产品分类
PML Knockout HAP1 Cell Pool
- 产品描述
- 细胞复苏
- 细胞传代
- 细胞冻存
- 抗体验证结果
-
- 品牌: ELEMok138cn太阳集团529
- 商品名称: PML Knockout HAP1 Cell Pool
- 商品编号: LM01010140464
- Gene Symbol: PML MYL PP8675 RNF71 TRIM19
- Ensembl ID: ENSG00000140464
- Uniprot ID: P29590
- 宿主细胞 / 类型: HAP1/慢性粒细胞白血病
- NCBI Gene ID: 5371
- 规格: 1×10^6 cells/ 冻存管
- 筛选标记: N/A
- 生长特性: 贴壁细胞,上皮细胞样
- 培养条件: 37℃,5% CO2 的培养箱,1/3 到 1/5 传代
- 倍增时间: ~16 hours
- 生长培养基: IMDM+10% FBS+1% P/S
- 参考换液频率: 2~3次/周
- 支原体检测结果: 阴性
- 敲除效率(Sanger测序): >70%
- 蛋白质组验证结果: 已完成蛋白水平验证
- 抗体货号: LMAb01140464-1
- 目标基因介绍: Exhibits antiviral activity against both DNA and RNA viruses. The antiviral activity can involve one or several isoform(s) and can be enhanced by the permanent PML-NB-associated protein DAXX or by the recruitment of p53/TP53 within these structures. Isoform PML-4 restricts varicella zoster virus (VZV) via sequestration of virion capsids in PML-NBs thereby preventing their nuclear egress and inhibiting formation of infectious virus particles. The sumoylated isoform PML-4 restricts rabies virus by inhibiting viral mRNA and protein synthesis. The cytoplasmic isoform PML-14 can restrict herpes simplex virus-1 (HHV-1) replication by sequestering the viral E3 ubiquitin-protein ligase ICP0 in the cytoplasm. Isoform PML-6 shows restriction activity towards human cytomegalovirus (HCMV) and influenza A virus strains PR8(H1N1) and ST364(H3N2). Sumoylated isoform PML-4 and isoform PML-12 show antiviral activity against encephalomyocarditis virus (EMCV) by promoting nuclear sequestration of viral polymerase (P3D-POL) within PML NBs. Isoform PML-3 exhibits antiviral activity against poliovirus by inducing apoptosis in infected cells through the recruitment and the activation of p53/TP53 in the PML-NBs. Isoform PML-3 represses human foamy virus (HFV) transcription by complexing the HFV transactivator, bel1/tas, preventing its binding to viral DNA. PML may positively regulate infectious hepatitis C viral (HCV) production and isoform PML-2 may enhance adenovirus transcription.||Functions via its association with PML-nuclear bodies (PML-NBs) in a wide range of important cellular processes, including tumor suppression, transcriptional regulation, apoptosis, senescence, DNA damage response, and viral defense mechanisms. Acts as the scaffold of PML-NBs allowing other proteins to shuttle in and out, a process which is regulated by SUMO-mediated modifications and interactions. Isoform PML-4 has a multifaceted role in the regulation of apoptosis and growth suppression: activates RB1 and inhibits AKT1 via interactions with PP1 and PP2A phosphatases respectively, negatively affects the PI3K pathway by inhibiting MTOR and activating PTEN, and positively regulates p53/TP53 by acting at different levels (by promoting its acetylation and phosphorylation and by inhibiting its MDM2-dependent degradation). Isoform PML-4 also: acts as a transcriptional repressor of TBX2 during cellular senescence and the repression is dependent on a functional RBL2/E2F4 repressor complex, regulates double-strand break repair in gamma-irradiation-induced DNA damage responses via its interaction with WRN, acts as a negative regulator of telomerase by interacting with TERT, and regulates PER2 nuclear localization and circadian function. Isoform PML-6 inhibits specifically the activity of the tetrameric form of PKM. The nuclear isoforms (isoform PML-1, isoform PML-2, isoform PML-3, isoform PML-4 and isoform PML-5) in concert with SATB1 are involved in local chromatin-loop remodeling and gene expression regulation at the MHC-I locus. Isoform PML-2 is required for efficient IFN-gamma induced MHC II gene transcription via regulation of CIITA. Cytoplasmic PML is involved in the regulation of the TGF-beta signaling pathway. PML also regulates transcription activity of ELF4 and can act as an important mediator for TNF-alpha- and IFN-alpha-mediated inhibition of endothelial cell network formation and migration.
- 细胞开发路径: 采用CRISPR-RNP方法生成稳定KO Cell Pool;Sanger 测序结果显示KO Cell Pool敲除效率>70%
- 应用: 高敲除效率的基因敲除细胞池(KO Cell Pool),特别适用于初步功能分析、复杂疾病模型的开发、精准药物筛选以及广泛的基因发现研究。KO pool能够无需繁琐的单克隆挑选过程,直接应用于多种类型的测定和分析,大幅提升实验效率。
关键词:- PML MYL PP8675 RNF71 TRIM19
-
01. 在 37℃水浴中预热完全培养基。
02. 将冻存管在 37℃水浴中解冻 1-2 分钟。
03. 将冻存管转移到生物安全柜中,并用 70% 乙醇擦拭表面。
04. 拧开冻存管管盖,将细胞悬液轻轻转移到含有 9mL 完全培养基的无菌离心管中。
05. 在室温下以 125g 离心 5-7 分钟,弃上清。
06. 用 5mL 的完整培养基重悬细胞沉淀,将细胞悬液转移到 T25 培养瓶中。
07. 将细胞转移到 37℃,5% CO2 的培养箱中培养。
08. 参考传代比例:1/3 到 1/5 传代,2-3 天长满。 -
01. 待培养瓶中细胞汇合度至 80%-90% 以上,可进行细胞传代。
02. 将培养基、PBS、胰酶(0.25%Trypsin_EDTA Gibco 25200-056) 等从 4℃冰箱中拿出, 置于 37℃水浴中温度接近 37℃时取出并在瓶子表面喷洒 75% 酒精后置于生物安全柜中。03. 从培养箱中取出待传代的培养瓶,瓶身喷洒 75% 酒精后置于生物安全柜中。
04. 为避免冲散细胞,沿培养瓶上壁 PBS 润洗细胞,清洗细胞后弃去,T25 加 2mL。
05. 加入对应体积的胰酶(T75 加 1.5mL, T25 加 0.5mL) ,并轻轻晃动瓶身使胰酶平铺满细胞 底部。可根据实际情况适当增加或减少用量。约 1-2min 后大部分细胞脱落时,加入对应体积的完全培养基终止消化,并用 5mL 移液管轻轻吹打至细胞全部脱落。
06. 将细胞悬液转移至 15mL 离心管,悬液 300g 离心 5min,弃上清。
07. 移取 5mL 完全培养基重悬细胞,按需求调整接种比例,并补充培养瓶中完全培养基,T75 加至 13-15mL,T25 加至 5mL,加 1% 双抗。
08. 盖上瓶盖拧紧后轻轻晃动瓶身,使细胞混合均匀后置于 37℃,5% CO2 培养箱中。 -
01. 准备冻存液,并提前预冷。
02. 确保待冻存的细胞满足冻存要求,用显微镜检查以下状态:健康的外观及形态特征、所处生 长周期(对数晚期)、无污染或衰退迹象。
03. 对细胞进行消化及离心处理(具体步骤参考传代培养流程)
04. 按照每管 1mL 的量添加冻存液重悬细胞,吹打均匀后分装至冻存管。
05. 将细胞放在程序降温盒中,在 -80℃冰箱中冷冻。
06. 后续将细胞转移到液氮罐中,以便长期储存。 - 采用特异性单克隆抗体对野生型细胞和KO细胞的裂解液同时进行Western Blot(WB)检测,目标靶蛋白条带在WT细胞中显示,在KO细胞中消失或减弱。
产品类型: 基因敲除细胞池(蛋白水平已验证)
细胞系信息
Gene Symbol
PML MYL PP8675 RNF71 TRIM19
NCBI Gene ID
5371
Ensembl ID
ENSG00000140464
Uniprot ID
P29590
筛选标记
N/A
宿主细胞 / 类型
HAP1/慢性粒细胞白血病
规格
1×10^6 cells/ 冻存管
生长培养基
IMDM+10% FBS+1% P/S
生长特性
贴壁细胞,上皮细胞样
培养条件
37℃,5% CO2 的培养箱,1/3 到 1/5 传代
倍增时间
~16 hours
参考换液频率
2~3次/周
支原体检测结果
阴性
敲除验证
敲除效率(Sanger测序)
>70%
蛋白质组验证结果
已完成蛋白水平验证
抗体货号
LMAb01140464-1
抗体验证结果
细胞系说明
目标基因介绍
Exhibits antiviral activity against both DNA and RNA viruses. The antiviral activity can involve one or several isoform(s) and can be enhanced by the permanent PML-NB-associated protein DAXX or by the recruitment of p53/TP53 within these structures. Isoform PML-4 restricts varicella zoster virus (VZV) via sequestration of virion capsids in PML-NBs thereby preventing their nuclear egress and inhibiting formation of infectious virus particles. The sumoylated isoform PML-4 restricts rabies virus by inhibiting viral mRNA and protein synthesis. The cytoplasmic isoform PML-14 can restrict herpes simplex virus-1 (HHV-1) replication by sequestering the viral E3 ubiquitin-protein ligase ICP0 in the cytoplasm. Isoform PML-6 shows restriction activity towards human cytomegalovirus (HCMV) and influenza A virus strains PR8(H1N1) and ST364(H3N2). Sumoylated isoform PML-4 and isoform PML-12 show antiviral activity against encephalomyocarditis virus (EMCV) by promoting nuclear sequestration of viral polymerase (P3D-POL) within PML NBs. Isoform PML-3 exhibits antiviral activity against poliovirus by inducing apoptosis in infected cells through the recruitment and the activation of p53/TP53 in the PML-NBs. Isoform PML-3 represses human foamy virus (HFV) transcription by complexing the HFV transactivator, bel1/tas, preventing its binding to viral DNA. PML may positively regulate infectious hepatitis C viral (HCV) production and isoform PML-2 may enhance adenovirus transcription.||Functions via its association with PML-nuclear bodies (PML-NBs) in a wide range of important cellular processes, including tumor suppression, transcriptional regulation, apoptosis, senescence, DNA damage response, and viral defense mechanisms. Acts as the scaffold of PML-NBs allowing other proteins to shuttle in and out, a process which is regulated by SUMO-mediated modifications and interactions. Isoform PML-4 has a multifaceted role in the regulation of apoptosis and growth suppression: activates RB1 and inhibits AKT1 via interactions with PP1 and PP2A phosphatases respectively, negatively affects the PI3K pathway by inhibiting MTOR and activating PTEN, and positively regulates p53/TP53 by acting at different levels (by promoting its acetylation and phosphorylation and by inhibiting its MDM2-dependent degradation). Isoform PML-4 also: acts as a transcriptional repressor of TBX2 during cellular senescence and the repression is dependent on a functional RBL2/E2F4 repressor complex, regulates double-strand break repair in gamma-irradiation-induced DNA damage responses via its interaction with WRN, acts as a negative regulator of telomerase by interacting with TERT, and regulates PER2 nuclear localization and circadian function. Isoform PML-6 inhibits specifically the activity of the tetrameric form of PKM. The nuclear isoforms (isoform PML-1, isoform PML-2, isoform PML-3, isoform PML-4 and isoform PML-5) in concert with SATB1 are involved in local chromatin-loop remodeling and gene expression regulation at the MHC-I locus. Isoform PML-2 is required for efficient IFN-gamma induced MHC II gene transcription via regulation of CIITA. Cytoplasmic PML is involved in the regulation of the TGF-beta signaling pathway. PML also regulates transcription activity of ELF4 and can act as an important mediator for TNF-alpha- and IFN-alpha-mediated inhibition of endothelial cell network formation and migration.
细胞开发路径
采用CRISPR-RNP方法生成稳定KO Cell Pool;Sanger 测序结果显示KO Cell Pool敲除效率>70%
应用
高敲除效率的基因敲除细胞池(KO Cell Pool),特别适用于初步功能分析、复杂疾病模型的开发、精准药物筛选以及广泛的基因发现研究。KO pool能够无需繁琐的单克隆挑选过程,直接应用于多种类型的测定和分析,大幅提升实验效率。
细胞培养说明
细胞复苏
01. 在 37℃水浴中预热完全培养基。
02. 将冻存管在 37℃水浴中解冻 1-2 分钟。
03. 将冻存管转移到生物安全柜中,并用 70% 乙醇擦拭表面。
04. 拧开冻存管管盖,将细胞悬液轻轻转移到含有 9mL 完全培养基的无菌离心管中。
05. 在室温下以 125g 离心 5-7 分钟,弃上清。
06. 用 5mL 的完整培养基重悬细胞沉淀,将细胞悬液转移到 T25 培养瓶中。
07. 将细胞转移到 37℃,5% CO2 的培养箱中培养。
08. 参考传代比例:1/3 到 1/5 传代,2-3 天长满。
细胞传代
01. 待培养瓶中细胞汇合度至 80%-90% 以上,可进行细胞传代。
02. 将培养基、PBS、胰酶(0.25%Trypsin_EDTA Gibco 25200-056) 等从 4℃冰箱中拿出, 置于 37℃水浴中温度接近 37℃时取出并在瓶子表面喷洒 75% 酒精后置于生物安全柜中。
03. 从培养箱中取出待传代的培养瓶,瓶身喷洒 75% 酒精后置于生物安全柜中。
04. 为避免冲散细胞,沿培养瓶上壁 PBS 润洗细胞,清洗细胞后弃去,T25 加 2mL。
05. 加入对应体积的胰酶(T75 加 1.5mL, T25 加 0.5mL) ,并轻轻晃动瓶身使胰酶平铺满细胞 底部。可根据实际情况适当增加或减少用量。约 1-2min 后大部分细胞脱落时,加入对应体积的完全培养基终止消化,并用 5mL 移液管轻轻吹打至细胞全部脱落。
06. 将细胞悬液转移至 15mL 离心管,悬液 300g 离心 5min,弃上清。
07. 移取 5mL 完全培养基重悬细胞,按需求调整接种比例,并补充培养瓶中完全培养基,T75 加至 13-15mL,T25 加至 5mL,加 1% 双抗。
08. 盖上瓶盖拧紧后轻轻晃动瓶身,使细胞混合均匀后置于 37℃,5% CO2 培养箱中。
细胞冻存
01. 准备冻存液,并提前预冷。
02. 确保待冻存的细胞满足冻存要求,用显微镜检查以下状态:健康的外观及形态特征、所处生 长周期(对数晚期)、无污染或衰退迹象。
03. 对细胞进行消化及离心处理(具体步骤参考传代培养流程)
04. 按照每管 1mL 的量添加冻存液重悬细胞,吹打均匀后分装至冻存管。
05. 将细胞放在程序降温盒中,在 -80℃冰箱中冷冻。
06. 后续将细胞转移到液氮罐中,以便长期储存。