Sap30bp-flox Mouse
一般名
Sap30bp-flox
製品ID
S-CKO-12271
背景情報
C57BL/6JCya
系統ID
CKOCMP-57230-Sap30bp-B6J-VA
状況
このマウス系統を論文で使用する場合は、「Sap30bp-flox Mouse(カタログ番号S-CKO-12271)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
Sap30bp-flox
系統ID
CKOCMP-57230-Sap30bp-B6J-VA
遺伝子名
製品ID
S-CKO-12271
遺伝子別名
Hcngp, 2700016D05Rik
遺伝子別名
C57BL/6JCya
NCBI ID
修正
Conditional knockout
染色体
Chr 11
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
ENSMUST00000140991
NCBIトランスクリプトID
NM_020483
ターゲット領域
Exon 6
有効領域の大きさ
~0.9 kb
遺伝子研究の概要
Sap30bp, a factor with relatively less-characterized functions previously, has emerged as significant in multiple biological processes. It is involved in the regulation of pre-mRNA splicing and may also play a role in histone deacetylase activity regulation in plants [1,8]. In the context of human pre-mRNA splicing, it is associated with the splicing process of a subset of short introns and acts as a critical activator of CDK11, a druggable target for cancer therapy [1,2].
In a case-control study based on the Han Chinese population, the genetic polymorphism of SAP30BP, specifically SNP rs820218, was found to be associated with the susceptibility of rotator cuff tear, with the A allele conferring less susceptibility [3]. However, in an Amazonian population, an association of the genetic variant rs820218 of the SAP30BP gene with rotator cuff tears was not established, though the presence of the A allele still indicated protection [4]. Multiple reviews also suggest the need for further investigation into the association between SAP30BP rs820218 and rotator cuff injuries [5,6,7].
In conclusion, Sap30bp has essential functions in pre-mRNA splicing regulation, potentially through its role as a CDK11 activator. Its genetic polymorphisms are associated with the susceptibility of rotator cuff tears, though more research is needed to clarify this relationship. Understanding Sap30bp can provide insights into RNA splicing-related biological processes and potentially into the genetic basis of rotator cuff-related diseases.
References:
1. Wang, Changshou, Xu, Lin, Du, Chen, Zhou, Yu, Cheng, Hong. 2023. CDK11 requires a critical activator SAP30BP to regulate pre-mRNA splicing. In The EMBO journal, 42, e114051. doi:10.15252/embj.2023114051. https://pubmed.ncbi.nlm.nih.gov/38059508/
2. Fukumura, Kazuhiro, Sperotto, Luca, Seuß, Stefanie, Sattler, Michael, Mayeda, Akila. 2023. SAP30BP interacts with RBM17/SPF45 to promote splicing in a subset of human short introns. In Cell reports, 42, 113534. doi:10.1016/j.celrep.2023.113534. https://pubmed.ncbi.nlm.nih.gov/38065098/
3. Tian, Bin, Kang, Xin, Zhang, Liang, Zheng, Jiang, Zhao, Zandong. 2020. SAP30BP gene is associated with the susceptibility of rotator cuff tear: a case-control study based on Han Chinese population. In Journal of orthopaedic surgery and research, 15, 356. doi:10.1186/s13018-020-01888-z. https://pubmed.ncbi.nlm.nih.gov/32843068/
4. Barros, Rui Sergio Monteiro de, Sant' Anna, Carla de Castro, Alcantara, Diego Di Felipe Ávila, Candido, Atylla de Andrade, Burbano, Rommel Mario Rodriguez. 2023. Association between the rs820218 Variant within the SAP30BP Gene and Rotator Cuff Rupture in an Amazonian Population. In Genes, 14, . doi:10.3390/genes14020367. https://pubmed.ncbi.nlm.nih.gov/36833294/
5. Collins, Malcolm, September, Alison V. 2023. Are commercial genetic injury tests premature? In Scandinavian journal of medicine & science in sports, 33, 1584-1597. doi:10.1111/sms.14406. https://pubmed.ncbi.nlm.nih.gov/37243491/
6. Longo, Umile Giuseppe, Candela, Vincenzo, Berton, Alessandra, Nazarian, Ara, Denaro, Vincenzo. 2019. Genetic basis of rotator cuff injury: a systematic review. In BMC medical genetics, 20, 149. doi:10.1186/s12881-019-0883-y. https://pubmed.ncbi.nlm.nih.gov/31477042/
7. Dabija, Dominique I, Gao, Chan, Edwards, Todd L, Kuhn, John E, Jain, Nitin B. 2017. Genetic and familial predisposition to rotator cuff disease: a systematic review. In Journal of shoulder and elbow surgery, 26, 1103-1112. doi:10.1016/j.jse.2016.11.038. https://pubmed.ncbi.nlm.nih.gov/28162885/
8. Liu, Zhongyuan, Lei, Xiaojin, Wang, Peilong, Li, Xinpin, Gao, Caiqiu. 2019. Overexpression of ThSAP30BP from Tamarix hispida improves salt tolerance. In Plant physiology and biochemistry : PPB, 146, 124-132. doi:10.1016/j.plaphy.2019.11.020. https://pubmed.ncbi.nlm.nih.gov/31743857/
品質管理基準
精子検査
凍結前の精子濃度を測定し、精子の生存能力の判定します。
凍結後の精子では、各バッチから1本の凍結保存された精子を選び出し、体外受精に使用します。
環境基準:
SPF対応地域:
グローバル由来:
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