Subclones dominate at MDS progression following allogeneic hematopoietic cell transplant
Meagan A. Jacoby, Eric J. Duncavage, Gue Su Chang, Christopher A. Miller, Jin Shao, Kevin Elliott, Joshua Robinson, Robert S. Fulton, Catrina C. Fronick, Michelle O’Laughlin, Sharon E. Heath, Iskra Pusic, John S. Welch, Daniel C. Link, John F. DiPersio, Peter Westervelt, Timothy J. Ley, Timothy A. Graubert, Matthew J. Walter
Meagan A. Jacoby, Eric J. Duncavage, Gue Su Chang, Christopher A. Miller, Jin Shao, Kevin Elliott, Joshua Robinson, Robert S. Fulton, Catrina C. Fronick, Michelle O’Laughlin, Sharon E. Heath, Iskra Pusic, John S. Welch, Daniel C. Link, John F. DiPersio, Peter Westervelt, Timothy J. Ley, Timothy A. Graubert, Matthew J. Walter
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Research Article Genetics Hematology

Subclones dominate at MDS progression following allogeneic hematopoietic cell transplant

Abstract

Allogeneic hematopoietic cell transplantation (alloHCT) is a potentially curative treatment for myelodysplastic syndromes (MDS), but patients who relapse after transplant have poor outcomes. In order to understand the contribution of tumor clonal evolution to disease progression,we applied exome and error-corrected targeted sequencing coupled with copy number analysis to comprehensively define changes in the clonal architecture of MDS in response to therapy using 51 serially acquired tumor samples from 9 patients who progressed after an alloHCT. We show that small subclones before alloHCT can drive progression after alloHCT. Notably, at least one subclone expanded or emerged at progression in all patients. Newly acquired structural variants (SVs) were present in an emergent/expanding subclone in 8 of 9 patients at progression, implicating the acquisition of SVs as important late subclonal progression events. In addition, pretransplant therapy with azacitidine likely influenced the mutation spectrum and evolution of emergent subclones after alloHCT. Although subclone evolution is common, founding clone mutations are always present at progression and could be detected in the bone marrow as early as 30 and/or 100 days after alloHCT in 6 of 8 (75%) patients, often prior to clinical progression. In conclusion, MDS progression after alloHCT is characterized by subclonal expansion and evolution, which can be influenced by pretransplant therapy.

Authors

Meagan A. Jacoby, Eric J. Duncavage, Gue Su Chang, Christopher A. Miller, Jin Shao, Kevin Elliott, Joshua Robinson, Robert S. Fulton, Catrina C. Fronick, Michelle O’Laughlin, Sharon E. Heath, Iskra Pusic, John S. Welch, Daniel C. Link, John F. DiPersio, Peter Westervelt, Timothy J. Ley, Timothy A. Graubert, Matthew J. Walter

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Figure 4

Preallogeneic hematopoietic cell transplant therapy affects clonal evolution at disease progression.

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Preallogeneic hematopoietic cell transplant therapy affects clonal evolu...
(A) The bone marrow myeloblast percentage underestimates MDS tumor burden, as determined by the percentage of cells harboring MDS variants detected by standard sequencing, at the time of transplant. (B) Summary of the clonal evolution of UPN 624702. Linear clonal evolution occurs when cells in the founding clone (containing cluster 1 mutations, yellow) give rise to clone 2 with the addition of cluster 2 mutations (red) and, subsequently, clone 3 with the addition of cluster 3 mutations (green). All mutations present in clones 1–3 are present at first sampling (day 0). After treatment with induction therapy and azacitidine, clone 3 contracts and is no longer detectable by standard sequencing by day 130, but clones 1 and 2 remain. A very rare cell from clone 3 (harboring cluster 1, 2, and 3 mutations) escapes eradication by transplant and gains a structural variant to emerge as the most abundant clone at progression (purple). Selected somatic alterations, some copy number corrected, are shown. Days are numbered as in Figure 1. (C) Spectrum of single nucleotide variant base substitutions present in cluster 1 at first sampling (yellow in D) and cluster 2 and 3 (red and green in D, respectively) present after azacitidine treatment in UPN 368402. Clusters 2 and 3 show a greater proportion of C-to-G transversions, consistent with azacitidine-induced mutations. (D) Summary of the clonal evolution of UPN 368402. Only the founding clone, shown in yellow, is detected at first sampling. After 8 cycles of azacitidine therapy, 2 new subclones emerge, with clone 2 (shown in red) derived from the founding clone, and clone 3 (green) derived from clone 2. Clone 2 expands to become the most abundant clone at progression after transplant.