1.Ataxin-3 Overexpression via Adeno-associated Viral Vector Injection in the Primate Cerebellum: A Novel Model of Spinocerebellar Ataxia Type 3
Keonwoo KIM ; Aryun KIM ; Jinyoung WON ; Junghyung PARK ; Kyung Seob LIM ; Chang-Yeop JEON ; Jisun MIN ; Jee-Hyun CHO ; Youngkyu SONG ; Bon-Sang KOO ; Gyu-Seo BAE ; Eunsu JEON ; Kang-Jin JEONG ; Sung-Hyun PARK ; Hwal-Yong LEE ; Won Seok CHOI ; Dong-Seok LEE ; Youngjeon LEE
Experimental Neurobiology 2025;34(6):248-262
Spinocerebellar ataxia type 3 (SCA3) is an autosomal-dominant neurodegenerative disorder caused by an expanded polyglutamine repeat in the ataxin-3 gene. The resulting mutant ataxin-3 protein forms intraneuronal inclusions that lead to neurodegeneration in the cerebellum and other brain regions. This study aimed to develop a novel nonhuman primate model of SCA3 to address the limitations of existing knock-in and transgenic models using an adeno-associated virus (AAV) to deliver the mutant gene. AAV viral vectors carrying mutant ataxin-3 were stereotaxically injected into the cerebellum of monkeys. The animals were monitored over an 8-week period, during which behavioral and neuroimaging assessments were conducted. This was followed by a detailed pathological examination. The AAV vector successfully spread throughout the cerebellum, and the expression of mutant ataxin-3 was confirmed. Neuroimaging revealed a reduction in N-acetylaspartate (NAA) levels, whereas histological analysis showed significant damage to the Purkinje cell layer. Notably, the monkeys exhibited sleep disturbances, a prodromal symptom commonly observed in human patients with SCA3. AAV-mediated delivery of mutant ataxin-3 can effectively replicate the key pathological and clinical features of SCA3 in primates. This approach offers a promising new model for studying disease mechanisms and evaluating potential therapies.
2.Temporal Regulation of Cytokines and Growth Factors for Optimized Hematopoietic-Lineage Specification from Human Pluripotent Stem Cells
Jisoo PARK ; Hyebin KOH ; Eunsu JEON ; Kyungjun UH ; Sangjune KIM ; Jong-Hee LEE
International Journal of Stem Cells 2025;18(4):384-400
Human pluripotent stem cells (hPSCs) can be used to investigate hematopoietic development and have the potential to advance cell-based therapies and to facilitate developmental biology studies. However, efficient ex vivo differentiation into hematopoietic lineages, including red blood cells (RBCs) of the erythroid lineage and immune cells such as macrophages of the myeloid lineage, is hampered by the need for precise temporal regulation of cytokines and growth factors.In this study, we developed an optimized protocol for hematopoietic lineage specification from hPSCs by fine-tuning the temporal dynamics of cytokine and growth factor applications. Prolonged mesodermal specification in the absence of hemogenic cytokines significantly enhanced the generation of hematopoietic progenitors (CD34+ CD45+ ) with robust functional potential. Early administration of interleukin (IL)-3 during hematopoietic specification promoted progenitor expansion and maturation. Supplementation of bone morphogenetic protein 4 at the hematopoietic maturation stage enhanced the differentiation efficiency and preferentially drove myeloid lineage commitment toward macrophages at the expense of erythroid differentiation. The timing of erythropoietin administration was important in erythroid lineage commitment, and delayed treatment (day 10) enhanced erythroblast expansion and RBC production. By contrast, the timing of IL-6, GM-CSF, and M-CSF exposure did not significantly affect macrophage differentiation efficiency, suggesting that myeloid lineage specification follows a default pathway under optimized differentiation conditions. These findings suggest a refined, time-controlled strategy for directing hematopoietic differentiation from hPSCs, and provide insight into therapeutic blood cell production, regenerative medicine, and ex vivo modeling of hematopoietic disorders.

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