Characterization of the clonal hierarchy and immunophenotype of PTPN11 mutations in acute myeloid leukemia
Sydney Fobare, Chia Sharpe, Kate Quinn, Kinsey Bryant, Linde A. Miles, Robert L. Bowman, Carolyn Cheney, Casie Furby, Marissa Long, Kaytlynn Fyock, Ben Wronowski, James R. Lerma, Krzysztof Mrózek, Deedra Nicolet, Thomas M. Sesterhenn, Megan E. Johnstone, Jianmin Pan, Shesh N. Rai, Chandrashekhar Pasare, Nives Zimmermann, Wen-Mei Yu, Cheng-Kui Qu, Andrew Carroll, Richard Stone, Eunice S. Wang, Jonathan Kolitz, Bayard Powell, John P. Perentesis, Ann-Kathrin Eisfeld, Erin Hertlein, John C. Byrd
Sydney Fobare, Chia Sharpe, Kate Quinn, Kinsey Bryant, Linde A. Miles, Robert L. Bowman, Carolyn Cheney, Casie Furby, Marissa Long, Kaytlynn Fyock, Ben Wronowski, James R. Lerma, Krzysztof Mrózek, Deedra Nicolet, Thomas M. Sesterhenn, Megan E. Johnstone, Jianmin Pan, Shesh N. Rai, Chandrashekhar Pasare, Nives Zimmermann, Wen-Mei Yu, Cheng-Kui Qu, Andrew Carroll, Richard Stone, Eunice S. Wang, Jonathan Kolitz, Bayard Powell, John P. Perentesis, Ann-Kathrin Eisfeld, Erin Hertlein, John C. Byrd
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Research Article Hematology Oncology

Characterization of the clonal hierarchy and immunophenotype of PTPN11 mutations in acute myeloid leukemia

Abstract

Mutations in protein tyrosine phosphatase non-receptor type 11 (PTPN11) have been considered late acquired mutations in acute myeloid leukemia (AML) development. Using single-cell DNA sequencing, we found that PTPN11 mutations can occur as initiating events in some patients with AML when accompanied by strong oncogenic drivers, commonly NPM1 mutations. The resulting AML has a diverse set of variably differentiated myeloid cells with few myeloid cells that lack leukemic mutations. The role of Ptpn11 as a codriver was confirmed in a murine model that exhibits an AML phenotype with a comparable immune diversity that is serially engraftable and reconstituted from early precursor cells. Furthermore, lineage-negative bone marrow cells from these mice reconstitute the full diversity of mature myeloid cells, and these cells exhibit an altered cytokine response after physiologic stimulation. Our work highlights how PTPN11-mutated AML is derived from a multitude of codominant and late acquired aberrations that have a previously unrecognized differentiated myeloid clonal expansion potentially contributing to pathogenesis of the disease.

Authors

Sydney Fobare, Chia Sharpe, Kate Quinn, Kinsey Bryant, Linde A. Miles, Robert L. Bowman, Carolyn Cheney, Casie Furby, Marissa Long, Kaytlynn Fyock, Ben Wronowski, James R. Lerma, Krzysztof Mrózek, Deedra Nicolet, Thomas M. Sesterhenn, Megan E. Johnstone, Jianmin Pan, Shesh N. Rai, Chandrashekhar Pasare, Nives Zimmermann, Wen-Mei Yu, Cheng-Kui Qu, Andrew Carroll, Richard Stone, Eunice S. Wang, Jonathan Kolitz, Bayard Powell, John P. Perentesis, Ann-Kathrin Eisfeld, Erin Hertlein, John C. Byrd

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Figure 3

Immunophenotypic diversity of primary PTPN11- and NPM1-mutated AML peripheral blood and bone marrow samples at diagnosis.

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Immunophenotypic diversity of primary PTPN11- and NPM1-mutated AML perip...
(A) Percentage of CD34+CD38 and CD34+CD38+ cells in healthy and leukemic peripheral blood (PB) and bone marrow (BM) with representative flow plots. (B) Percentage of CD14+ monocytes in healthy and leukemic PB and BM with representative flow plots. (C) Percentage of pre-conventional dendritic cells (pre-cDCs) in healthy and leukemic PB and BM with representative flow plots. (D) Percentage of plasmacytoid DCs (pDCs) in healthy and leukemic PB and BM with representative flow plots. (E) Percentage of CD1c+ DCs, CD141+ DCs, and immature DCs in healthy and leukemic PB and BM, respectively, with representative flow plots. Percentages are based on CD45+ cells. Data are presented as mean ± SD of 2 independent experiments. Statistical analysis by 1-way ANOVA with Benjamini-Hochberg FDR correction applied. *FDR-adjusted P ≤ 0.05, ***FDR-adjusted P ≤ 0.001.