A Mouse Model of Evi1-Related Leukemia.

Abstract 1958 Poster Board I-981 Background: Evi1 gene is located on chromosome 3q26 and aberrantly expressed in acute myeloid leukemia (AML) patients with or without 3q26 abnormalities, and inappropriate expression of Evi1 associates with poor prognosis. Evi-1 is originally identified in a common integration site of murine leukemia retrovirus and enhanced expression of Evi1 by retrovirus integration is thought to be responsible for leukemogenesis in mouse models. However, retroviral expression of marker genes such as GFP has not induced leukemia even if some clones possessing integration at Evi1 site have been identified. These data indicate that Evi1 requires cooperative factors to induce progressive leukemia, whereas overexpression of Evi1 is enough to lead to clonal expansion of hematopoietic cells. Therefore, identifying genes collaborating with Evi1 is one of the key issues of understanding Evi1-related leukemogenesis. Recently, we demonstrated that a point mutation of the transcription factor AML1 (AML1-D171N) can induce myelodysplastic syndrome (MDS) that progresses to AML in association with overexpression of Evi1 through a mouse bone marrow transplantation model. In that work, we analyzed mice transplanted with BM cells transduced Evi1 alone as control and surprisingly confirmed that all of the mice developed leukemia within 6-11 months after the transplant. In this report, we will describe interesting findings in the novel mouse model of Evi1-induced leukemia. Result: C57BL6/Ly-5.1 murine BM cells infected with retroviruses harboring Evi1 were transplanted into irradiated syngeneic Ly-5.2 mice. The mice looked fine until 5 months, but GFP-positive-Evi1 expressing cells were gradually increased in the peripheral blood (PB), and then the mice died at 6-11 months after the transplantation. The mice showed dysplastic features in myeloid and erythroid cells, increase of blasts in the PB and the BM, hepatosplenomegaly, slight anemia, and some of the mice showed severe leukocytosis. The mice were thought to die of multiple organ failure due to invasion of leukemic cells not due to anemia. The phenotype is different from that of the mouse BMT model expressing Evi1 by retrovirus reported by another group, in which the mice died about 10 months with severe peripheral cytopenia and finally the disease did not progress to AML. Therefore, we considered that Evi1 might have collaborated with unknown genes near retrovirus integration sites in our case and analyzed integration sites by the bubble PCR method. Interestingly, frequent integration at 3' side of C/EBPb gene was found in six mice out of eight mice transplanted with Evi1-transduced BM cells. The integrations were located at 62.5-86.7kb downstream of C/EBPb gene. Next, we examined the expression level of C/EBPb, Tmem189, and Ptpn1, all of which are located near the integration site, and confirmed that C/EBPb showed elevated expression although neither Tmem189 nor Ptpn1 did. We also identified Bcas1, Rps6ka1, and Rapgef4 genes at the retroviral integration site in the other two mice without integration near C/EBPb. Discussion: C/EBPb, also known as NF-IL6, is a transcription factor that specifically binds to an IL1-responsive element in the IL-6 gene and has a role in regulation not only for the IL-6 gene but also for several cytokine genes such as TNF, IL-8, and G-CSF. The hematopoietic progenitor cells of C/EBPb-deficient mice have been reported to respond imperfectly to GM-CSF and G-CSF. Furthermore, C/EBPb is a downstream target of the Ras-Raf pathway. The locus of C/EBPb gene has been reported as a common integration site in the Retrovirus Tagged Cancer Gene Database (RTCGD), which is a database of retroviral insertional mutagenesis in mouse tumors. AKxD mice, Cdkn2a-KO mice, NUP98/HOXD13 transgenic mice, and MYC/Runx2 transgenic mice were reported to develop myeloid or lymphoid leukemia by retroviral insertion into 3' side of C/EBPb gene. In this study, we identified frequent integration at 3' side of C/EBPb gene in Evi1-transduced leukemic cells, whereas we have not identified this locus in AML1-mutants-transduced leukemic cells. Based on these findings and our results, C/EBPb is supposed to be a candidate gene to collaborate with Evi1 in leukemogenesis. Conclusion: We identified involvement of C/EBPb in Evi1-induced leukemogenesis. The novel mouse model that we generated in this study could help understanding the molecular basis of Evi1-related leukemia. Disclosures: No relevant conflicts of interest to declare.

Unaltered repopulation properties of mouse hematopoietic stem cells transduced with lentiviral vectors

Recent studies of retroviral-mediated gene transfer have shown that retroviral integrations themselves may trigger nonmalignant clonal expansion of hematopoietic stem cells (HSCs) in transplant recipients. These observations suggested that previous conclusions of HSC dynamics based on gamma-retroviral gene marking should be confirmed with improved vectors having a more limited capacity to transactivate endogenous genes. Because of the low trans-activation activity of self-inactivating lentiviral vectors (LVs), we have investigated whether the LV marking of mouse HSCs induces a competitive repopulation advantage in recipients of serially transplants. As deduced from analyses conducted in primary and secondary recipients, we concluded that lentivirally transduced HSCs have no competitive repopulation advantages over untransduced HSCs. By linear amplification-mediated polymerase chain reaction (LAM-PCR) analysis, we characterized LV-targeted genes in HSC clones that engrafted up to quaternary recipients. Although 9 clones harbored integrations close to defined retroviral insertion sites, none was characterized as a common integration site, and none was present in HSC clones repopulating quaternary recipients. Taken together, our results show unaltered repopulation properties of HSCs transduced with LVs, and confirm early studies suggesting the natural capacity of a few HSC clones to generate a monoclonal or oligoclonal hematopoiesis in transplant recipients.

Radiation Leukemia Virus Common Integration at the Kis2 Locus: Simultaneous Overexpression of a Novel Noncoding RNA and of the Proximal Phf6 Gene

ABSTRACT Retroviral tagging has been used extensively and successfully to identify genes implicated in cancer pathways. In order to find oncogenes implicated in T-cell leukemia, we used the highly leukemogenic radiation leukemia retrovirus VL3 (RadLV/VL3). We applied the inverted PCR technique to isolate and analyze sequences flanking proviral integrations in RadLV/VL3-induced T lymphomas. We found retroviral integrations in c-myc and Pim1 as already reported but we also identified for the first time Notch1 as a RadLV common integration site. More interestingly, we found a new RadLV common integration site that is situated on mouse chromosome X (XA4 region, bp 45091000). This site has also been reported as an SL3-3 and Moloney murine leukemia virus integration site, which strengthens its implication in murine leukemia virus-induced T lymphomas. This locus, named Kis2 (Kaplan Integration Site 2), was found rearranged in 11% of the tumors analyzed. In this article, we report not only the alteration of the Kis2 gene located nearby in response to RadLV integration but also the induction of the expression of Phf6, situated about 250 kbp from the integration site. The Kis2 gene encodes five different alternatively spliced noncoding RNAs and the Phf6 gene codes for a 365-amino-acid protein which contains two plant homology domain fingers, recently implicated in the Börjeson-Forssman-Lehmann syndrome in humans. With the recent release of the mouse genome sequence, high-throughput retroviral tagging emerges as a powerful tool in the quest for oncogenes. It also allows the analysis of large DNA regions surrounding the integration locus.

A New Common Integration Site, Int7, for the Mouse Mammary Tumor Virus in Mouse Mammary Tumors Identifies a Gene Whose Product Has Furin-Like and Thrombospondin-Like Sequences

ABSTRACT A novel common integration site for the mouse mammary tumor virus (MMTV) was identified (designated Int7) in five independently arising mouse mammary tumors. The insertion sites all cluster within a 1-kb region that is 2 to 3 kb 5′ of the transcription initiation site of a gene, 2610028F08RIK, whose gene product contains furin-like and thrombospondin-like sequences. Expression of Int7 is normally very low or silent during various stages of mammary gland development, but MMTV integration at this site results in the activation of high steady-state levels of expression of the gene. These five tumors were also found to have two or three additional viral insertions, which in each case occurred flanking a member of either the Wnt and/or FGF gene family. Reverse transcriptase PCR results demonstrated that each of the viral insertions led to elevated expression of the presumed target flanking genes.

Rorγ (Rorc) Is a Common Integration Site in Type B Leukemogenic Virus-Induced T-Cell Lymphomas

ABSTRACT The retrovirus type B leukemogenic virus (TBLV) causes T-cell lymphomas in mice. We have identified the Rorγ locus as an integration site in 19% of TBLV-induced tumors. Overexpression of one or more Rorγ isoforms in >77% of the tumors tested may complement apoptotic effects of c-myc overexpression.

Gris1, a New Common Integration Site in Graffi Murine Leukemia Virus-Induced Leukemias: Overexpression of a Truncated Cyclin D2 due to Alternative Splicing

ABSTRACT The Graffi murine leukemia virus is a nondefective ecotropic retrovirus that was originally reported to induce myeloid leukemia in some strains of mice (A. Graffi, Ann. N.Y. Acad. Sci. 68:540-558, 1957). Using provirus-flanking sequences as DNA probes, we identified a new common retroviral integration site called Gris1 (for Graffi integration site 1). Viral integrations in Gris1 were detected in 13% of the tumors analyzed. The Gris1 locus was mapped to the distal region of mouse chromosome 6, 85 kb upstream of the cyclin D2 gene. Such viral integration in Gris1 causes overexpression of the normal 6.5-kb major transcript of cyclin D2 but also induces the expression of a new, alternatively spliced 1.1-kb transcript from the cyclin D2 gene that encodes a truncated cyclin D2 of 17 kDa. The expression of this 1.1-kb transcript is specific to tumors in which Gris1 is rearranged but is also detected at low levels in normal tissue.