Myeloid malignancies, including acute myeloid leukaemia (AML), arise from the expansion of haematopoietic stem and progenitor cells that acquire somatic mutations. Bulk molecular profiling has ...suggested that mutations are acquired in a stepwise fashion: mutant genes with high variant allele frequencies appear early in leukaemogenesis, and mutations with lower variant allele frequencies are thought to be acquired later
. Although bulk sequencing can provide information about leukaemia biology and prognosis, it cannot distinguish which mutations occur in the same clone(s), accurately measure clonal complexity, or definitively elucidate the order of mutations. To delineate the clonal framework of myeloid malignancies, we performed single-cell mutational profiling on 146 samples from 123 patients. Here we show that AML is dominated by a small number of clones, which frequently harbour co-occurring mutations in epigenetic regulators. Conversely, mutations in signalling genes often occur more than once in distinct subclones, consistent with increasing clonal diversity. We mapped clonal trajectories for each sample and uncovered combinations of mutations that synergized to promote clonal expansion and dominance. Finally, we combined protein expression with mutational analysis to map somatic genotype and clonal architecture with immunophenotype. Our findings provide insights into the pathogenesis of myeloid transformation and how clonal complexity evolves with disease progression.
Mutations in the gene DNMT3A have been identified in various hematopoietic conditions, including clonal hematopoiesis, myelodysplastic syndrome, and acute myeloid leukemia. The clinical significance ...of this early mutation and the resultant enhanced clonal fitness have been a focus for therapeutic intervention. See related article by Venugopal et al., p. 756.
Over the past year, Cell Stem Cell has introduced early-career researchers impacted by the COVID-19 pandemic and subsequent closures to our readers. One year since our first introductions, we’ve ...invited several participants to reflect on their experiences and key issues. In this Story, Aaron Viny discusses the emotional toll faced by physician-scientists over this past year and highlights how we need vaccinations, and each other, to see the pandemic through.
Over the past year, Cell Stem Cell has introduced early-career researchers impacted by the COVID-19 pandemic and subsequent closures to our readers. One year since our first introductions, we’ve invited several participants to reflect on their experiences and key issues. In this Story, Aaron Viny discusses the emotional toll faced by physician-scientists over this past year and highlights how we need vaccinations, and each other, to see the pandemic through.
•Mutations in chromatin modifiers are recurrently observed in myelodysplastic syndrome.•Loss of function of cohesin complex members alters chromatin accessibility and transcriptional ...output.•Alterations to STAG2 are most common and likely to selectively perturb short-range loops in lineage commitment.•Potential therapeutic vulnerabilities will be discussed.
Disordered chromatin organization has emerged as a new aspect of the pathogenesis of myelodysplastic syndrome (MDS). Characterized by lineage dysplasia and a high transformation rate to acute myeloid leukemia (AML), the genetic determinant of MDS is thought to be the main driver of the disease's progression. Among the recurrently mutated pathways, alterations in chromatin organization, such as the cohesin complex, have a profound impact on hematopoietic stem cell (HSC) function and lineage commitment. The cohesin complex is a ring-like structure comprised of structural maintenance of chromosomes (SMC), RAD21, and STAG proteins that involve three-dimensional (3D) genome organization via loop extrusion in mammalian cells. The partial loss of the functional cohesin ring leads to altered chromatin accessibility specific to key hematopoietic transcription factors, which is thought to be the molecular mechanism of cohesin dysfunction. Currently, there are no specific targeting agents for cohesin mutant MDS/AML. Potential therapeutic strategies have been proposed based on the current understanding of cohesin mutant leukemogenesis. Here, we will review the recent advances in investigation and targeting approaches against cohesin mutant MDS/AML.
In this issue of Molecular Cell, Bomber et al. demonstrate that acute loss of SMARCA5 in human cells leads to eviction of CTCF and an increase in nucleosome repeat length without direct impact on ...transcriptional activity.
In this issue of Molecular Cell, Bomber et al. demonstrate that acute loss of SMARCA5 in human cells leads to eviction of CTCF and an increase in nucleosome repeat length without direct impact on transcriptional activity.
Mutations in genes involved in DNA methylation (DNAme; for example, TET2 and DNMT3A) are frequently observed in hematological malignancies
and clonal hematopoiesis
. Applying single-cell sequencing ...to murine hematopoietic stem and progenitor cells, we observed that these mutations disrupt hematopoietic differentiation, causing opposite shifts in the frequencies of erythroid versus myelomonocytic progenitors following Tet2 or Dnmt3a loss. Notably, these shifts trace back to transcriptional priming skews in uncommitted hematopoietic stem cells. To reconcile genome-wide DNAme changes with specific erythroid versus myelomonocytic skews, we provide evidence in support of differential sensitivity of transcription factors due to biases in CpG enrichment in their binding motif. Single-cell transcriptomes with targeted genotyping showed similar skews in transcriptional priming of DNMT3A-mutated human clonal hematopoiesis bone marrow progenitors. These data show that DNAme shapes the topography of hematopoietic differentiation, and support a model in which genome-wide methylation changes are transduced to differentiation skews through biases in CpG enrichment of the transcription factor binding motif.
Clonal hematopoiesis (CH) is an entity hallmarked by skewed hematopoiesis with persistent overrepresentation of cells from a common stem/progenitor lineage harboring single-nucleotide variants and/or ...insertions/deletions. CH is a common and age-related phenomenon that is associated with an increased risk of hematological malignancies, cardiovascular disease, and all-cause mortality. While CH is a term of the hematological aspect, there exists a complex interaction with other organ systems, especially the cardiovascular system. The strongest factor in the development of CH is aging, however, other multiple factors also affect the development of CH including lifestyle-related factors and co-morbid diseases. In recent years, germline genetic factors have been linked to CH risk. In this review, we synthesize what is currently known about how genetic variation affects the risk of CH, how this genetic architecture intersects with myeloid neoplasms, and future prospects for CH.
Somatic cohesin mutations have been reported in myelodysplastic syndrome (MDS) and acute myeloid leukemia (AML). To account for the morphologic and cytogenetic diversity of these neoplasms, a ...well-annotated cohort of 1060 patients with myeloid malignancies including MDS (n = 386), myeloproliferative neoplasms (MPNs) (n = 55), MDS/MPNs (n = 169), and AML (n = 450) were analyzed for cohesin gene mutational status, gene expression, and therapeutic and survival outcomes. Somatic cohesin defects were detected in 12% of patients with myeloid malignancies, whereas low expression of these genes was present in an additional 15% of patients. Mutations of cohesin genes were mutually exclusive and mostly resulted in predicted loss of function. Patients with low cohesin gene expression showed similar expression signatures as those with somatic cohesin mutations. Cross-sectional deep-sequencing analysis for clonal hierarchy demonstrated STAG2, SMC3, and RAD21 mutations to be ancestral in 18%, 18%, and 47% of cases, respectively, and each expanded to clonal dominance concordant with disease transformation. Cohesin mutations were significantly associated with RUNX1, Ras-family oncogenes, and BCOR and ASXL1 mutations and were most prevalent in high-risk MDS and secondary AML. Cohesin defects were associated with poor overall survival (27.2 vs 40 months; P = .023), especially in STAG2 mutant MDS patients surviving >12 months (median survival 35 vs 50 months; P = .017).
•Recurrent hypomorphic cohesin defects and cohesin low expression were identified in a significant proportion of patients with MDS and AML.•Cohesin mutations likely represent secondary events in clonal hierarchy and contribute to clonal transformation.
The mutational landscape of acute myeloid leukemia (AML) has revised diagnostic, prognostic, and therapeutic schemata over the past decade. Recurrently mutated AML genes have functional consequences ...beyond typical oncogene-driven growth and loss of tumor suppresser function.
Large-scale genomic sequencing efforts have mapped the complexity of AML and trials of mutation-based targeted therapy has led to several FDA-approved drugs for mutant-specific AML. However, many recurrent mutations have been identified across a spectrum from clonal hematopoiesis to myelodysplasia to overt AML, such as effectors of DNA methylation, chromatin modifiers, and spliceosomal machinery. The functional effects of these mutations are the basis for substantial discovery.
Understanding the molecular and pathophysiologic functions of key genes that exert leukemogenic potential is essential towards translating these findings into better treatment for AML.
Transcriptional regulators, including the cohesin complex member STAG2, are recurrently mutated in cancer. The role of STAG2 in gene regulation, hematopoiesis, and tumor suppression remains ...unresolved. We show that Stag2 deletion in hematopoietic stem and progenitor cells (HSPCs) results in altered hematopoietic function, increased self-renewal, and impaired differentiation. Chromatin immunoprecipitation (ChIP) sequencing revealed that, although Stag2 and Stag1 bind a shared set of genomic loci, a component of Stag2 binding sites is unoccupied by Stag1, even in Stag2-deficient HSPCs. Although concurrent loss of Stag2 and Stag1 abrogated hematopoiesis, Stag2 loss alone decreased chromatin accessibility and transcription of lineage-specification genes, including Ebf1 and Pax5, leading to increased self-renewal and reduced HSPC commitment to the B cell lineage. Our data illustrate a role for Stag2 in transformation and transcriptional dysregulation distinct from its shared role with Stag1 in chromosomal segregation.
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•Hematopoietic Stag2 loss enhances stem cell self-renewal and impairs differentiation•Stag1 can maintain TAD boundary integrity in the absence of Stag2•Stag2 is required for intra-TAD interactions at lineage genes (e.g., PU.1 targets)•Stag2 target expression, but not PU.1 overexpression, restores B cell differentiation
In murine hematopoietic Stag2 deletion, Stag1 rescues topologically associated domains in the absence of Stag2 but cannot restore the chromatin architecture required for hematopoietic lineage commitment. PU.1 target genes lose accessibility and expression. Induced target gene expression, but not PU.1 overexpression, is sufficient to restore differentiation in the altered chromatin state.