Pygl-flox Mouse
Common Name
Pygl-flox
제품 ID
S-CKO-18300
Backgroud
C57BL/6JCya
품종 계통계통 ID
CKOCMP-110095-Pygl-B6J-VB
상태
이 마우스 계통을 논문에서 사용할 경우, “Pygl-flox Mouse (카탈로그 번호 S-CKO-18300)은 Cyagen에서 구입하였습니다.”라고 명시해 주시기 바랍니다.
구매 가능한 제품 종류
연령
Genotype
성별
수량
표준 제공 조건은 최소 3마리의 이형접합(heterozygous) 보균자를 보장합니다. 동형접합(homozygous) 보균자 및/또는 특정 성별에 대한 브리딩 서비스도 제공됩니다.
기본 정보
품종 계통
Pygl-flox
품종 계통계통 ID
CKOCMP-110095-Pygl-B6J-VB
유전자명
제품 ID
S-CKO-18300
유전자 별칭
--
배경
C57BL/6JCya
유전자 공식 전체 명칭
liver glycogen phosphorylase
NCBI ID
변형 내용
Conditional knockout
염색체
Chr 12
Phenotype
Datasheet
적용 분야
--
품종 계통 설명
Ensembl 전사체 ID
ENSMUST00000071250
NCBI 전사체 ID
NM_133198
타겟 영역
Exon 3
유효 영역 크기
~1.0 kb
유전자 연구 개요
PYGL, short for glycogen phosphorylase L, is a key enzyme in the glycogen metabolism pathway, specifically involved in glycogenolysis. It mobilizes glycogen to fuel glycolysis, thus playing a crucial role in glucose metabolism regulation. This process is associated with multiple cellular functions and is of great biological importance [1,3,4,7,8].
In pancreatic cancer, PYGL overexpression promotes cell migration, invasion, and liver metastasis, while knockdown has opposite effects. Hypoxia can induce PYGL expression in a HIF1α -dependent manner, leading to glycogen accumulation and subsequent induction of the epithelial-mesenchymal transition (EMT) process through glycolysis, which is related to tumor invasion and metastasis [1].
In head and neck squamous cell carcinoma (HNSCC), PYGL is identified as a metabolism-related oncogenic biomarker promoting tumor progression, metastasis, and chemotherapy resistance via the GSH/ROS/p53 pathway [2].
In gliomas, high PYGL expression is an independent predictor of poor prognosis, and it is involved in glioma cell proliferation, glycolysis, apoptosis, and metabolic activities. Hypoxia-induced PYGL expression regulated by HIF1α also plays a role in glioma progression [5,6,8].
Moreover, PYGL mutations can cause glycogen storage disease type VI, mainly characterized by hepatomegaly, growth retardation, and elevated liver transaminases in untreated children [9].
In conclusion, PYGL is essential for glucose metabolism, with its function intricately linked to the progression of various cancers like pancreatic, HNSCC, and glioma, as well as in glycogen storage diseases. Studies on PYGL, especially through gene-knockout or conditional-knockout models (not explicitly detailed in these references but generally valuable for such gene-function studies), can provide insights into the underlying mechanisms of these diseases, potentially guiding the development of new therapeutic strategies.
References:
1. Ji, Qian, Li, Hengchao, Cai, Zhiwei, Zhang, Xiaoxin, Li, Rongkun. 2023. PYGL-mediated glucose metabolism reprogramming promotes EMT phenotype and metastasis of pancreatic cancer. In International journal of biological sciences, 19, 1894-1909. doi:10.7150/ijbs.76756. https://pubmed.ncbi.nlm.nih.gov/37063425/
2. Guan, Jiezhong, Xu, Xi, Qiu, Guo, Cheng, Bin, Yang, Bo. 2023. Cellular hierarchy framework based on single-cell/multi-patient sample sequencing reveals metabolic biomarker PYGL as a therapeutic target for HNSCC. In Journal of experimental & clinical cancer research : CR, 42, 162. doi:10.1186/s13046-023-02734-w. https://pubmed.ncbi.nlm.nih.gov/37420300/
3. Chen, Yan-Fang, Zhu, Jing-Jing, Li, Jing, Ye, Xin-Shan. . O-GlcNAcylation increases PYGL activity by promoting phosphorylation. In Glycobiology, 32, 101-109. doi:10.1093/glycob/cwab114. https://pubmed.ncbi.nlm.nih.gov/34939084/
4. Liu, Qingxu, Li, Jiaxin, Zhang, Weiji, Chen, Lanfen, Zhou, Dawang. 2021. Glycogen accumulation and phase separation drives liver tumor initiation. In Cell, 184, 5559-5576.e19. doi:10.1016/j.cell.2021.10.001. https://pubmed.ncbi.nlm.nih.gov/34678143/
5. Zhao, Chang-Yi, Hua, Chun-Hui, Li, Chang-Hua, Zheng, Rui-Zhe, Li, Xin-Yuan. 2021. High PYGL Expression Predicts Poor Prognosis in Human Gliomas. In Frontiers in neurology, 12, 652931. doi:10.3389/fneur.2021.652931. https://pubmed.ncbi.nlm.nih.gov/34177761/
6. Zhu, Yongjie, Liu, Zhendong, Lv, Dongbo, Liu, Runze, Gao, Yanzheng. 2022. Identification of PYGL as a key prognostic gene of glioma by integrated bioinformatics analysis. In Future oncology (London, England), 18, 579-596. doi:10.2217/fon-2021-0759. https://pubmed.ncbi.nlm.nih.gov/35037470/
7. Zhang, Dian-Guang, Zhao, Tao, Xu, Xiao-Jian, Jiang, Ming, Luo, Zhi. 2022. Selenoprotein F (SELENOF)-mediated AKT1-FOXO3a-PYGL axis contributes to selenium supranutrition-induced glycogenolysis and lipogenesis. In Biochimica et biophysica acta. Gene regulatory mechanisms, 1865, 194814. doi:10.1016/j.bbagrm.2022.194814. https://pubmed.ncbi.nlm.nih.gov/35439639/
8. Cao, Tingyu, Wang, Jinchun. 2024. PYGL regulation of glycolysis and apoptosis in glioma cells under hypoxic conditions via HIF1α-dependent mechanisms. In Translational cancer research, 13, 5627-5648. doi:10.21037/tcr-24-1974. https://pubmed.ncbi.nlm.nih.gov/39525037/
9. Luo, Xiaomei, Hu, Jiacheng, Gao, Xueren, Gu, Xuefan, Qiu, Wenjuan. 2020. Novel PYGL mutations in Chinese children leading to glycogen storage disease type VI: two case reports. In BMC medical genetics, 21, 74. doi:10.1186/s12881-020-01010-4. https://pubmed.ncbi.nlm.nih.gov/32268899/
품질 관리 기준
정자 검사
동결 보존 전: 정자 농도 측정 및 정자 생존율 평가.
동결 보존 후: 각 배치에서 동결 보존된 정자 바이알 1개를 선택하여 체외수정(in vitro fertilization)에 사용합니다.
Environmental Standards:
SPFAvailable Region:
GlobalSource:
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