ADAR1 Activation Drives Leukemia Stem Cell Self-Renewal by Impairing Let-7 Biogenesis

Zipeto, M; Court, Angela C.; Sadarangani, Anil; Santos, Nathaniel Delos; Balaian, Larisa; Chun, Hye Jung; Pineda, Gabriel; Morris, Sheldon R.; Mason, Cheryl L.; Geron, Ifat; Barrett, Christian; Goff, Daniel; Wall, Russell; Pellecchia, Maurizio; Minden, Mark D.; Frazer, Kelly A.; Marra, Marco A.; Crews, Leslie; Jiang, Qingfei; Jamieson, Catriona

doi:10.1016/j.stem.2016.05.004

Cited by 188 publications

(196 citation statements)

References 65 publications

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“…The resulting inosine bases are subsequently read as guanosines, thus inducing A-to-G post-transcriptional changes that contribute to transcriptome diversity. Although the precise mechanisms governing RNA editing events in cancer are currently the subject of intense investigation, copy number amplification at chromosome 1q 39 — the locus of the human ADAR1 gene — and inflammation 7,40 are two primary mechanisms that may contribute to induction of RNA editing in cancer. Normally, ADAR1 transcription is activated by RNA viruses and represents an essential component of the innate antiviral immune response 41 .…”

Section: A-to-i Editing In Cscsmentioning

confidence: 99%

RNA editing-dependent epitranscriptome diversity in cancer stem cells

et al. 2017

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Cancer stem cells (CSCs) can regenerate all facets of a tumour as a result of their stem cell-like capacity to self-renew, survive and become dormant in protective microenvironments. CSCs evolve during tumour progression in a manner that conforms to Charles Darwin’s principle of natural selection. Although somatic DNA mutations and epigenetic alterations promote evolution, post-transcriptional RNA modifications together with RNA binding protein activity (the ‘epitranscriptome’) might also contribute to clonal evolution through dynamic determination of RNA function and gene expression diversity in response to environmental stimuli. Deregulation of these epitranscriptomic events contributes to CSC generation and maintenance, which governs cancer progression and drug resistance. In this Review, we discuss the role of malignant RNA processing in CSC generation and maintenance, including mechanisms of RNA methylation, RNA editing and RNA splicing, and the functional consequences of their aberrant regulation in human malignancies. Finally, we highlight the potential of these events as novel CSC biomarkers as well as therapeutic targets.

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Section: A-to-i Editing In Cscsmentioning

confidence: 99%

RNA editing-dependent epitranscriptome diversity in cancer stem cells

et al. 2017

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“…Recently, pre-mRNA splicing alterations (Abrahamsson et al, 2009; Adamia et al, 2014; DeBoever et al, 2015; Goff et al, 2013; Holm et al, 2015), together with RNA editing and lncRNA deregulation, were associated with therapeutic resistance in leukemia (Crews et al, 2015; Jiang et al, 2013; Trimarchi et al, 2014). With regard to the functional impact of RNA processing alterations on therapeutic resistance, we discovered that malignant reprogramming of human pre-leukemic progenitors into self-renewing LSC was enhanced by missplicing of a stem cell regulatory transcript, GSK3β (Abrahamsson et al, 2009), through RNA editing (Crews et al, 2015; Jiang et al, 2013; Zipeto et al, 2016) and pro-survival BCL2 family splice isoform switching in CML (Goff et al, 2013). Moreover, reversion to an embryonic splicing program by MBNL 3 downregulation also promoted acute leukemic transformation (Holm et al, 2015) and underscored the importance of splicing deregulation in human LSC generation.…”

Section: Introductionmentioning

confidence: 99%

RNA Splicing Modulation Selectively Impairs Leukemia Stem Cell Maintenance in Secondary Human AML

et al. 2016

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SUMMARY Age-related human hematopoietic stem cell (HSC) exhaustion and myeloid-lineage skewing promote oncogenic transformation of hematopoietic progenitor cells into therapy-resistant leukemia stem cells (LSC) in secondary acute myeloid leukemia (sAML). While acquisition of clonal DNA mutations have been linked to increased rates of sAML for individuals over 60, the contribution of RNA processing alterations to human hematopoietic stem and progenitor aging and LSC generation remains unclear. Comprehensive RNA-sequencing and splice isoform-specific PCR uncovered characteristic RNA splice isoform expression patterns that distinguished normal young and aged HSPCs, compared with malignant MDS and AML progenitors. In splicing reporter assays and in pre-clinical patient-derived AML models, treatment with a pharmacologic splicing modulator, 17S-FD-895, reversed pro-survival splice isoform switching and significantly impaired LSC maintenance. By comparing splice isoform biomarkers of normal HSPC aging with those of LSC generation, splicing modulation may be employed safely and effectively to prevent relapse – the leading cause of leukemia-related mortality.

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“…In chronic myeloid leukemia, the increased expressions of IFN-γ-R1 and IL-3Rα upregulate ADAR1′s transcription through JAK2, which controls the biogenesis of let-7 miRNA and the self-renewal of leukemia stem cells. A-to-I editing by ADAR1 is needed for the transformation into the malignant pathway, by inhibiting let-7 miRNA biogenesis and promoting the self-renewal of progenitor cells [144]. This would also explain the higher ADAR1p150 levels observed with dysregulated levels of the myeloid transcription factor PU.1 and mis-splicing of the GSK3-β protein, which drives the blastic transformation between the second and third phases of disease progression [145].…”

Section: Regulation Of Adar1 Expressionmentioning

confidence: 99%

Functions of the RNA Editing Enzyme ADAR1 and Their Relevance to Human Diseases

Song

Sakurai

Shiromoto

et al. 2016

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Adenosine deaminases acting on RNA (ADARs) convert adenosine to inosine in double-stranded RNA (dsRNA). Among the three types of mammalian ADARs, ADAR1 has long been recognized as an essential enzyme for normal development. The interferon-inducible ADAR1p150 is involved in immune responses to both exogenous and endogenous triggers, whereas the functions of the constitutively expressed ADAR1p110 are variable. Recent findings that ADAR1 is involved in the recognition of self versus non-self dsRNA provide potential explanations for its links to hematopoiesis, type I interferonopathies, and viral infections. Editing in both coding and noncoding sequences results in diseases ranging from cancers to neurological abnormalities. Furthermore, editing of noncoding sequences, like microRNAs, can regulate protein expression, while editing of Alu sequences can affect translational efficiency and editing of proximal sequences. Novel identifications of long noncoding RNA and retrotransposons as editing targets further expand the effects of A-to-I editing. Besides editing, ADAR1 also interacts with other dsRNA-binding proteins in editing-independent manners. Elucidating the disease-specific patterns of editing and/or ADAR1 expression may be useful in making diagnoses and prognoses. In this review, we relate the mechanisms of ADAR1′s actions to its pathological implications, and suggest possible mechanisms for the unexplained associations between ADAR1 and human diseases.

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ADAR1 Activation Drives Leukemia Stem Cell Self-Renewal by Impairing Let-7 Biogenesis

Cited by 188 publications

References 65 publications

RNA editing-dependent epitranscriptome diversity in cancer stem cells

RNA editing-dependent epitranscriptome diversity in cancer stem cells

RNA Splicing Modulation Selectively Impairs Leukemia Stem Cell Maintenance in Secondary Human AML

Functions of the RNA Editing Enzyme ADAR1 and Their Relevance to Human Diseases

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