Multiorgan failure with abnormal receptor metabolism in mice mimicking Samd9/9L syndromes
Akiko Nagamachi, … , Hirotaka Matsui, Toshiya Inaba
Akiko Nagamachi, … , Hirotaka Matsui, Toshiya Inaba
Published December 29, 2020
Citation Information: J Clin Invest. 2021;131(4):e140147. https://doi.org/10.1172/JCI140147.
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Research Article Cell biology Hematology

Multiorgan failure with abnormal receptor metabolism in mice mimicking Samd9/9L syndromes

Abstract

Autosomal dominant sterile α motif domain containing 9 (Samd9) and Samd9L (Samd9/9L) syndromes are a large subgroup of currently established inherited bone marrow failure syndromes that includes myelodysplasia, infection, growth restriction, adrenal hypoplasia, genital phenotypes, and enteropathy (MIRAGE), ataxia pancytopenia, and familial monosomy 7 syndromes. Samd9/9L genes are located in tandem on chromosome 7 and have been known to be the genes responsible for myeloid malignancies associated with monosomy 7. Additionally, as IFN-inducible genes, Samd9/9L are crucial for protection against viruses. Samd9/9L syndromes are caused by gain-of-function mutations and develop into infantile myelodysplastic syndromes associated with monosomy 7 (MDS/–7) at extraordinarily high frequencies. We generated mice expressing Samd9LD764N, which mimic MIRAGE syndrome, presenting with growth retardation, a short life, bone marrow failure, and multiorgan degeneration. In hematopoietic cells, Samd9LD764N downregulates the endocytosis of transferrin and c-Kit, resulting in a rare cause of anemia and a low bone marrow reconstitutive potential that ultimately causes MDS/–7. In contrast, in nonhematopoietic cells we tested, Samd9LD764N upregulated the endocytosis of EGFR by Ship2 phosphatase translocation to the cytomembrane and activated lysosomes, resulting in the reduced expression of surface receptors and signaling. Thus, Samd9/9L is a downstream regulator of IFN that controls receptor metabolism, with constitutive activation leading to multiorgan dysfunction.

Authors

Akiko Nagamachi, Akinori Kanai, Megumi Nakamura, Hiroshi Okuda, Akihiko Yokoyama, Satoru Shinriki, Hirotaka Matsui, Toshiya Inaba

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Figure 3

Characterization of hematopoietic progenitors.

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Characterization of hematopoietic progenitors. (A) The numbers of cells ...
(A) The numbers of cells in a KLS population (LT-HSCs, CD34flt3; ST-HSCs, CD34+flt3; MPP, CD34+flt3+) (35) per 1000 bone marrow cells. Means and SD of 4 mice at 10 weeks of age. (B) Percentage of progenitors in a Lin/Sca-1/IL-7Rα-c-Kit+ population (54). Mean and SD of 5 mice are shown. (CD) KL cells were cultured in Epo for 3 days. The numbers of mature erythrocytes (FSClo, SSClo) at day 3 (C). Living cell numbers and percentages of dead cells during culture were determined by trypan blue dye exclusion (D). Mean and SD of 5 mice at 8 weeks of age are shown. (E) Bone marrow cells from either mice+/+ or micem/m containing mSCF and TPO were cultured for 5 days. KL cells were isolated and continued in culture for an additional 5 days. Cell count (upper) and results of SHIP analysis for c-Kit internalization (lower). Mean and SD of 5 mice at 9 weeks of age are shown. (F and G) Reconstitutive potential using the Ly5 congenic mouse system and LT-HSC cells isolated from 9-week-old mice. The percentages of donor-derived (Ly5.2+) cells in the total WBCs in the peripheral blood at the periods indicated after transplantation. Means are plotted, and error bars show SD (F). The ratio of Ly5.2-positive cells in LT-HSC, ST-HSC, MPP, and Lin-negative cells in bone marrow of recipient mice 3 months after transplantation. Means and SD of 5 mice are shown (G). *P < 0.05; **P < 0.01, Tukey’s test (BE and G); Tukey-Kramer test (F).