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Malignant Progression of an MDS-Derived Cell Line Serves As an in Vitro Model for the Leukemic Evolution of MDS

Myelodysplastic syndromes (MDS) have a risk of progression to acute myeloid leukemia (AML), but the deterioration mechanisms of MDS and the alteration points still remain to be elucidated. We previously… Click to show full abstract

Myelodysplastic syndromes (MDS) have a risk of progression to acute myeloid leukemia (AML), but the deterioration mechanisms of MDS and the alteration points still remain to be elucidated. We previously established a myelodysplastic cell line, MDS92 from the bone marrow of an MDS patient, and after a long-term interleukin(IL)-3-containing culture of MDS92, five blastic sublines including MDS-L were isolated. From MDS-L, we obtained two sublines, MDS-L-2007 and MDS-LGF after culture in the presence and absence of IL-3, respectively. To investigate the mechanism of leukemic evolution, we applied a next-generation sequencing (NGS) to the series of cell lines for comprehensive, comparative exome analyses, and searched for the origin of mutations by ultra-deep target sequencing of the original patient bone marrow. Whole exome sequencing and ultra-deep target sequencing demonstrated: (1) TP53 mutation was found in the patient bone marrow and this mutation was inherited by all subsequent cell lines; (2) CEBPA mutation was originally present in a small fraction of the bone marrow; (3) NRAS mutation emerged by chance during IL-3-containing culture; (4) HIST1H3C(K27M) mutation (Histone-H3-K27M) was newly detected at the generation of MDS-L from MDS92. H3-K27M mutation was detected in MDS-L-2007 but not in MDS-LGF. We focused on H3-K27M mutation because it is frequently found in pediatric brain stem tumors and recently found in a small population of AML cases (Lehnertz et al. Blood. 2017). MDS-L cells were a mixture of H3-K27M-mutant and wild-type clones. When MDS-L was cultured in the presence of IL-3, the proportion of H3-K27M-mutant fraction gradually increased. In contrast, when MDS-L was cultured without IL-3, the proportion of H3-K27M-mutant fraction gradually decreased. To investigate the implication of H3-K27M mutation, we tried single cell cloning from MDS-L and secured four wild-type clones and seven H3-K27M-mutant clones. In all H3-K27M-mutant clones, there was a marked reduction in H3-K27me3/2. Expression of a tumor-suppressor molecule p16 was reduced in six of the seven H3-K27M-mutant clones. H3-K27M-mutant clones showed rapid growth in the presence of IL-3, but cell proliferation was suppressed without IL-3. Competitive growth experiment by co-culture of H3-K27-wild-type and H3-K27M-mutant clones in the presence or absence of IL-3 showed that H3-K27M-mutant clones were predominant in the presence of IL-3, whereas wild-type clones were sustained comparatively in the absence of IL-3. Treatment with EPZ-6438, an inhibitor of H3-K27 methyltransferase EZH2, caused growth suppression of H3-K27M-mutant clones as well as wild-type clones and involved obvious recovery of p16 expression in H3-K27M-mutant clones, which provides a possibility that p16 might be a therapeutic target for H3-K27M mutant. Although GSK-J4, an inhibitor of H3-K27 demethylase JMJD3, was reported to inhibit H3-K27M-mutated pediatric brain stem tumors, GSK-J4 exerted only non-specific growth inhibitory effect on both H3-K27M-mutant and wild-type clones. Whole exome analyses indicated that the accumulation of oncogenic mutations seemed to have led to establishment of MDS cell lines. The finding that growth advantage of H3-K27M mutant was influenced by the presence or absence of IL-3 raised a possibility that even if neoplastic clones emerge, their expansion might be influenced not only by genetic/epigenetic status but by surrounding environmental factors including cytokines. This series of cell lines will be a useful tool as an in vitro model for leukemic evolution of MDS. No relevant conflicts of interest to declare.

Keywords: mutant clones; k27m mutant; mds; cell; mutation

Journal Title: Blood
Year Published: 2018

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