Germline SAMD9 and SAMD9L mutations are associated with extensive genetic evolution and diverse hematologic outcomes
Jasmine C. Wong, Victoria Bryant, Tamara Lamprecht, Jing Ma, Michael Walsh, Jason Schwartz, Maria del pilar Alzamora, Charles G. Mullighan, Mignon L. Loh, Raul Ribeiro, James R. Downing, William L. Carroll, Jeffrey Davis, Stuart Gold, Paul C. Rogers, Sara Israels, Rochelle Yanofsky, Kevin Shannon, Jeffery M. Klco
Jasmine C. Wong, Victoria Bryant, Tamara Lamprecht, Jing Ma, Michael Walsh, Jason Schwartz, Maria del pilar Alzamora, Charles G. Mullighan, Mignon L. Loh, Raul Ribeiro, James R. Downing, William L. Carroll, Jeffrey Davis, Stuart Gold, Paul C. Rogers, Sara Israels, Rochelle Yanofsky, Kevin Shannon, Jeffery M. Klco
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Research Article Hematology

Germline SAMD9 and SAMD9L mutations are associated with extensive genetic evolution and diverse hematologic outcomes

Abstract

Germline SAMD9 and SAMD9L mutations cause a spectrum of multisystem disorders that carry a markedly increased risk of developing myeloid malignancies with somatic monosomy 7. Here, we describe 16 siblings, the majority of which were phenotypically normal, from 5 families diagnosed with myelodysplasia and leukemia syndrome with monosomy 7 (MLSM7; OMIM 252270) who primarily had onset of hematologic abnormalities during the first decade of life. Molecular analyses uncovered germline SAMD9L (n = 4) or SAMD9 (n = 1) mutations in these families. Affected individuals had a highly variable clinical course that ranged from mild and transient dyspoietic changes in the bone marrow to a rapid progression of myelodysplastic syndrome (MDS) or acute myeloid leukemia (AML) with monosomy 7. Expression of these gain-of-function SAMD9 and SAMD9L mutations reduces cell cycle progression, and deep sequencing demonstrated selective pressure favoring the outgrowth of clones that have either lost the mutant allele or acquired revertant mutations. The myeloid malignancies of affected siblings acquired cooperating mutations in genes that are also altered in sporadic cases of AML characterized by monosomy 7. These data have implications for understanding how SAMD9 and SAMD9L mutations contribute to myeloid transformation and for recognizing, counseling, and treating affected families.

Authors

Jasmine C. Wong, Victoria Bryant, Tamara Lamprecht, Jing Ma, Michael Walsh, Jason Schwartz, Maria del pilar Alzamora, Charles G. Mullighan, Mignon L. Loh, Raul Ribeiro, James R. Downing, William L. Carroll, Jeffrey Davis, Stuart Gold, Paul C. Rogers, Sara Israels, Rochelle Yanofsky, Kevin Shannon, Jeffery M. Klco

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Figure 3

SAMD9 K676E mutation in MLSM7 family 2.

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SAMD9 K676E mutation in MLSM7 family 2. (A) Pedigree of family 2 with a...
(A) Pedigree of family 2 with a germline SAMD9 p.K676E mutation (red font). The cooperating mutations found in the bone marrows of patients 2A (AML) and 2B (MDS) are shown in black text. Squares indicate male family members, circles female members. Unaffected individuals are indicated with open symbols, unaffected mutation carriers are denoted with black dots, affected individuals with a clinical history of monosomy 7 are shown with filled symbols, and symbols with a slash denote deceased individuals. Arrow indicates the proband. (B) EdU cell cycle results from 293T cells transfected with an empty GFP vector, a cDNA encoding WT SAMD9, or a SAMD9 p.K676E cDNA. Percentages of cells in the S phase of the cell division cycle were compared using 1-way ANOVAs with repeated measures followed by Tukey’s post hoc multiple-comparisons test; significance was based on α = 0.05 (n = 3). ***P < 0.001. n.s., not significant. Individual data points, and mean ± SD are shown. Data representative of 2 experiments completed in triplicate. (C) SNP array analysis showing a focal 12p13.2 deletion that includes the ETV6 gene (red arrow) in the AML sample of patient 2A.