Gain-of-function SAMD9L mutations cause a syndrome of cytopenia, immunodeficiency, MDS, and neurological symptoms.

Several monogenic causes of familial myelodysplastic syndrome (MDS) have recently been identified. We studied 2 families with cytopenia, predisposition to MDS with chromosome 7 aberrations, immunodeficiency, and progressive cerebellar dysfunction. Genetic studies uncovered heterozygous missense mutations in SAMD9L, a tumor suppressor gene located on chromosome arm 7q. Consistent with a gain-of-function effect, ectopic expression of the 2 identified SAMD9L mutants decreased cell proliferation relative to wild-type protein. Of the 10 individuals identified who were heterozygous for either SAMD9L mutation, 3 developed MDS upon loss of the mutated SAMD9L allele following intracellular infections associated with myeloid, B-, and natural killer (NK)-cell deficiency. Five other individuals, 3 with spontaneously resolved cytopenic episodes in infancy, harbored hematopoietic revertant mosaicism by uniparental disomy of 7q, with loss of the mutated allele or additional in cisSAMD9L truncating mutations. Examination of 1 individual indicated that somatic reversions were postnatally selected. Somatic mutations were tracked to CD34+ hematopoietic progenitor cell populations, being further enriched in B and NK cells. Stimulation of these cell types with interferon (IFN)-α or IFN-γ induced SAMD9L expression. Clinically, revertant mosaicism was associated with milder disease, yet neurological manifestations persisted in 3 individuals. Two carriers also harbored a rare, in trans germ line SAMD9L missense loss-of-function variant, potentially counteracting the SAMD9L mutation. Our results demonstrate that gain-of-function mutations in the tumor suppressor SAMD9L cause cytopenia, immunodeficiency, variable neurological presentation, and predisposition to MDS with -7/del(7q), whereas hematopoietic revertant mosaicism commonly ameliorated clinical manifestations. The findings suggest a role for SAMD9L in regulating IFN-driven, demand-adapted hematopoiesis.

[1]  P. Nguyen,et al.  Myelodysplastic syndromes , 2009, Nature Reviews Disease Primers.

[2]  S. Holland,et al.  Adaptive NK cells can persist in patients with GATA2 mutation depleted of stem and progenitor cells. , 2017, Blood.

[3]  M. Voss,et al.  Natural killer cell biology illuminated by primary immunodeficiency syndromes in humans. , 2017, Clinical immunology.

[4]  H. Okano,et al.  SAMD9 mutations cause a novel multisystem disorder, MIRAGE syndrome, and are associated with loss of chromosome 7 , 2016, Nature Genetics.

[5]  Deborah Nickerson,et al.  Ataxia-Pancytopenia Syndrome Is Caused by Missense Mutations in SAMD9L. , 2016, American journal of human genetics.

[6]  C. Dinardo,et al.  Hereditary Predispositions to Myelodysplastic Syndrome , 2016, International journal of molecular sciences.

[7]  Mario Cazzola,et al.  The 2016 revision to the World Health Organization classification of myeloid neoplasms and acute leukemia. , 2016, Blood.

[8]  M. Wlodarski,et al.  Prevalence, clinical characteristics, and prognosis of GATA2-related myelodysplastic syndromes in children and adolescents. , 2016, Blood.

[9]  James Y. Zou Analysis of protein-coding genetic variation in 60,706 humans , 2015, Nature.

[10]  A. Fischer,et al.  An in vivo genetic reversion highlights the crucial role of Myb-Like, SWIRM, and MPN domains 1 (MYSM1) in human hematopoiesis and lymphocyte differentiation. , 2015, The Journal of allergy and clinical immunology.

[11]  Christopher A. Miller,et al.  Genomic analysis of germ line and somatic variants in familial myelodysplasia/acute myeloid leukemia. , 2015, Blood.

[12]  S. Miyano,et al.  Inherited and Somatic Defects in DDX41 in Myeloid Neoplasms. , 2015, Cancer cell.

[13]  J. Delrow,et al.  Functional analysis of a chromosomal deletion associated with myelodysplastic syndromes using isogenic human induced pluripotent stem cells , 2015, Nature Biotechnology.

[14]  H. Ljunggren,et al.  Cytomegalovirus infection drives adaptive epigenetic diversification of NK cells with altered signaling and effector function. , 2015, Immunity.

[15]  David A. Williams,et al.  Germline ETV6 mutations in familial thrombocytopenia and hematologic malignancy , 2015, Nature Genetics.

[16]  M. McCarthy,et al.  Age-related clonal hematopoiesis associated with adverse outcomes. , 2014, The New England journal of medicine.

[17]  S. Gabriel,et al.  Clonal hematopoiesis and blood-cancer risk inferred from blood DNA sequence. , 2014, The New England journal of medicine.

[18]  B. Dumitriu,et al.  Bone marrow failure and the telomeropathies. , 2014, Blood.

[19]  Ze-Guang Han,et al.  SAMD9L Inactivation Promotes Cell Proliferation via Facilitating G1-S Transition in Hepatitis B Virus-associated Hepatocellular Carcinoma , 2014, International journal of biological sciences.

[20]  H. Honda,et al.  −7/7q− syndrome in myeloid-lineage hematopoietic malignancies: attempts to understand this complex disease entity , 2014, Oncogene.

[21]  J. Orange,et al.  GATA2 deficiency: a protean disorder of hematopoiesis, lymphatics, and immunity. , 2014, Blood.

[22]  N. McGovern,et al.  The evolution of cellular deficiency in GATA2 mutation. , 2014, Blood.

[23]  S. Miyano,et al.  Recurrent genetic defects on chromosome 7q in myeloid neoplasms , 2014, Leukemia.

[24]  C Haferlach,et al.  Landscape of genetic lesions in 944 patients with myelodysplastic syndromes , 2013, Leukemia.

[25]  J. Orange,et al.  HEMATOPOIESIS AND STEM CELLS GATA 2 de fi ciency : a protean disorder of hematopoiesis , lymphatics , and immunity , 2014 .

[26]  M. Stratton,et al.  Clinical and biological implications of driver mutations in myelodysplastic syndromes. , 2013, Blood.

[27]  T. Suda,et al.  Haploinsufficiency of SAMD9L, an endosome fusion facilitator, causes myeloid malignancies in mice mimicking human diseases with monosomy 7. , 2013, Cancer cell.

[28]  J. Orange Natural killer cell deficiency. , 2013, Journal of Allergy and Clinical Immunology.

[29]  S. Chanda,et al.  A Short Hairpin RNA Screen of Interferon-Stimulated Genes Identifies a Novel Negative Regulator of the Cellular Antiviral Response , 2013, mBio.

[30]  G. McFadden,et al.  Evolution and divergence of the mammalian SAMD9/SAMD9L gene family , 2013, BMC Evolutionary Biology.

[31]  J. Orange,et al.  Mutations in GATA2 cause human NK cell deficiency with specific loss of the CD56(bright) subset. , 2013, Blood.

[32]  Luca Malcovati,et al.  Revised international prognostic scoring system for myelodysplastic syndromes. , 2012, Blood.

[33]  Weimin Bi,et al.  Aneuploidy as a mechanism for stress-induced liver adaptation. , 2012, The Journal of clinical investigation.

[34]  A. Jankowska,et al.  Loss of heterozygosity in 7q myeloid disorders: clinical associations and genomic pathogenesis. , 2012, Blood.

[35]  William Wheeler,et al.  Detectable clonal mosaicism and its relationship to aging and cancer , 2012, Nature Genetics.

[36]  V. Plagnol,et al.  Exome sequencing identifies autosomal-dominant SRP72 mutations associated with familial aplasia and myelodysplasia. , 2012, American journal of human genetics.

[37]  Ingo Ruczinski,et al.  Detectable clonal mosaicism from birth to old age and its relationship to cancer , 2012, Nature Genetics.

[38]  M. Manz,et al.  Demand-adapted regulation of early hematopoiesis in infection and inflammation. , 2012, Blood.

[39]  Anna L. Brown,et al.  Heritable GATA2 Mutations Associated with Familial Myelodysplastic Syndrome and Acute Myeloid Leukemia , 2011, Nature Genetics.

[40]  O. Sarig,et al.  Functional characterization of SAMD9, a protein deficient in normophosphatemic familial tumoral calcinosis. , 2011, The Journal of investigative dermatology.

[41]  Leiliang Zhang,et al.  M062 Is a Host Range Factor Essential for Myxoma Virus Pathogenesis and Functions as an Antagonist of Host SAMD9 in Human Cells , 2011, Journal of Virology.

[42]  P. Noris,et al.  Mutations in the 5' UTR of ANKRD26, the ankirin repeat domain 26 gene, cause an autosomal-dominant form of inherited thrombocytopenia, THC2. , 2011, American journal of human genetics.

[43]  Nathan C Boles,et al.  Quiescent hematopoietic stem cells are activated by IFNγ in response to chronic infection , 2010, Nature.

[44]  D. Geschwind,et al.  Longitudinal system-based analysis of transcriptional responses to type I interferons. , 2009, Physiological genomics.

[45]  T. Inaba,et al.  Identification of a common microdeletion cluster in 7q21.3 subband among patients with myeloid leukemia and myelodysplastic syndrome. , 2009, Biochemical and biophysical research communications.

[46]  Andreas Trumpp,et al.  IFNα activates dormant haematopoietic stem cells in vivo , 2009, Nature.

[47]  Mark George Thomas,et al.  Normophosphatemic familial tumoral calcinosis is caused by deleterious mutations in SAMD9, encoding a TNF-alpha responsive protein. , 2008, The Journal of investigative dermatology.

[48]  I. Baumann,et al.  Myelodysplastic syndrome in children and adolescents. , 2008, Seminars in hematology.

[49]  Thomas H Müller,et al.  New insights into the prognostic impact of the karyotype in MDS and correlation with subtypes: evidence from a core dataset of 2124 patients. , 2007, Blood.

[50]  M. L. Le Beau,et al.  Evaluation of recurring cytogenetic abnormalities in the treatment of myelodysplastic syndromes. , 2007, Leukemia research.

[51]  R. Y. Wei,et al.  Human sterile alpha motif domain 9, a novel gene identified as down-regulated in aggressive fibromatosis, is absent in the mouse , 2007, BMC Genomics.

[52]  D. Geiger,et al.  A deleterious mutation in SAMD9 causes normophosphatemic familial tumoral calcinosis. , 2006, American journal of human genetics.

[53]  T. Lister,et al.  Mutation of CEBPA in familial acute myeloid leukemia. , 2004, The New England journal of medicine.

[54]  T. Morio,et al.  Pancytopenia presenting with monosomy 7 which disappeared after immunosuppressive therapy. , 2004, Leukemia research.

[55]  R. Hirschhorn In vivo reversion to normal of inherited mutations in humans , 2003, Journal of medical genetics.

[56]  J. Harbott,et al.  Refractory anemia in childhood: a retrospective analysis of 67 patients with particular reference to monosomy 7. , 2003, Blood.

[57]  Marianne Berwick,et al.  A 20-year perspective on the International Fanconi Anemia Registry (IFAR). , 2003, Blood.

[58]  B. Alter Cancer in Fanconi anemia, 1927–2001 , 2003, Cancer.

[59]  A. Knudson,et al.  Two genetic hits (more or less) to cancer , 2001, Nature Reviews Cancer.

[60]  M. Mancini,et al.  Spontaneous remission in adult patients with de novo myelodysplastic syndrome: a possible event. , 2001, Haematologica.

[61]  John M. Maris,et al.  Haploinsufficiency of CBFA2 causes familial thrombocytopenia with propensity to develop acute myelogenous leukaemia , 1999, Nature Genetics.

[62]  J. Harbott,et al.  Chronic myelomonocytic leukemia in childhood. A retrospective analysis of 110 cases. , 1997 .

[63]  K. Kinzler,et al.  Lessons from Hereditary Colorectal Cancer , 1996, Cell.

[64]  H. Hasle,et al.  Childhood myelodysplastic syndrome in Denmark: incidence and predisposing conditions. , 1995, Leukemia.

[65]  P. Papenhausen,et al.  SPONTANEOUS REMISSION IN MONOSOMY 7 MYELODYSPLASTIC SYNDROME , 1995, British journal of haematology.

[66]  R. Gale,et al.  Hematologic abnormalities in Fanconi anemia: an International Fanconi Anemia Registry study. , 1994, Blood.

[67]  A. Borkhardt,et al.  Spontaneous hematological remission in a boy with myelodysplastic syndrome and monosomy 7. , 1994, Leukemia.

[68]  A. Bowcock,et al.  Familial bone marrow monosomy 7. Evidence that the predisposing locus is not on the long arm of chromosome 7. , 1989, The Journal of clinical investigation.

[69]  J. Whang‐Peng,et al.  A family with acute leukemia, hypoplastic anemia and cerebellar ataxia: association with bone marrow C-monosomy. , 1978, The American journal of medicine.

[70]  Sb,et al.  Cancer in Fanconi Anemia , 2022 .