A mouse model of Zhu-Tokita-Takenouchi-Kim syndrome reveals indispensable SON functions in organ development and hematopoiesis
Lana Vukadin, Bohye Park, Mostafa Mohamed, Huashi Li, Amr Elkholy, Alex Torrelli-Diljohn, Jung-Hyun Kim, Kyuho Jeong, James M. Murphy, Caitlin A. Harvey, Sophia Dunlap, Leah Gehrs, Hanna Lee, Hyung-Gyoon Kim, Jay Prakash Sah, Seth N. Lee, Denise Stanford, Robert A. Barrington, Jeremy B. Foote, Anna G. Sorace, Robert S. Welner, Blake E. Hildreth III, Ssang-Taek Steve Lim, Eun-Young Erin Ahn
Lana Vukadin, Bohye Park, Mostafa Mohamed, Huashi Li, Amr Elkholy, Alex Torrelli-Diljohn, Jung-Hyun Kim, Kyuho Jeong, James M. Murphy, Caitlin A. Harvey, Sophia Dunlap, Leah Gehrs, Hanna Lee, Hyung-Gyoon Kim, Jay Prakash Sah, Seth N. Lee, Denise Stanford, Robert A. Barrington, Jeremy B. Foote, Anna G. Sorace, Robert S. Welner, Blake E. Hildreth III, Ssang-Taek Steve Lim, Eun-Young Erin Ahn
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Resource and Technical Advance Development Genetics

A mouse model of Zhu-Tokita-Takenouchi-Kim syndrome reveals indispensable SON functions in organ development and hematopoiesis

Abstract

Rare diseases are underrepresented in biomedical research, leading to insufficient awareness. Zhu-Tokita-Takenouchi-Kim (ZTTK) syndrome is a rare disease caused by genetic alterations that result in heterozygous loss of function of SON. While patients with ZTTK syndrome live with numerous symptoms, the lack of model organisms hampers our understanding of SON and this complex syndrome. Here, we developed Son haploinsufficiency (Son+/–) mice as a model of ZTTK syndrome and identified the indispensable roles of Son in organ development and hematopoiesis. Son+/– mice recapitulated clinical symptoms of ZTTK syndrome, including growth retardation, cognitive impairment, skeletal abnormalities, and kidney agenesis. Furthermore, we identified hematopoietic abnormalities in Son+/– mice, including leukopenia and immunoglobulin deficiency, similar to those observed in human patients. Surface marker analyses and single-cell transcriptome profiling of hematopoietic stem and progenitor cells revealed that Son haploinsufficiency shifted cell fate more toward the myeloid lineage but compromised lymphoid lineage development by reducing genes required for lymphoid and B cell lineage specification. Additionally, Son haploinsufficiency caused inappropriate activation of erythroid genes and impaired erythropoiesis. These findings highlight the importance of the full gene expression of Son in multiple organs. Our model serves as an invaluable research tool for this rare disease and related disorders associated with SON dysfunction.

Authors

Lana Vukadin, Bohye Park, Mostafa Mohamed, Huashi Li, Amr Elkholy, Alex Torrelli-Diljohn, Jung-Hyun Kim, Kyuho Jeong, James M. Murphy, Caitlin A. Harvey, Sophia Dunlap, Leah Gehrs, Hanna Lee, Hyung-Gyoon Kim, Jay Prakash Sah, Seth N. Lee, Denise Stanford, Robert A. Barrington, Jeremy B. Foote, Anna G. Sorace, Robert S. Welner, Blake E. Hildreth III, Ssang-Taek Steve Lim, Eun-Young Erin Ahn

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Figure 4

Son haploinsufficiency causes a reduction of the early-stage HSPC (LSK) pool size, an imbalance of myeloid versus lymphoid lineage–biased MPPs, and impaired erythroid terminal differentiation during fetal liver hematopoiesis in Son+/– embryos.

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Son haploinsufficiency causes a reduction of the early-stage HSPC (LSK)...
(A) Representative image of WT and Son+/– embryos at E14 (left panel). Fetal liver cellularity at E14 (right panel) showing no statistically significant difference between WT and Son+/– fetal livers. (B) A schematic indicating subpopulations within the LSK population (LT-HSC, short-term HSC [ST-HSC], MPP2, MPP3, and MPP4), their lineage bias, and the surface markers. (C) Representative flow cytometry contour plots showing the gating scheme used to identify LSK and other subpopulations in the fetal liver. (D) Frequency of the indicated populations within total fetal liver (E16) cells (for Lin and LSK) or within the LSK population (LT-HSC, ST-HSC, MPP2, MPP3, and MPP4). (E) A schematic depicting the process of erythroid differentiation and the expression levels of CD71 and Ter119. (F) Representative flow cytometry contour plots demonstrating fetal liver erythroid subsets S0–S5 indicated by CD71 and Ter119 expression (E14). (G) Frequency of the indicated erythroid subsets, presented as percentage of total fetal liver (E14) cells. (A, D, and G) Data are presented as mean ± SD, n = 8–11. *P < 0.05, **P < 0.01, ***P < 0.001 by 2-tailed t test.