ALBERT

Description: Background In advanced human malignancies, RNA sequencing (RNA-seq) has uncovered deregulation of adenosine deaminase acting on RNA (ADAR) editases that promote therapeutic resistance and leukemia stem cell (LSC) generation. Chronic myeloid leukemia (CML), an important paradigm for understanding LSC evolution, is initiated by BCR-ABL1 oncogene expression in hematopoietic stem cells (HSCs) but undergoes blast crisis (BC) transformation following aberrant self-renewal acquisition by myeloid progenitors harboring cytokine-responsive ADAR1 p150 overexpression. Emerging evidence suggests that adenosine to inosine editing at the level of primary (pri) or precursor (pre)-microRNA (miRNA), alters miRNA biogenesis and impairs biogenesis. However, relatively little is known about the role of inflammatory niche-driven ADAR1 miRNA editing in malignant reprogramming of progenitors into self-renewing LSCs. Methods Primary normal and CML progenitors were FACS-purified and RNA-Seq analysis as well as qRT-PCR validation were performed according to published methods (Jiang, 2013). MiRNAs were extracted from purified CD34+ cells derived from CP, BC CML and cord blood by RNeasy microKit (QIAGEN) and let-7 expression was evaluated by qRT-PCR using miScript Primer assay (QIAGEN). CD34+ cord blood (n=3) were transduced with lentiviral human JAK2, let-7a, wt-ADAR1 and mutant ADAR1, which lacks a functional deaminase domain. Because STAT signaling triggers ADAR1 transcriptional activation and both BCR-ABL1 and JAK2 activate STAT5a, nanoproteomics analysis of STAT5a levels was performed. Engrafted immunocompromised RAG2-/-γc-/- mice were treated with a JAK2 inhibitor, SAR302503, alone or in combination with a potent BCR-ABL1 TKI Dasatinib, for two weeks followed by FACS analysis of human progenitor engraftment in hematopoietic tissues and serial transplantation. Results RNA-seq and qRT-PCR analysis in FACS purified BC CML progenitors revealed an over-representation of inflammatory pathway activation and higher levels of JAK2-dependent inflammatory cytokine receptors, when compared to normal and chronic phase (CP) progenitors. Moreover, RNA-seq and qRT-PCR analysis showed decreased levels of mature let-7 family of stem cell regulatory miRNA in BC compared to normal and CP progenitors. Lentiviral human JAK2 transduction of CD34+ progenitors led to an increase of ADAR1 transcript levels and to a reduction in let-7 family members. Interestingly, lentiviral human JAK2 transduction of normal progenitors enhanced ADAR1 activity, as revealed by RNA editing-specific qRT-PCR and RNA-seq analysis. Moreover, qRT-PCR analysis of CD34+ progenitors transduced with wt-ADAR1, but not mutant ADAR1 lacking functional deaminase activity, reduced let-7 miRNA levels. These data suggested that ADAR1 impairs let-7 family biogenesis in a RNA editing dependent manner. Interestingly, RNA-seq analysis confirmed higher frequency of A-to-I editing events in pri- and pre-let-7 family members in CD34+ BC compared to CP progenitors, as well as normal progenitors transduced with human JAK2 and ADAR1-wt, but not mutant ADAR1. Lentiviral ADAR1 overexpression enhanced CP CML progenitor self-renewal and decreased levels of some members of the let-7 family. In contrast, lentiviral transduction of human let-7a significantly reduced self-renewal of progenitors. In vivo treatments with Dasatinib in combination with a JAK2 inhibitor, significantly reduced self-renewal of BCR-ABL1 expressing BC progenitors in the bone marrow thereby prolonging survival of serially transplanted mice. Finally, a reduction in ADAR1 p150 transcripts was also noted following combination treatment only suggesting a role for ADAR1 in CSC propagation. Conclusion This is the first demonstration that intrinsic BCR-ABL oncogenic signaling and extrinsic cytokines signaling through JAK2 converge on activation of ADAR1 that drives LSC generation by impairing let-7 miRNA biogenesis. Targeted reversal of ADAR1-mediated miRNA editing may enhance eradication of inflammatory niche resident cancer stem cells in a broad array of malignancies, including JAK2-driven myeloproliferative neoplasms. Disclosures Jamieson: J&J: Research Funding; GSK: Research Funding.

Description: Chronic myeloid leukemia (CML) represents an important paradigm for identifying the molecular events that promote malignant reprogramming of progenitors into therapeutically recalcitrant leukemia stem cells (LSC) during blast crisis (BC) transformation. To elucidate mechanisms of human BC LSC generation, whole transcriptome RNA sequencing (RNA Seq), lentiviral BCR-ABL and JAK2 transduction, quantitative RT-PCR (qRT-PCR) and serial xenotransplantation studies were performed. In human BC LSC, RNA seq revealed extensive upregulation of inflammation-responsive genes in conjunction with JAK/STAT signaling pathway activation and splice isoform specific qRT-PCR uncovered a predilection for selective STAT5a isoform expression. While lentiviral BCR-ABL1 expression in cord blood progenitors enhanced JAK2 activation and expression of specific STAT5a splice isoforms, lentiviral human JAK2 overexpression globally activated inflammation-response genes and expression of adenosine deaminase RNA associated (ADAR1), a primate specific RNA editase previously shown to activate self-renewal in response to inflammation. Notably, inhibition of BC LSC self-renewal with dasatinib, a BCR-ABL inhibitor, combined with a potent JAK2 inhibitor, SAR302503, was associated with reduced STAT5a isoform expression and phospho-STAT5 activation as well as ADAR1 expression and activity. These results highlight a novel JAK/STAT pathway driven niche-responsive mechanism of human BC LSC generation that can be targeted, at least in part, with a selective JAK2 inhibitor and may be utilized as an RNA editing-based biomarker of cancer stem cell generation and therapeutic resistance. Disclosures: Jamieson: Sanofi: Consultancy.

Description: Introduction Human bone marrow aging is typified by decreased cellularity, stem cell exhaustion and myeloid lineage bias that may set the stage for development of myeloid malignancies. Secondary AML (sAML) arises from prior myelodysplastic syndromes (MDS) or myeloproliferative neoplasms (MPN), and occurs in patients with an average age of 〉65. Because of the typically advanced age of this population, patients currently have few effective treatment options available after leukemic transformation. We and others have recently identified a key role for enzymatic RNA editing activity in cancer progression, and in particular in leukemia stem cell (LSC) generation. In hematopoietic stem and progenitor cells, adenosine deaminase acting on dsRNA-1 (ADAR1) is the most abundantly expressed RNA editing gene. However, the role of abnormal RNA editing activity has not been elucidated in healthy human bone marrow aging and age-related MDS with a high risk of transforming to sAML. Therefore, we established whole transcriptome-based RNA editing signatures of benign versus malignant bone marrow progenitor cell aging, which provides novel RNA-based functionally relevant biomarkers of aging, MDS and progression to sAML. Methods Whole transcriptome sequencing (RNA-Seq) was performed on FACS-purified hematopoietic stem (CD34+CD38-Lin- HSC) and progenitor cells (CD34+CD38+Lin- HPC) from aged (average age = 65.9 y/o) versus young (average age = 25.8 y/o) adult healthy bone marrow samples, and in leukemia stem cells (LSC) from patients with sAML (average age = 71.4 y/o) and MDS (average age = 63.8 y/o). Comparative gene set enrichment analyses (GSEA) and RNA editing profiles were identified for normal and malignant progenitor cell aging. Results Aberrant RNA editing activity has recently been shown to be induced in multiple cancers, and has been implicated as a malignant reprogramming factor. Comparative whole transcriptome RNA sequencing (RNA-seq) and single nucleotide variant analyses revealed widespread increases in RNA editing rates in aged versus young HPC, and in human sAML LSC compared with age-matched normal progenitors. Moreover, RNA editing rates, represented as adenosine (A) to inosine/guanosine (G) changes at known RNA editing loci, were increased in sAML compared with MDS progenitors. The differential expression of certain sites is as high as 70%, which can be readily detected by RESS-qPCR. These data suggest that during aging niche-dependent RNA editing deregulation contributes to MDS progression to sAML. Interestingly, the highly edited loci in sAML LSC were distinct from loci that were differentially edited in aged versus young HPC, suggesting that pro-inflammatory conditions in sAML may trigger RNA editing of a unique set of transcripts, including predominantly RNA processing-related gene products and transcription factors. Notably, several loci in transcripts of APOBEC3C/D that we previously found were associated with blast crisis transformation of chronic myeloid leukemia also displayed enhanced editing in sAML LSC, but not aged versus young HPC. Conclusions Detection of aberrant RNA processing provides novel biomarkers as well as potential therapeutic targets for sAML LSC eradication with implications for treatment of a variety of human malignancies and other age-related disorders. We have identified commonly RNA-edited transcripts in multiple hematologic malignancies, which could be developed clinically and as companion diagnostic targets for LSC-targeted therapeutics. Disclosures Jamieson: CTI Biopharma: Research Funding; Johnson & Johnson: Research Funding; GlaxoSmithKline: Research Funding.

Description: Abstract 2772 While advanced malignancies in Chronic Myeoloid Leukemia (CML) are diverse in phenotype, they often exhibit stem cell properties including enhanced survival, quiescence and self-renewal potential. The molecular etiology of human progenitor reprogramming into self-renewing leukemia stem cells (LSC) has remained elusive. While DNA sequencing has uncovered spliceosome gene mutations that promote alternative splicing and portend leukemic transformation, isoform diversity may also be generated by aberrant RNA editing mediated by adenosine deaminase acting on dsRNA (ADAR) family, which have been shown to promote an embryonic transcriptional program and regulate fetal and adult hematopoietic stem cell (HSC) self-renewal as well as stem cell responses to inflammation. In this study, whole transcriptome sequencing of normal, chronic phase (CP) and functionally validated blast crisis (BC) chronic myeloid leukemia (CML) progenitors revealed increased inflammatory pathway gene expression in concert with BCR-ABL amplification, enhanced expression of interferon-responsive ADAR1 and a propensity for increased A-to-I RNA editing during CML progression. Mechanistic studies demonstrated that lentivirally enforced ADAR1 p150 expression induced expression of the myeloid-skewing transcription factor PU.1 and skewed cell fate towards granulocyte-macrophage progenitors - the initiating LSC population in BC CML. Moreover, lentiviral ADAR1 knockdown reduced BC LSC self-renewal capacity in RAG2−/−gc−/− mice. These data shed new light on the role of ADAR1-directed RNA editing in myeloid progenitor reprogramming and self-renewal potential of malignant progenitors that drive disease progression and therapeutic resistance in CML, and provide a compelling rationale for developing ADAR1-based LSC detection and eradication strategies. Disclosures: No relevant conflicts of interest to declare.

Description: Introduction Chronic myeloid leukemia (CML) was one of the first malignancies shown to be initiated in hematopoietic stem cells by the BCR-ABL1 oncogene and sustained in blast crisis (BC) by progenitor cells that co-opt stem cell properties and behave like leukemia stem cells (BC LSCs). The BCR-ABL fusion oncogene encodes a constitutively active tyrosine kinase BCR-ABL. Although tyrosine kinase inhibitor (TKI) therapy targeting BCR-ABL suppresses CML during the chronic phase (CP), progenitors undergo expansion as a consequence of subsequent genetic and epigenetic alterations that fuel blast crisis transformation, BC LSC generation and TKI resistance. Self-renewing human BC LSCs harbor increased expression of Inflammation responsive adenosine deaminase acting on RNA (ADAR1), which can alter transcript as well as microRNA (miRNA) maturation, splicing and translation by Adenosine (A)-to-Inosine (I) editing of double stranded RNA. miRNAs are a family of small non-coding RNA molecules that regulate gene expression at a post-transcriptional level by inhibiting protein translation and/or reducing mRNA stability. Eukaryotic cells employ miRNAs in diverse biological processes including cell proliferation, differentiation, pluripotency and self-renewal. The stem cell pluripotency RNA binding protein LIN28B plays critical roles in BC transformation of CML. In this study we sought to characterize CML related-oncogenes, such as BCR-ABL, JAK2 and ADAR1, alone or in stromal co-culture in terms of their ability to regulate LSC self-renewal through modulation of let-7 /LIN28B stem cell transcriptional regulatory axis. Methods MiRNAs were extracted from purified CD34+ cells derived from CP and BC CML patient samples as well as cord blood by RNeasy microKit (QIAGEN) and let-7 expression was evaluated by qRT-PCR using miScript Primer assay (QIAGEN). CD34+ cord blood (n=3) were transduced with lentiviral human BCR-ABL, JAK2, let-7a, wild type ADAR1 and ADAR1 mutant, which lacks a functional deaminase domain. Then, 72 hours after transduction, lentivirally transduced cells were plated on irradiated SL/M2 cells. After 5 days of culture, cells were collected for RNA and microRNA extraction. Transduction efficiency and LIN28B levels were evaluated by qRT-PCR and let-7 expression was quantified by qRT-PCR using miScript primer assay. Hematopoietic Progenitor and Replating assaywere performed on lenti-let-7a-overexpressing CB cells to assess differentiation, survival and self-renewal capacity. Results Lentiviral overexpression of human BCR-ABL in CD34+ CB did not induce any significant change in let-7 family members and LIN28B expression in absence of stromal co-culture. However, stromal co-culture of BCR-ABL overexpressing CB led to the significant downregulation of members of the let-7 family as well as to upregulation of their target gene LIN28B, thus suggesting that extrinsic microenvironmental cues are necessary for modulating let-7 family levels in presence of BCR-ABL. Notably, qRT-PCR of CB transduced with JAK2 showed significant upregulation of ADAR1 in the absence of stroma, thus suggesting that JAK2 might be a mediator of inflammatory cytokine-driven ADAR1 activation. Lentiviral overexpression of both human JAK2 and ADAR1 significantly reduced the expression of let-7 family members and induced up-regulation of LIN28B. Interestingly, lentiviral overexpression of ADAR1 mutant did not induce any significant change in most let-7 family members. Finally, lentiviral overexpression of let-7a induced significant reduction in survival and self-renewal. Conclusion These finding suggest that BCR-ABL requires extrinsic signals from the niche to modulate self-renewal of BC LSCs. Conversely, lentiviral JAK2 overexpression induces activation of aberrant RNA editing and subsequent reduction of let-7 family members in the absence of the niche. Interestingly, experiments with ADAR1 mutant, suggest that ADAR1 downregulates most of the let-7 family members in a RNA–editing dependent way manner. In summary these findings suggest a novel mechanism for BC LSC generation that may have utility in prognostication and selective LSCs targeting. Disclosures Jamieson: J&J: Research Funding; Sanofi: Research Funding, Travel Support, Travel Support Other; Roche: Research Funding.

Description: Abstract 1034 Introduction: T-cell acute lymphoblastic leukemia (T-ALL) is a therapeutically recalcitrant malignancy that accounts for approximately 15% of pediatric and 25% of adult ALL cases. In leukemia, cancer stem cells constitute a relatively rare population of tumor cells that play a key role in cancer propagation and, like adult stem cells, have enhanced self-renewal potential. A previous report showed that following in vitro culture, CD34+/CD4- and CD34+/CD7- subfractions of T-ALL marrow were enriched for leukemia stem cells (LSC) capable of engrafting leukemia in nonobese diabetic/severe combined immune deficient mouse (NOD/SCID). However, difficulties in maintaining primary cultures of leukemia cells hampered investigations into the biology of T-ALL underscoring the need for a direct transplantation model to characterize human LSC in vivo and as a paradigm for screening candidate drugs that inhibit self-renewal pathways active in T-ALL. Experimental Procedures: Quantitative RT-PCR of NOTCH target gene expression and NOTCH mutation DNA sequencing analysis was performed on human CD34+ cells from T-ALL patient samples (n =12). To develop a humanized mouse model of T-ALL, CD34+ progenitors were lentivirally transduced with GFP-Luciferase Fusion protein (GLF) and transplanted intrahepatically into neonatal T, B, and NK cell deficient mice. In some experiments, FACS purified CD34+ subpopulations were transplanted at limiting dilution, including CD34+CD38+CD2+Lin- cells. Leukemic engraftment was monitored by in vivo bioluminescence imaging and analyzed by FACS detection of human CD34+ cells in liver, bone marrow, spleen and thymus when mice were sacrificed at 8–10 weeks post-transplant. NOTCH1 target gene expression was analyzed by q-RT-PCR in human CD34+ cells derived from engrafted tissues and NOTCH mutation analysis was performed by DNA sequencing on the same population. To assay LSC self-renewal, engrafted human CD34+ cells from bone marrow were transplanted into secondary and tertiary recipients. In serially transplanted mice, NOTCH1 target gene expression, NOTCH1 receptor expression was analyzed by FACS and NICD expression was assessed in the bone marrow by immunohistochemistry. Results: Q-RT-PCR data showed that NOTCH1, HES1 and c-MYC expression correlated with NOTCH 1 mutation status as well as the emergence of a CD34+CD2+Lin- population not evident in normal cord blood. We transplanted 12 T-ALL patient samples with detectable Notch1 expression and 100% of samples engrafted RAG 2-/- gamma c-/- mice. Transplanted LSC could be tracked for 10 weeks after transplant by in vivo bioluminescent imaging while Lin+ engraftment declined. Human CD34+/CD45+ cells, CD45+/CD34+/CD38+/Lin−/CD2+ cells were found in the bone marrow, thymus, spleen of the engrafted mice at 9–10 weeks post transplant or the end of dosing. Finally, human CD34+ cells engrafted secondary and tertiary recipients with T-ALL demonstrating their propensity for self-renewal and differentiation. Notch1 target gene and Hes1 expression was higher in patients with Notch1 mutation identified by sequencing. Conclusion: Serially transplantable candidate LSC retain high level NOTCH1 target gene expression and may be uniquely susceptible to targeted NOTCH1 receptor inhibition. Disclosures: Jamieson: Pfizer: Research Funding.

Description: Innate immune anti-viral adenosine to inosine (A-to-I) base editing enzymes (editases) promote hematopoietic stem cell (HSC) self-renewal and protect the human genome from retroviral integration in response to inflammatory cytokine signaling. However, hyper-editing has been linked to therapeutic resistance and cancer progression. Because myeloproliferative neoplasm (MPN) progression is typified by increased JAK2/STAT-mediated cytokine signaling, we investigated the cell type and context specific role of adenosine deaminase acting on RNA1 (ADAR1) editaseactivity in MPN pre-leukemia stem cell (pre-LSC) evolution into acute myeloid leukemia stem cells (LSCs). Here we show by whole transcriptome sequencing (RNA-seq) of 113 FACS-purified hematopoietic stem cells and progenitors from 78 individuals, including 54 MPN and AML patients and 24healthy young and aged individuals, that anti-viral signaling pathway activation and splice isoform switching from ADAR1p110 to JAK2/STAT-inducible ADAR1p150 RNA editase activation contributes to MPN progression. Pre-LSC evolution to LSC was characterized by ADAR1p150 upregulation, distinctive RNA editome patterns, STAT3 hyper-editing, increased replating as a measure of self-renewal. Moreover, LSC generation was typified by beta-catenin self-renewal pathway upregulation, which was recapitulated by lentiviral ADAR1p150 overexpression and reversed by lentiviral ADAR1p150 shRNA knockdown. Our studyunderscores the importance of inflammatory-cytokine fueled enzymatic mutagenesis in human MPN pre-LSC evolution to LSC. Thus, this study sets the stage for developing predictive RNA editome biomarkers of LSC generation to guidetherapeutic strategies aimed at preventing progression of hematopoietic malignancies. Disclosures Crews: Ionis Pharmaceuticals: Research Funding.

Description: Abstract 516 Introduction: Several studies have demonstrated the role of leukemia stem cells (LSC) in the development and maintenance of human chronic myeloid leukemia (CML). These cells, which first develop in chronic phase CML (CP CML) with acquisition of the BCR-ABL fusion protein, are often quiescent and can be highly resistant to apoptosis induced by drugs and radiotherapy that target rapidly dividing cells. Data has also shown that CML LSC become increasingly resistant to BCR-ABL inhibition with progression to blast crisis CML (BC CML). Bcl-2 family proteins are key regulators of apoptosis and have been shown by numerous studies to regulate cancer resistance to chemotherapy. This family of proteins has also been implicated in the development of BC CML, however most studies have focused on CML cell lines and their expression of Bcl-2 family proteins in vitro. Thus, there is relatively little data on expression of Bcl-2 family proteins in primary CML LSC and on the role of these proteins in regulating chemotherapy resistance in CML LSC in vivo. As Bcl-2 family proteins are known regulators of chemotherapy resistance we hypothesized that human BC CML LSC may overexpress these proteins compared to normal hematopoietic stem cells. We analyzed Bcl-2 family mRNA and protein expression in CP CML and BC CML LSC and compared this expression to normal cord blood stem and progenitor cells. We also analyzed whether these cells were sensitive to chemotherapy treatment in vitro. Finally, we tested whether a high potency pan-Bcl-2 inhibitor, 97C1, could effectively kill CML LSC in vitro and in vivo. Methods: Bcl-2 and Mcl-1 protein expression was measured in primary CP CML, BC CML, and normal cord blood cells using intracellular FACS. We also measured Bcl-2, Mcl-1, Bcl-X, and Bfl-1 mRNA expression in FACS sorted CD34+CD38+lin− cells (LSC) from these samples. For all drug studies we used either serially transplanted CD34+ cells derived from primary BC CML patient samples or primary CD34+ normal cord blood cells. In vitro drug responses were tested by culturing CD34+ cells either alone or in co-culture with a mouse bone marrow stromal cell line (SL/M2). Effects on colony formation and replating were also tested by culturing sorted CD34+CD38+lin− cells in methylcellulose in the presence and absence of drug. For in vivo testing of 97C1 we transplanted neonatal RAG2-/-yc-/- mice with CD34+ cells from 3 different BC CML and cord blood samples. Transplanted mice were screened for peripheral blood engraftment at 6–8 weeks post-transplant and engrafted mice were then treated for 2 weeks with 97C1 by IP injection. Following the treatment period the mice were sacrificed and hemotapoietic organs were analyzed for human engraftment by FACS. Results: BC CML progenitors expressed higher levels of Bcl-2 and Mcl-1 protein compared to normal cord blood and chronic phase CML cells. mRNA expression of Mcl-1, Bcl-X, and Bfl-1 was also increased in BC CML progenitors compared to CP CML progenitors. While BC CML LSC cultured in vitro were resistant to etoposide and dasatinib-induced cell death, 97C1 treatment led to a dose-dependent increase in cell death along with a dose-dependent decrease in the frequency of CD34+CD38+lin− cells compared to vehicle treated controls. While cord blood progenitor cells were also sensitive to 97C1 treatment they had an IC50 around 10 times higher than that for the BC CML cells (100nM versus 10nM). Importantly, 97C1 treatment did not inhibit cord blood colony formation or colony replating in vitro. Mice transplanted with BC CML LSC developed CML in 6–8 weeks post-transplant with diffuse myeloid sarcomas and engraftment of human CD34+CD38+lin− cells in the peripheral blood, liver, spleen, and bone marrow. In vivo treatment with 97C1 led to a significant reduction in both total human engraftment and engraftment of CD34+CD38+lin− cells in all hematopoietic organs analyzed. Conclusion: Our results demonstrate that BC CML LSC are resistant to conventional chemotherapy but are sensitive to 97C1 in vitro and in vivo. Broad-spectrum inhibition of Bcl-2 family proteins may help to eliminate CML LSC while sparing normal hematopoietic stem and progenitor cells. Disclosures: Jamieson: CoronadoBiosciences: Research Funding; CIRM: Research Funding.