基本情報
- 所属
- 自治医科大学 医学部生化学講座 病態生化学部門 講師
- 学位
- 博士(医学)(自治医科大学大学院)
- J-GLOBAL ID
- 201401086045181561
- researchmap会員ID
- B000236665
- 外部リンク
経歴
4-
2021年5月 - 現在
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2020年1月 - 2021年4月
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2011年4月 - 2019年12月
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2010年4月 - 2011年3月
受賞
5論文
41-
Arteriosclerosis, thrombosis, and vascular biology 44(12) 2616-2627 2024年12月BACKGROUND: PC (protein C) is a plasma anticoagulant encoded by PROC; mutation in both PROC alleles results in neonatal purpura fulminans-a fatal systemic thrombotic disorder. In the present study, we aimed to develop a genome editing treatment to cure congenital PC deficiency. METHODS: We generated an engineered APC (activated PC) to insert a furin-cleaving peptide sequence between light and heavy chains. The engineered PC was expressed in the liver of mice using an adeno-associated virus vector or CRISPR/Cas9 (clustered regularly interspaced short palindromic repeats/clustered regularly interspaced short palindromic repeat-associated 9)-mediated genome editing using an adeno-associated virus vector in vivo. RESULTS: The engineered PC could be released in its activated form and significantly prolonged the plasma coagulation time independent of the cofactor activity of PS (protein S) in vitro. The adeno-associated virus vector-mediated expression of the engineered PC, but not wild-type PC, prolonged coagulation time owing to the inhibition of activated coagulation FV (factor V) in a dose-dependent manner and abolished pathological thrombus formation in vivo in C57BL/6J mice. The insertion of EGFP (enhanced green fluorescent protein) sequence conjugated with self-cleaving peptide sequence at Alb locus via neonatal in vivo genome editing using adeno-associated virus vector resulted in the expression of EGFP in 7% of liver cells, mainly via homology-directed repair, in mice. Finally, we succeeded in improving the survival of PC-deficient mice by expressing the engineered PC via neonatal genome editing in vivo. CONCLUSIONS: These results suggest that the expression of engineered PC via neonatal genome editing is a potential cure for severe congenital PC deficiency.
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Blood advances 7(22) 7017-7027 2023年11月28日The importance of genetic diagnosis for patients with hemophilia has been recently demonstrated. However, the pathological variant cannot be identified in some patients. Here, we aimed to identify the pathogenic intronic variant causing hemophilia A using induced pluripotent stem cells (iPSCs) from patients and genome editing. We analyzed siblings with moderate hemophilia A and without abnormalities in the F8 exon. Next-generation sequencing of the entire F8 revealed 23 common intron variants. Variant effect predictor software indicated that the deep intronic variant at c.5220-8563A>G (intron 14) might act as a splicing acceptor. We developed iPSCs from patients and used genome editing to insert the elongation factor 1α promoter to express F8 messenger RNA (mRNA). Then, we confirmed the existence of abnormal F8 mRNA derived from aberrant splicing, resulting in a premature terminal codon as well as a significant reduction in F8 mRNA in iPSCs due to nonsense-mediated RNA decay. Gene repair by genome editing recovered whole F8 mRNA expression. Introduction of the intron variant into human B-domain-deleted F8 complementary DNA suppressed factor VIII (FVIII) activity and produced abnormal FVIII lacking the light chain in HEK293 cells. Furthermore, genome editing of the intron variant restored FVIII production. In summary, we have directly proven that the deep intronic variant in F8 results in aberrant splicing, leading to abnormal mRNA and nonsense-mediated RNA decay. Additionally, genome editing targeting the variant restored F8 mRNA and FVIII production. Our approach could be useful not only for identifying causal variants but also for verifying the therapeutic effect of personalized genome editing.
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Molecular Therapy - Methods & Clinical Development 30 502-514 2023年8月
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PAM-flexible Cas9-mediated base editing of a hemophilia B mutation in induced pluripotent stem cellsCommunications Medicine 3(1) 2023年4月19日Abstract Background Base editing via CRISPR-Cas9 has garnered attention as a method for correcting disease-specific mutations without causing double-strand breaks, thereby avoiding large deletions and translocations in the host chromosome. However, its reliance on the protospacer adjacent motif (PAM) can limit its use. We aimed to restore a disease mutation in a patient with severe hemophilia B using base editing with SpCas9-NG, a modified Cas9 with the board PAM flexibility. Methods We generated induced pluripotent stem cells (iPSCs) from a patient with hemophilia B (c.947T>C; I316T) and established HEK293 cells and knock-in mice expressing the patient’s F9 cDNA. We transduced the cytidine base editor (C>T), including the nickase version of Cas9 (wild-type SpCas9 or SpCas9-NG), into the HEK293 cells and knock-in mice through plasmid transfection and an adeno-associated virus vector, respectively. Results Here we demonstrate the broad PAM flexibility of SpCas9-NG near the mutation site. The base-editing approach using SpCas9-NG but not wild-type SpCas9 successfully converts C to T at the mutation in the iPSCs. Gene-corrected iPSCs differentiate into hepatocyte-like cells in vitro and express substantial levels of F9 mRNA after subrenal capsule transplantation into immunodeficient mice. Additionally, SpCas9-NG–mediated base editing corrects the mutation in both HEK293 cells and knock-in mice, thereby restoring the production of the coagulation factor. Conclusion A base-editing approach utilizing the broad PAM flexibility of SpCas9-NG can provide a solution for the treatment of genetic diseases, including hemophilia B.
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The Journal of Gene Medicine 2023年4月12日
MISC
22-
EUROPEAN JOURNAL OF IMMUNOLOGY 46 145-145 2016年8月
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EUROPEAN JOURNAL OF IMMUNOLOGY 46 444-444 2016年8月
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EUROPEAN JOURNAL OF IMMUNOLOGY 46 749-750 2016年8月
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MOLECULAR THERAPY 21 S91-S92 2013年6月
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HUMAN GENE THERAPY 23(10) A85-A85 2012年10月
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JOURNAL OF TISSUE ENGINEERING AND REGENERATIVE MEDICINE 6 288-289 2012年9月
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JOURNAL OF THROMBOSIS AND HAEMOSTASIS 9 232-233 2011年7月
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JOURNAL OF THROMBOSIS AND HAEMOSTASIS 9 424-424 2011年7月
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日本血栓止血学会誌 21(2) 199-199 2010年4月
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JOURNAL OF GENE MEDICINE 8(3) 395-395 2006年3月
所属学協会
5共同研究・競争的資金等の研究課題
3-
日本学術振興会 科学研究費助成事業 2021年4月 - 2024年3月
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日本学術振興会 科学研究費助成事業 2014年4月 - 2017年3月
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日本学術振興会 科学研究費助成事業 2012年4月 - 2015年3月