Juerg Schwaller

Stat5 Is Essential for the Myelo- and Lymphoproliferative Disease Induced by TEL/JAK2

STAT5 is activated in a broad spectrum of human hematologic malignancies. We addressed whether STAT5 activation is necessary for the myelo- and lymphoproliferative disease induced by TEL/JAK2 using a genetic approach. Whereas mice transplanted with bone marrow transduced with retrovirus expressing TEL/JAK2 develop a rapidly fatal myelo- and lymphoproliferative syndrome, reconstitution with bone marrow derived from Stat5ab-deficient mice expressing TEL/JAK2 did not induce disease. Disease induction in the Stat5a/b-deficient background was rescued with a bicistronic retrovirus encoding TEL/JAK2 and Stat5a. Furthermore, myeloproliferative disease was induced by reconstitution with bone marrow cells expressing a constitutively active mutant, Stat5a, or a single Stat5a target, murine oncostatin M (mOSM). These data define a critical role for Stat5a/b and mOSM in the pathogenesis of TEL/JAK2 disease.

Socs-1 Inhibits TEL-JAK2-Mediated Transformation of Hematopoietic Cells through Inhibition of JAK2 Kinase Activity and Induction of Proteasome-Mediated Degradation

ABSTRACT TEL-JAK2 fusion proteins, which are a result of t(9;12)(p24;p13) translocations associated with human leukemia, activate Stat5 in vitro and in vivo and cause a myelo- and lymphoproliferative disease in a murine bone marrow transplant model. We report that Socs-1, a member of the SOCS family of endogenous inhibitors of JAKs and STATs, inhibits transformation of Ba/F3 cells by TEL-JAK2 but has no effect on Ba/F3 cells transformed by BCR-ABL, TEL-ABL, or TEL–platelet-derived growth factor receptor beta. TEL-JAK2, in addition to activating Stat5, associates with Shc and Grb2 and induces activation of Erk2, and expression of Socs-1 inhibits engagement of each of these signaling molecules. TEL-JAK2 kinase activity is inhibited by Socs-1, as assessed by in vitro kinase assays. In addition, Socs-1 induces proteasomal degradation of TEL-JAK2. Mutational analysis indicates that the SOCS box of Socs-1 is required for proteasomal degradation and for abrogation of growth of TEL-JAK2-transformed cells. Furthermore, murine bone marrow transplant assays demonstrate that expression of Socs-1 prolongs latency of TEL-JAK2-mediated disease in vivo. Collectively, these data indicate that Socs-1 inhibits TEL-JAK2 in vitro and in vivo through inhibition of kinase activity and induction of TEL-JAK2 protein degradation.

The expression of ETV6/CBFA2 (TEL/AML1) is not sufficient for the transformation of hematopoietic cell lines in vitro or the induction of hematologic disease in vivo

ETV6/CBFA2 (TEL/AML1) is the most frequent genetic abnormality associated with acute lymphoblastic leukemias in children, and is associated with a favorable prognosis. To investigate the influence of ETV6/CBFA2 on cellular transformation, the fusion gene was cloned into a murine ecotropic retroviral vector and transduced into IL-3-dependent Ba/F3 and 32Dcl.3 and IL-7-dependent IxN/2b murine hematopoietic cell lines. Different variants of ETV6/CBFA2, corresponding to CBFA2 alternatively spliced variants, and the reciprocal product CBFA2/ETV6, were stably expressed in each of these cell lines. However, although Western blot analysis demonstrated expression of each variant, none of the stable cell lines expressing CBFA2/ETV6 or the variants conferred factor-independent growth. We further investigated the effect of ETV6/CBFA2 expression in vivo by generating transgenic mice in which expression of the fusion was directed to lymphoid cells using the immunoglobulin heavy chain enhancer/promoter. Four founder mice were identified showing transmission and expression of the chimeric product. The mice were bred for five generations and followed for more than 24 months. The mice did not develop a malignant hematologic disorder, nor did they display histopathologic, morphologic, or immunophenotypic abnormalities, although ETV6/CBFA2 expression was confirmed in each line. We conclude that the expression of ETV6/CBFA2 alone is not sufficient for induction of growth factor independence in hematopoietic cell lines or hematologic disease in transgenic mice.

Signal transduction and transforming properties of the TEL–TRKC fusions associated with t(12;15)(p13;q25) in congenital fibrosarcoma and acute myelogenous leukemia

The TEL–TRKC fusion is expressed as a consequence of t(12;15)(p13;q25), and is associated with two human cancers: congenital fibrosarcoma and acute myelogenous leukemia (AML). We report that the T/T(F) and T/T(L) fusion variants associated with congenital fibrosarcoma and AML, respectively, are constitutively tyrosine phosphorylated, and confer factor‐independent growth to the murine hematopoietic cell line Ba/F3. Retroviral transduction of T/T(L) causes a rapidly fatal myeloproliferative disease in a murine bone marrow transplant (BMT) model, whereas T/T(F) causes a long‐latency, pre‐B‐cell lymphoblastic lymphoma. TEL–TRKC variants are potent activators of the MAP kinase pathway, but neither variant activates Stat5 or other Stat family members. T/T(L), but not T/T(F), induces tyrosine phosphorylation of phospholipase Cγ (PLCγ), phosphoinositol‐3 kinase and SHC. However, mutation analysis demonstrates that PLCγ tyrosine phos phorylation by T/T(L) is dispensable for induction of the myeloproliferative phenotype by T/T(L). Collectively, these data demonstrate that the TEL–TRKC fusion variants are oncoproteins that activate the MAP kinase pathway, and do not require activation of either PLCγ or Stat5 for efficient induction of a myeloproliferative phenotype in the murine BMT model.

Leukemogenic mechanisms and targets of a NUP98/HHEX fusion in acute myeloid leukemia

We have studied a patient with acute myeloid leukemia (AML) and t(10;11)(q23;p15) as the sole cytogenetic abnormality. Molecular analysis revealed a translocation involving nucleoporin 98 (NUP98) fused to the DNA-binding domain of the hematopoietically expressed homeobox gene (HHEX). Expression of NUP98/HHEX in murine bone marrow cells leads to aberrant self-renewal and a block in normal differentiation that depends on the integrity of the NUP98 GFLG repeats and the HHEX homeodomain. Transplantation of bone marrow cells expressing NUP98/HHEX leads to transplantable acute leukemia characterized by extensive infiltration of leukemic blasts expressing myeloid markers (Gr1(+)) as well as markers of the B-cell lineage (B220(+)). A latency period of 9 months and its clonal character suggest that NUP98/HHEX is necessary but not sufficient for disease induction. Expression of EGFP-NUP98/HHEX fusions showed a highly similar nuclear localization pattern as for other NUP98/homeodomain fusions, such as NUP98/HOXA9. Comparative gene expression profiling in primary bone marrow cells provided evidence for the presence of common targets in cells expressing NUP98/HOXA9 or NUP98/HHEX. Some of these genes (Hoxa5, Hoxa9, Flt3) are deregulated in NUP98/HHEX-induced murine leukemia as well as in human blasts carrying this fusion and might represent bona fide therapeutic targets.

Role of constitutively activated protein tyrosine kinases in malignant myeloproliferative disorders: an update.

Modern molecular technology helped identify more than 10 protein tyrosine kinases related to myeloid malignancies, which allowed the development of small molecule inhibitors targeting deregulated protein tyrosine kinase activity. Protein tyrosine kinase deregulation can occur as a consequence of fusion gene formation because of chromosomal translocations, or as distinct gain-of-function point mutations. Although the tyrosine kinase inhibitor imatinib mesylate (Gleevec) targeting the ABL protein tyrosine kinase has revolutionized current chronic myeloid leukemia therapy, it became rapidly evident that overcoming the multiple cellular resistance mechanisms will be very challenging. To develop efficient therapeutic alternatives, one must understand the complex signal transduction mechanisms involved in transformation by deregulated protein tyrosine kinases. This article reviews the most recently identified molecular mechanisms involved in cell transformation by the BCR/ABL protein tyrosine kinase fusion and presents new members of the increasing family of deregulated protein tyrosine kinases involved in myeloproliferative disorders. In addition, the article discusses new, promising small molecule protein tyrosine kinase inhibitors and the molecular mechanism that may lead to resistance to these drugs. Finally, the article highlights putative alternative strategies that could be used to block signal transduction pathways of deregulated protein tyrosine kinase activity.

The hematopoietic precursor cell in which driver mutations occur is linked to AML aggressiveness – a potential target for personalized medicine

Acute myeloid leukemia (AML) is a clinically and biologically heterogeneous disease. The shift from a stochastic concept toward a more hierarchic organization of AML driven by a small population of cells, also referred to as leukemic stem cells, raised the interest to better understand the role of cellular origin. Recent studies combining novel inducible transgenic mouse models with comparative cross-species transcriptomics suggested that in most cases AML originates from a continuum of early multipotent to differentiated hematopoietic progenitor cells [1,2]. These observations indicated that in about 10–20% of AML patients, the disease might originate from hematopoietic stem cells (HSCs) not strictly related to the presence of a particular leukemogenic driver mutation. The cellular origin may add to the wide heterogeneity and genetic complexity of AML as modeling of HSC-derived AML in mice resulted in a more invasive and drug-resistant phenotype than the AML originating from mature progenitors and this was associated with genetic signatures that characterized human AML with poor outcome [2,3]. Increasing evidence indicates that HSCs are a rather functionally heterogeneous cell population [4]. Thus, distinct HSC subtypes or states may be particularly susceptible for transformation by distinct leukemia driver mutations. Modeling the effects of mutations associated with preleukemic states and/or potential leukemia drivers in different HSC or early progenitors may be essential for targeting these origin-related aggressive and drug-resistant leukemic stem cells.