Scientific Resources

The present study reports for the first time a dual antiglioma effect of the well-known antidiabetic drug metformin. In low-density cultures of the C6 rat glioma cell line,metformin blocked the cell cycle progression in G(0)/G(1) phase without inducing significant cell death. In confluent C6 cultures,on the other hand,metformin caused massive induction of caspase-dependent apoptosis associated with c-Jun N-terminal kinase (JNK) activation,mitochondrial depolarization and oxidative stress. Metformin-triggered apoptosis was completely prevented by agents that block mitochondrial permeability transition (cyclosporin A) and oxygen radical production (N-acetylcisteine),while the inhibitors of JNK activation (SP600125) or glycolysis (sodium fluoride,iodoacetate) provided partial protection. The antiglioma effect of metformin was reduced by compound C,an inhibitor of AMP-activated protein kinase (AMPK),and was mimicked by the AMPK agonist AICAR. Similar effects were observed in the human glioma cell line U251,while rat primary astrocytes were completely resistant to the antiproliferative and proapoptotic action of metformin. View Publication

Infection with a recombinant murine-feline gammaretrovirus,MoFe2,or with the parent virus,Moloney murine leukemia virus,caused significant reduction in B-lymphoid differentiation of bone marrow at 2 to 8 weeks postinfection. The suppression was selective,in that myeloid potential was significantly increased by infection. Analysis of cell surface markers and immunoglobulin H gene rearrangements in an in vitro model demonstrated normal B-lymphoid differentiation after infection but significantly reduced viability of differentiating cells. This reduction in viability may confer a selective advantage on undifferentiated lymphoid progenitors in the bone marrow of gammaretrovirus-infected animals and thereby contribute to the establishment of a premalignant state. View Publication

Wortmannin (Wm),a steroid-like molecule of 428.4 Da,appears to be unstable in biological fluids (apparent chemical instability),yet it exhibits an antiproliferative activity in assays employing a 48 hr incubation period (prolonged bioactivity),a situation we refer to as the wortmannin paradox." Under physiological conditions� View Publication

Activated tyrosine kinases have been frequently implicated in the pathogenesis of cancer,including acute myeloid leukemia (AML),and are validated targets for therapeutic intervention with small-molecule kinase inhibitors. To identify novel activated tyrosine kinases in AML,we used a discovery platform consisting of immunoaffinity profiling coupled to mass spectrometry that identifies large numbers of tyrosine-phosphorylated proteins,including active kinases. This method revealed the presence of an activated colony-stimulating factor 1 receptor (CSF1R) kinase in the acute megakaryoblastic leukemia (AMKL) cell line MKPL-1. Further studies using siRNA and a small-molecule inhibitor showed that CSF1R is essential for the growth and survival of MKPL-1 cells. DNA sequence analysis of cDNA generated by 5'RACE from CSF1R coding sequences identified a novel fusion of the RNA binding motif 6 (RBM6) gene to CSF1R gene generated presumably by a t(3;5)(p21;q33) translocation. Expression of the RBM6-CSF1R fusion protein conferred interleukin-3 (IL-3)-independent growth in BaF3 cells,and induces a myeloid proliferative disease (MPD) with features of megakaryoblastic leukemia in a murine transplant model. These findings identify a novel potential therapeutic target in leukemogenesis,and demonstrate the utility of phosphoproteomic strategies for discovery of tyrosine kinase alleles. View Publication

The kinase inhibitor imatinib mesylate targeting the oncoprotein Bcr-Abl has revolutionized the treatment of chronic myeloid leukemia (CML). However,even though imatinib successfully controls the leukemia in chronic phase,it seems not to be able to cure the disease,potentially necessitating lifelong treatment with the inhibitor under constant risk of relapse. On a molecular level,the cause of disease persistence is not well understood. Initial studies implied that innate features of primitive progenitor cancer stem cells may be responsible for the phenomenon. Here,we describe an assay using retroviral insertional mutagenesis (RIM) to identify genes contributing to disease persistence in vivo. We transplanted mice with bone marrow cells retrovirally infected with the Bcr-Abl oncogene and subsequently treated the animals with imatinib to select for leukemic cells in which the proviral integration had affected genes modulating the imatinib response. Southern blot analysis demonstrated clonal outgrowth of cells carrying similar integration sites. Candidate genes located near the proviral insertion sites were identified,among them the transcription factor RUNX3. Proviral integration near the RUNX3 promoter induced RUNX3 expression,and Bcr-Abl-positive cell lines with stable or inducible expression of RUNX1 or RUNX3 were protected from imatinib-induced apoptosis. Furthermore,imatinib treatment selected for RUNX1-expressing cells in vitro and in vivo after infection of primary bone marrow cells with Bcr-Abl and RUNX1. Our results demonstrate the utility of RIM for probing molecular modulators of targeted therapies and suggest a role for members of the RUNX transcription factor family in disease persistence in CML patients. View Publication

BACKGROUND AND OBJECTIVES: Chemokines are soluble mediators involved in angiogenesis,cellular growth control and immunomodulation. In the present study we investigated the effects of various chemokines on proliferation of acute myelogenous leukemia (AML) cells and constitutive chemokine release by primary AML cells. DESIGN AND METHODS: Native human AML cells derived from 68 consecutive patients were cultured in vitro. We investigated AML cell proliferation (3H-thymidine incorporation,colony formation),chemokine receptor expression,constitutive chemokine release and chemotaxis of normal peripheral blood mononuclear cells. RESULTS: Exogenous chemokines usually did not have any effect on AML blast proliferation in the absence of hematopoietic growth factors,but when investigating growth factor-dependent (interleukin 3 + granulocyte-macrophage colony-stimulating factor + stem cell factor) proliferation in suspension cultures the following patient subsets were identified: (i) patients whose cells showed chemokine-induced growth enhancement (8 patients); (ii) divergent effects on proliferation (15 patients); and (iii) no effect (most patients). These patient subsets did not differ in chemokine receptor expression,but,compared to CD34- AML cells,CD34+ cells showed higher expression of several receptors. Chemokines also increased the proliferation of clonogenic AML cells from the first subset of patients. Furthermore,a broad constitutive chemokine release profile was detected for most patients,and the following chemokine clusters could be identified: CCL2-4/CXCL1/8,CCL5/CXCL9-11 (possibly also CCL23) and CCL13/17/22/24/CXCL5 (possibly also CXCL6). Only the CCL2-4/CXCL1/8 cluster showed significant correlations between corresponding mRNA levels and NFkB levels/activation. The chemotaxis of normal immunocompetent cells for patients without constitutive chemokine release was observed to be decreased. INTERPRETATION AND CONCLUSIONS: Differences in chemokine responsiveness as well as chemokine release contribute to patient heterogeneity in AML. Patients with AML can be classified into distinct subsets according to their chemokine responsiveness and chemokine release profile. View Publication

In the context of pancreatic cancer,metastasis remains the most critical determinant of resectability,and hence survival. The objective of this study was to determine whether Hedgehog (Hh) signaling plays a role in pancreatic cancer invasion and metastasis because this is likely to have profound clinical implications. In pancreatic cancer cell lines,Hh inhibition with cyclopamine resulted in down-regulation of snail and up-regulation of E-cadherin,consistent with inhibition of epithelial-to-mesenchymal transition,and was mirrored by a striking reduction of in vitro invasive capacity (P textless 0.0001). Conversely,Gli1 overexpression in immortalized human pancreatic ductal epithelial cells led to a markedly invasive phenotype (P textless 0.0001) and near total down-regulation of E-cadherin. In an orthotopic xenograft model,cyclopamine profoundly inhibited metastatic spread; only one of seven cyclopamine-treated mice developed pulmonary micrometastases versus seven of seven mice with multiple macrometastases in control animals. Combination of gemcitabine and cyclopamine completely abrogated metastases while also significantly reducing the size of primary" tumors. Gli1 levels were up-regulated in tissue samples of metastatic human pancreatic cancer samples compared with matched primary tumors. Aldehyde dehydrogenase (ALDH) overexpression is characteristic for both hematopoietic progenitors and leukemic stem cells; cyclopamine preferentially reduced "ALDH-high" cells by approximately 3-fold (P = 0.048). We confirm pharmacologic Hh pathway inhibition as a valid therapeutic strategy for pancreatic cancer and show for the first time its particular efficacy against metastatic spread. By targeting specific cellular subpopulations likely involved in tumor initiation at metastatic sites� View Publication

Although natural killer (NK) cells are well known for their ability to kill tumors,few studies have addressed the interactions between resting (nonactivated) NK cells and freshly isolated human tumors. Here,we show that human leukocyte antigen class I(low) tumor cells isolated directly from patients with advanced ovarian carcinoma trigger degranulation by resting allogeneic NK cells. This was paralleled by induction of granzyme B and caspase-6 activities in the tumor cells and significant tumor cell lysis. Ovarian carcinoma cells displayed ubiquitous expression of the DNAX accessory molecule-1 (DNAM-1) ligand PVR and sparse/heterogeneous expression of the NKG2D ligands MICA/MICB and ULBP1,ULBP2,and ULBP3. In line with the NK receptor ligand expression profiles,antibody-mediated blockade of activating receptor pathways revealed a dominant role for DNAM-1 and a complementary contribution of NKG2D signaling in tumor cell recognition. These results show that resting NK cells are capable of directly recognizing freshly isolated human tumor cells and identify ovarian carcinoma as a potential target for adoptive NK cell-based immunotherapy. View Publication

Cross-linked human leukocyte antigen (HLA) class I molecules have been shown to mediate cell death in neoplastic lymphoid cells. However,clinical application of an anti-HLA class I antibody is limited by possible side effects due to widespread expression of HLA class I molecules in normal tissues. To reduce the unwanted Fc-mediated functions of the therapeutic antibody,we have developed a recombinant single-chain Fv diabody (2D7-DB) specific to the alpha2 domain of HLA-A. Here,we show that 2D7-DB specifically induces multiple myeloma cell death in the bone marrow environment. Both multiple myeloma cell lines and primary multiple myeloma cells expressed HLA-A at higher levels than normal myeloid cells,lymphocytes,or hematopoietic stem cells. 2D7-DB rapidly induced Rho activation and robust actin aggregation that led to caspase-independent death in multiple myeloma cells. This cell death was completely blocked by Rho GTPase inhibitors,suggesting that Rho-induced actin aggregation is crucial for mediating multiple myeloma cell death. Conversely,2D7-DB neither triggered Rho-mediated actin aggregation nor induced cell death in normal bone marrow cells despite the expression of HLA-A. Treatment with IFNs,melphalan,or bortezomib enhanced multiple myeloma cell death induced by 2D7-DB. Furthermore,administration of 2D7-DB resulted in significant tumor regression in a xenograft model of human multiple myeloma. These results indicate that 2D7-DB acts on multiple myeloma cells differently from other bone marrow cells and thus provide the basis for a novel HLA class I-targeting therapy against multiple myeloma. View Publication

CTLs act as the effector arm of the cell-mediated immune system to kill undesirable cells. Two processes regulate these effector cells to prevent self reactivity: a thymic selection process that eliminates autoreactive clones and a multistage activation or priming process that endows them with a license to kill cognate target cells. Hitherto no subsequent regulatory restrictions have been ascribed for properly primed and activated CTLs that are licensed to kill. In this study we show that CTLs possess a novel postpriming regulatory mechanism(s) that influences the outcome of their encounter with cognate target cells. This mechanism gauges the degree of Ag density,whereupon reaching a certain threshold significant changes occur that induce anergy in the effector T cells. The biological consequences of this Ag-induced postpriming control includes alterations in the expression of cell surface molecules that control immunological synapse activity and cytokine profiles and induce retarded cell proliferation. Most profound is genome-wide microarray analysis that demonstrates changes in the expression of genes related to membrane potential,TCR signal transduction,energy metabolism,and cell cycle control. Thus,a discernible and unique gene expression signature for anergy as a response to high Ag density has been observed. Consequently,activated T cells possess properties of a self-referential sensory organ. These studies identify a new postpriming control mechanism of CTL with anergenic-like properties. This mechanism extends our understanding of the control of immune function and regulation such as peripheral tolerance,viral infections,antitumor immune responses,hypersensitivity,and autoimmunity. View Publication

We showed that resistance to severe hypoxia defines hierarchical levels within normal hematopoietic populations and that hypoxia modulates the balance between generation of progenitors and maintenance of hematopoietic stem cells (HSC) in favor of the latter. This study deals with the effects of hypoxia (0.1% oxygen) in vitro on Friend's murine erythroleukemia (MEL) cells,addressing the question of whether a clonal leukemia cell population comprise functionally different cell subsets characterized by different hypoxia resistance. To identify leukemia stem cells (LSC),we used the Culture Repopulating Ability (CRA) assay we developed to quantify in vitro stem cells capable of short-term reconstitution (STR). Hypoxia strongly inhibited the overall growth of MEL cell population,which,despite its clonality,comprised progenitors characterized by markedly different hypoxia-resistance. These included hypoxia-sensitive colony-forming cells and hypoxia-resistant STR-type LSC,capable of repopulating secondary liquid cultures of CRA assays,confirming what was previously shown for normal hematopoiesis. STR-type LSC were found capable not only of surviving in hypoxia but also of being mostly in cycle,in contrast with the fact that almost all hypoxia-surviving cells were growth-arrested and with what we previously found for HSC. However,quiescent LSC were also detected,capable of delayed culture repopulation with the same efficiency as STR-like LSC. The fact that even quiescent LSC,believed to sustain minimal residual disease in vivo,were found within the MEL cells indicates that all main components of leukemia cell populations may be present within clonal cell lines,which are therefore suitable to study the sensitivity of individual components to treatments. Disclosure of potential conflicts of interest is found at the end of this article. View Publication

Mutations in the RUNX1 gene are found at high frequencies in minimally differentiated acute myelogenous leukemia. In addition to null mutations,many of the mutations generate Runx1 DNA-binding (RDB) mutants. To determine if these mutants antagonize wild-type protein activity,cDNAs were transduced into murine bone marrow or human cord blood cells using retroviral vectors. Significantly,the RDB mutants did not act in a transdominant fashion in vivo to disrupt Runx1 activity in either T-cell or platelet development,which are highly sensitive to Runx1 dosage. However,RDB mutant expression impaired expansion and differentiation of the erythroid compartment in which Runx1 expression is normally down-regulated,showing that a RDB-independent function is incompatible with erythroid differentiation. Significantly,both bone marrow progenitors expressing RDB mutants or deficient for Runx1 showed increased replating efficiencies in vitro,accompanied by the accumulation of myeloblasts and dysplastic progenitors,but the effect was more pronounced in RDB cultures. Disruption of the interface that binds CBFbeta,an important cofactor of Runx1,did not impair RDB mutant replating activity,arguing against inactivation of Runx1 function by CBFbeta sequestration. We propose that RDB mutants antagonize Runx1 function in early progenitors by disrupting a critical balance between DNA-binding-independent and DNA-binding-dependent signaling. View Publication