. We observed that gamma-irradiation enhanced B7.1 molecule expression in murine leukaemic cell lines and in B7.2 molecules in human HL60 and K562 cell lines. gamma-Irradiation induced B7.1 molecule expression in 90% AML samples but only 21% showed B7.2 molecule expression enhancement. B7.1 expression was increased both at the protein and RNA level in human AML cells but only at the protein level in the DA1-3b murine cell line. Oxidative stress increased B7.1 expression in the murine DA1-3b cell line but human cell lines and AML samples remained unaffected both by heat shock and oxidative stress, suggesting different pathways of B7.1 induction between mouse and human cells. Our data show that B7.1 expression can be induced by ex vivo irradiation of AML cells, indicating that these cells can express co-stimulatory molecules without gene transfer.

Transduction of bone marrow cells by the AdZ.F(pK7) modified adenovirus demonstrates preferential gene transfer in myeloma cells.

Adenoviral vectors can efficiently infect myeloma cell lines, but transduction of fresh myeloma cells performed at low multiplicity of infections (MOIs) showed only partial efficacy. The modified adenoviral vector AdZ.F(pK7), through binding of polylysines to heparan sulfate-containing receptors, could increase virus adsorption and gene transfer efficiency in myeloma cells, which express heparan sulfate-containing receptors. Thus, we investigated the ability of AdZ.F(pK7) vector to achieve efficient gene transfer in primary cultured fresh myeloma cells. Transduction of 16 primary cultured myeloma samples showed that gene transfer was much more efficient with AdZ.F(pK7) than with control AdZ.F. Both addition of soluble heparin and cell treatment with heparinase I dramatically inhibited gene transfer in myeloma cells by AdZ.F(pK7) but had no effect with AdZ.F, while addition of recombinant fiber protein inhibited AdZ.F but not AdZ.F(pK7), confirming that AdZ.F(pK7) gene transfer in myeloma cells is mediated by the targeting of heparan sulfates. AdZ.F(pK7) transduction of bone marrow cells showed that myeloma cells and hematopoietic progenitor AC133-, CD34-, and CD33-positive cells were efficiently transduced at an MOI of 100, but that only myeloma cells were significantly transduced at an MOI of 12. Thus, AdZ.F(pK7) vector seems to be well suited for immunological approaches of gene therapy or bone marrow-purging applications in multiple myeloma.

Transfer of p16inka/CDKN2 gene in leukaemic cell lines inhibits cell proliferation.

The gene encoding for p16ink4a, a negative regulator of transition between G1 and S phase, is homozygously deleted in a large proportion of acute lymphoblastic leukaemias (ALL). Transfer of p16ink4a gene in several solid tumour cell lines with functional pRb and lacking both p16ink4a alleles has resulted in a dramatic reduction of cell proliferation, and the aim of this work was to confirm this effect in leukaemic (especially ALL) cell lines. We tested the proliferation in liquid medium and in soft agar after transfer of p16ink4a gene by a retroviral vector in leukaemic cell lines with homozygous p16ink4a gene deletion (K562, CEM, Jurkat cell lines) or with p16ink4a gene hemizygous deletion and a point mutation inactivating the remaining allele (HL60 cell line). The viral titre obtained after transfection of PA317 amphotropic packaging cell line, which has a p16ink4a gene homozygous deletion, was low, suggesting that p16ink4a gene expression could impair viral production of retroviral packaging cell lines derived from the NIH3T3 cell line. After retroviral transfer of p16ink4a in cell lines and G418 selection in liquid medium, a strong cell proliferation inhibition was observed for K562, CEM and Jurkat, but no inhibition was seen for HL60. A strong growth reduction in soft agar was also observed with p16ink4a-transduced CEM, Jurkat and K562 cells, with a moderate growth reduction in the HL60 cell line. The growth inhibition in liquid culture, of K562 and Jurkat cell lines, was confirmed by electroporation transfer of the p16ink4a gene. Our findings show that p16ink4a gene transfer has a growth-inhibitory effect in leukaemic cell lines with p16ink4a gene homozygous deletion. These data suggest that p16 could be a suitable gene for gene therapy in ALL.

Mis-splicing yields circular RNA molecules.

We previously identified novel human ets-1 transcripts in which the normal order of exons is inverted, and demonstrated that although the order of exons is different than in the genomic DNA, splicing of these exons out of order occurs in pairs using genuine splice sites (1). Here we determine the structure of these novel transcripts, showing that they correspond to circular RNA molecules containing only exons in genomic order. These transcripts are stable molecules, localized in the cytoplasmic component of the cells. To our knowledge, this is the first case of circular transcripts being processed from nuclear pre-mRNA in eukaryotes. This new type of transcript might represent a novel aspect of gene expression and hold some interesting clues about the splicing mechanism.