Ccdc32-flox Mouse
一般名
Ccdc32-flox
製品ID
S-CKO-09782
背景情報
C57BL/6JCya
系統ID
CKOCMP-269336-Ccdc32-B6J-VA
状況
このマウス系統を論文で使用する場合は、「Ccdc32-flox Mouse(カタログ番号S-CKO-09782)はサイアジェンから購入しました。」と引用してください。
製品タイプ
年齢
遺伝子型
性別
数量
標準的な配送方法では、少なくとも3匹のヘテロ接合体キャリアを保証しています。ホモ接合体キャリアや指定された性別の個体の繁殖サービスも利用可能です。
基本情報
系統名
Ccdc32-flox
系統ID
CKOCMP-269336-Ccdc32-B6J-VA
遺伝子名
製品ID
S-CKO-09782
遺伝子別名
Gm631
遺伝子別名
C57BL/6JCya
NCBI ID
修正
Conditional knockout
染色体
Chr 2
表現型
アプリケーション
--
さらに
系統詳細
EnsemblトランスクリプトID
ENSMUST00000036470
NCBIトランスクリプトID
NM_199310
ターゲット領域
Exon 3
有効領域の大きさ
~2.0 kb
遺伝子研究の概要
CCDC32, also known as C15orf57, is an endocytic accessory protein with a significant role in clathrin-mediated endocytosis (CME), a process essential for maintaining cellular homeostasis [1]. It is also involved in the assembly of the AP2 adaptor complex, a key player in CME [2].
Loss-of-function mutations in CCDC32 cause a congenital syndrome characterized by craniofacial, cardiac, and neurodevelopmental anomalies. Zebrafish models with ccdc32 depletion recapitulate human phenotypes, and ccdc32 is required for normal cilia formation in zebrafish embryos and mammalian cell culture, suggesting ciliary defects contribute to the disorder's pathomechanism [3]. In patients with cardio-facio-neuro-developmental syndrome (CFNDS), homozygous loss-of-function variants in CCDC32 have been identified, and ccdc32 deletion in zebrafish implies a ciliary contribution to the pathomechanism [4]. A novel homozygous deletion in CCDC32 gene was also reported to cause CFNDS [5]. Additionally, CCDC32 gene fusions, such as CCDC32-CBX3, were found in MYCN non-amplified neuroblastoma and acute myeloid leukemia patients, affecting gene expression and potentially contributing to treatment resistance [6,7]. CCDC32 was also identified as a new gene with potential biological relevance to colorectal cancer through gene-gene interaction studies [8], and it was found to interact with the C-terminal fragment of annexin A2 in yeast two-hybrid screening [9].
In summary, CCDC32 is crucial for clathrin-mediated endocytosis and AP2 adaptor complex assembly. Its loss-of-function mutations lead to severe congenital syndromes involving craniofacial, cardiac, and neurodevelopmental anomalies. The use of zebrafish models has been instrumental in understanding its role in these disease conditions. Studies on gene fusions and interactions of CCDC32 also suggest its potential involvement in various cancers, highlighting its significance in multiple biological processes and disease areas.
References:
1. Yang, Ziyan, Yang, Changsong, Huang, Zheng, Schmid, Sandra L, Chen, Zhiming. 2025. CCDC32 stabilizes clathrin-coated pits and drives their invagination. In bioRxiv : the preprint server for biology, , . doi:10.1101/2024.06.26.600785. https://pubmed.ncbi.nlm.nih.gov/38979322/
2. Wan, Chun, Puscher, Harrison, Ouyang, Yan, Yin, Qian, Shen, Jingshi. 2024. An AAGAB-to-CCDC32 handover mechanism controls the assembly of the AP2 adaptor complex. In Proceedings of the National Academy of Sciences of the United States of America, 121, e2409341121. doi:10.1073/pnas.2409341121. https://pubmed.ncbi.nlm.nih.gov/39145939/
3. Harel, Tamar, Griffin, John N, Arbogast, Thomas, Elpeleg, Orly, Katsanis, Nicholas. . Loss of function mutations in CCDC32 cause a congenital syndrome characterized by craniofacial, cardiac and neurodevelopmental anomalies. In Human molecular genetics, 29, 1489-1497. doi:10.1093/hmg/ddaa073. https://pubmed.ncbi.nlm.nih.gov/32307552/
4. Abdalla, Ebtesam, Alawi, Malik, Meinecke, Peter, Kutsche, Kerstin, Harms, Frederike L. 2022. Cardiofacioneurodevelopmental syndrome: Report of a novel patient and expansion of the phenotype. In American journal of medical genetics. Part A, 188, 2448-2453. doi:10.1002/ajmg.a.62762. https://pubmed.ncbi.nlm.nih.gov/35451546/
5. Fernandes da Rocha, Diogo, Quental, Rita, Grangeia, Ana, Pinto Moura, Carla. 2024. A novel homozygous deletion in CCDC32 gene causing cardiofacioneurodevelopmental syndrome: the fourth patient reported. In Clinical dysmorphology, 33, 114-117. doi:10.1097/MCD.0000000000000501. https://pubmed.ncbi.nlm.nih.gov/38818818/
6. Lee, Eunjin, Lee, Ji Won, Lee, Boram, Sung, Ki Woong, Park, Woong-Yang. 2020. Genomic profile of MYCN non-amplified neuroblastoma and potential for immunotherapeutic strategies in neuroblastoma. In BMC medical genomics, 13, 171. doi:10.1186/s12920-020-00819-5. https://pubmed.ncbi.nlm.nih.gov/33172452/
7. Xu, Yi, Li, Shengwen Calvin, Xiao, Jeffrey, Cao, Huynh, Zhong, Jiang F. 2025. Exploring treatment-driven subclonal evolution of prognostic triple biomarkers: Dual gene fusions and chimeric RNA variants in novel subtypes of acute myeloid leukemia patients with KMT2A rearrangement. In Drug resistance updates : reviews and commentaries in antimicrobial and anticancer chemotherapy, 79, 101199. doi:10.1016/j.drup.2024.101199. https://pubmed.ncbi.nlm.nih.gov/39823827/
8. Kafaie, Somayeh, Xu, Ling, Hu, Ting. 2020. Statistical methods with exhaustive search in the identification of gene-gene interactions for colorectal cancer. In Genetic epidemiology, 45, 222-234. doi:10.1002/gepi.22372. https://pubmed.ncbi.nlm.nih.gov/33231893/
9. Li, Qun, Laumonnier, Yves, Syrovets, Tatiana, Simmet, Thomas. 2011. Yeast two-hybrid screening of proteins interacting with plasmin receptor subunit: C-terminal fragment of annexin A2. In Acta pharmacologica Sinica, 32, 1411-8. doi:10.1038/aps.2011.121. https://pubmed.ncbi.nlm.nih.gov/21963895/
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