The Cellular Pathway of Leukemic Transformation in MDS: It's the Stem Cells, Stupid!

Myelodysplastic syndromes (MDS) are malignant hematologic diseases characterized by defective myeloid differentiation and high risk of transformation to secondary acute myeloid leukemia (sAML), which is associated with dismal clinical outcomes. MDS is propagated by rare and distinct MDS stem cells that accumulate somatic mutations. Previous bulk sequencing studies have demonstrated that acquisition of additional genetic and cytogenetic abnormalities correlates with progression of MDS to sAML, but the specific subset of cells in which this clonal evolution occurs has not been identified. Characterizing the cell-of-origin underlying transformation to sAML is essential to understanding the molecular events responsible for leukemic transformation in chronic myeloid malignancies, which will pave the way for early detection and interventions to prevent later disease progression.

Combining high-resolution targeted deep-sequencing of fractionated bone marrow populations and single-cell sequencing, Dr. Jiahao Chen and colleagues characterized the cellular architecture of clonal evolution in seven patients with MDS who progressed to sAML. Previous studies had suggested that sAML evolved from an ancestral MDS subclone that acquired further genetic mutations mostly in a linear and hierarchical fashion.^1,2  However, results from Dr. Chen and colleagues suggest that the evolutionary landscape of transformation might be more complex than previously thought.

Targeted sequencing of stem cells and blasts from longitudinal samples revealed that at both the MDS and sAML stages, stem cells were more genetically diverse than blast counterparts in the same patient. Consequently, only a subset of the genetic subclones present in stem cells could be identified in MDS or sAML blast cells analyzed at the bulk level. Subsequent targeted single-cell sequencing of the same populations confirmed that dominant clones identified in MDS blasts and sAML blasts frequently differed within the same patient, but all genetic subclones could be traced back to the stem cell compartment. These results support that genetically distinct subpopulations of stem cells within an individual patient give rise to MDS versus sAML blasts, leading the authors to propose a model of parallel rather than stepwise evolution in the progression to sAML.

Although further functional studies are now needed to elucidate the molecular and functional mechanisms of this process, the model proposed by Dr. Chen and colleagues substantially revises our current understanding of pathways to leukemic transformation in chronic myeloid malignancies. Furthermore, the key finding that genetic heterogeneity can differ markedly in stem cell versus bulk tumor populations has implications more broadly for precision oncology approaches, which typically involve analysis of total tumor populations. This study nicely demonstrated that genetic analysis of fractionated cell populations, including stem cells, can provide additional information that might more accurately predict disease course. Clearly, the challenge is now to analyze larger MDS patient cohorts, including patients without disease transformation, to understand more precisely how genetic heterogeneity of stem cells correlates with risk of disease transformation.