PARK7 Knockout A549 Cell Pool

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LM01100116288

产品编号: LM01100116288

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隐藏域元素占位

  • 产品描述
  • 细胞复苏
  • 细胞传代
  • 细胞冻存
  • 抗体验证结果
    • 品牌: ELEM粒曼
    • 商品名称: PARK7 Knockout A549 Cell Pool
    • 商品编号: LM01100116288
    • Gene Symbol: PARK7
    • Ensembl ID: ENSG00000116288
    • Uniprot ID: Q99497
    • 宿主细胞 / 类型: A549/人非小细胞肺癌细胞
    • NCBI Gene ID: 11315
    • 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,1/2 到 1/3 传代
    • 倍增时间: ~22 hours
    • 生长培养基: MEM+10%FBS+100U/ml Penicillin-Strep
    • 参考换液频率: 2-3天换液
    • 支原体检测结果: 阴性
    • 敲除效率(Sanger测序): 93%
    • 蛋白质组验证结果: N/A
    • 抗体货号: LMAb01116288
    • 目标基因介绍: Multifunctional protein with controversial molecular function which plays an important role in cell protection against oxidative stress and cell death acting as oxidative stress sensor and redox-sensitive chaperone and protease (PubMed:17015834, PubMed:20304780, PubMed:18711745, PubMed:12796482, PubMed:19229105, PubMed:25416785, PubMed:26995087, PubMed:28993701). It is involved in neuroprotective mechanisms like the stabilization of NFE2L2 and PINK1 proteins, male fertility as a positive regulator of androgen signaling pathway as well as cell growth and transformation through, for instance, the modulation of NF-kappa-B signaling pathway (PubMed:12612053, PubMed:15502874, PubMed:14749723, PubMed:17015834, PubMed:21097510, PubMed:18711745). Has been described as a protein and nucleotide deglycase that catalyzes the deglycation of the Maillard adducts formed between amino groups of proteins or nucleotides and reactive carbonyl groups of glyoxals (PubMed:25416785, PubMed:28596309). But this function is rebuted by other works (PubMed:27903648, PubMed:31653696). As a protein deglycase, repairs methylglyoxal- and glyoxal-glycated proteins, and releases repaired proteins and lactate or glycolate, respectively. Deglycates cysteine, arginine and lysine residues in proteins, and thus reactivates these proteins by reversing glycation by glyoxals. Acts on early glycation intermediates (hemithioacetals and aminocarbinols), preventing the formation of advanced glycation endproducts (AGE) that cause irreversible damage (PubMed:25416785, PubMed:28013050, PubMed:26995087). Also functions as a nucleotide deglycase able to repair glycated guanine in the free nucleotide pool (GTP, GDP, GMP, dGTP) and in DNA and RNA. Is thus involved in a major nucleotide repair system named guanine glycation repair (GG repair), dedicated to reversing methylglyoxal and glyoxal damage via nucleotide sanitization and direct nucleic acid repair (PubMed:28596309). Protects histones from adduction by methylglyoxal, controls the levels of methylglyoxal-derived argininine modifications on chromatin (PubMed:30150385). Able to remove the glycations and restore histone 3, histone glycation disrupts both local and global chromatin architecture by altering histone-DNA interactions as well as histone acetylation and ubiquitination levels (PubMed:30150385, PubMed:30894531). Displays a very low glyoxalase activity that may reflect its deglycase activity (PubMed:22523093, PubMed:31653696, PubMed:28993701). Eliminates hydrogen peroxide and protects cells against hydrogen peroxide-induced cell death (PubMed:16390825). Required for correct mitochondrial morphology and function as well as for autophagy of dysfunctional mitochondria (PubMed:19229105, PubMed:16632486). Plays a role in regulating expression or stability of the mitochondrial uncoupling proteins SLC25A14 and SLC25A27 in dopaminergic neurons of the substantia nigra pars compacta and attenuates the oxidative stress induced by calcium entry into the neurons via L-type channels during pacemaking (PubMed:18711745). Regulates astrocyte inflammatory responses, may modulate lipid rafts-dependent endocytosis in astrocytes and neuronal cells (PubMed:23847046). In pancreatic islets, involved in the maintenance of mitochondrial reactive oxygen species (ROS) levels and glucose homeostasis in an age- and diet dependent manner. Protects pancreatic beta cells from cell death induced by inflammatory and cytotoxic setting (By similarity). Binds to a number of mRNAs containing multiple copies of GG or CC motifs and partially inhibits their translation but dissociates following oxidative stress (PubMed:18626009). Metal-binding protein able to bind copper as well as toxic mercury ions, enhances the cell protection mechanism against induced metal toxicity (PubMed:23792957). In macrophages, interacts with the NADPH oxidase subunit NCF1 to direct NADPH oxidase-dependent ROS production, and protects against sepsis (By similarity).
    • 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93%
    • 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。

  • 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:1/2 到 1/3 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。

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STUB1 Knockout A549 Cell Pool

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

PARK7

NCBI Gene ID

11315

Ensembl ID

ENSG00000116288

Uniprot ID

Q99497

筛选标记

N/A

宿主细胞 / 类型

A549/人非小细胞肺癌细胞

规格

1×10^6 cells/ 冻存管

生长培养基

MEM+10%FBS+100U/ml Penicillin-Strep

生长特性

贴壁细胞,上皮细胞样

培养条件

37℃,5% CO2 的培养箱,1/2 到 1/3 传代

倍增时间

~22 hours

参考换液频率

2-3天换液

支原体检测结果

阴性

敲除验证

敲除效率(Sanger测序)

93%

蛋白质组验证结果

N/A

抗体货号

LMAb01116288

抗体验证结果

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。

细胞系说明

目标基因介绍

Multifunctional protein with controversial molecular function which plays an important role in cell protection against oxidative stress and cell death acting as oxidative stress sensor and redox-sensitive chaperone and protease (PubMed:17015834, PubMed:20304780, PubMed:18711745, PubMed:12796482, PubMed:19229105, PubMed:25416785, PubMed:26995087, PubMed:28993701). It is involved in neuroprotective mechanisms like the stabilization of NFE2L2 and PINK1 proteins, male fertility as a positive regulator of androgen signaling pathway as well as cell growth and transformation through, for instance, the modulation of NF-kappa-B signaling pathway (PubMed:12612053, PubMed:15502874, PubMed:14749723, PubMed:17015834, PubMed:21097510, PubMed:18711745). Has been described as a protein and nucleotide deglycase that catalyzes the deglycation of the Maillard adducts formed between amino groups of proteins or nucleotides and reactive carbonyl groups of glyoxals (PubMed:25416785, PubMed:28596309). But this function is rebuted by other works (PubMed:27903648, PubMed:31653696). As a protein deglycase, repairs methylglyoxal- and glyoxal-glycated proteins, and releases repaired proteins and lactate or glycolate, respectively. Deglycates cysteine, arginine and lysine residues in proteins, and thus reactivates these proteins by reversing glycation by glyoxals. Acts on early glycation intermediates (hemithioacetals and aminocarbinols), preventing the formation of advanced glycation endproducts (AGE) that cause irreversible damage (PubMed:25416785, PubMed:28013050, PubMed:26995087). Also functions as a nucleotide deglycase able to repair glycated guanine in the free nucleotide pool (GTP, GDP, GMP, dGTP) and in DNA and RNA. Is thus involved in a major nucleotide repair system named guanine glycation repair (GG repair), dedicated to reversing methylglyoxal and glyoxal damage via nucleotide sanitization and direct nucleic acid repair (PubMed:28596309). Protects histones from adduction by methylglyoxal, controls the levels of methylglyoxal-derived argininine modifications on chromatin (PubMed:30150385). Able to remove the glycations and restore histone 3, histone glycation disrupts both local and global chromatin architecture by altering histone-DNA interactions as well as histone acetylation and ubiquitination levels (PubMed:30150385, PubMed:30894531). Displays a very low glyoxalase activity that may reflect its deglycase activity (PubMed:22523093, PubMed:31653696, PubMed:28993701). Eliminates hydrogen peroxide and protects cells against hydrogen peroxide-induced cell death (PubMed:16390825). Required for correct mitochondrial morphology and function as well as for autophagy of dysfunctional mitochondria (PubMed:19229105, PubMed:16632486). Plays a role in regulating expression or stability of the mitochondrial uncoupling proteins SLC25A14 and SLC25A27 in dopaminergic neurons of the substantia nigra pars compacta and attenuates the oxidative stress induced by calcium entry into the neurons via L-type channels during pacemaking (PubMed:18711745). Regulates astrocyte inflammatory responses, may modulate lipid rafts-dependent endocytosis in astrocytes and neuronal cells (PubMed:23847046). In pancreatic islets, involved in the maintenance of mitochondrial reactive oxygen species (ROS) levels and glucose homeostasis in an age- and diet dependent manner. Protects pancreatic beta cells from cell death induced by inflammatory and cytotoxic setting (By similarity). Binds to a number of mRNAs containing multiple copies of GG or CC motifs and partially inhibits their translation but dissociates following oxidative stress (PubMed:18626009). Metal-binding protein able to bind copper as well as toxic mercury ions, enhances the cell protection mechanism against induced metal toxicity (PubMed:23792957). In macrophages, interacts with the NADPH oxidase subunit NCF1 to direct NADPH oxidase-dependent ROS production, and protects against sepsis (By similarity).

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93%

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:1/2 到 1/3 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。