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- 详细信息
- 文献和实验
- 技术资料
- 品系:
详见细胞说明资料
- 细胞类型:
详见细胞说明资料
- 肿瘤类型:
详见细胞说明资料
- 供应商:
上海冠导生物工程有限公司
- 库存:
≥100瓶
- 生长状态:
详见细胞说明资料
- 年限:
详见细胞说明资料
- 运输方式:
常温运输【复苏细胞】或干冰运输【冻存细胞】
- 器官来源:
详见细胞说明资料
- 是否是肿瘤细胞:
详见细胞说明资料
- 细胞形态:
详见细胞说明资料
- 免疫类型:
详见细胞说明资料
- 物种来源:
详见细胞说明资料
- 相关疾病:
详见细胞说明资料
- 组织来源:
详见细胞说明资料
- 英文名:
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
- 规格:
1*10(6)Cellls/瓶
"COLO 205人结肠癌传代细胞长期复苏|送STR图谱
传代方法:1:2-1:4(首次传代建议1:2)
生长特性:贴壁生长
换液频率:每周2-3次
背景资料:该细胞系是1957年由T.U.Sle等从患有结肠癌的70岁男性白人的腹水中分离的。该病人在取腹水样前已用5-尿嘧啶治疗4~6周。角蛋白免疫过氧化物酶染色阳性;产生A、IL10。
关于细胞株是否都能一直传代,答案是否定的。细胞系分为有限细胞系与连续细胞系两类。有限细胞系就像一位有着既定行程的行者,其传代之旅存在明确的终点。以正常的人体肝细胞系为例,在体外培养时,它大约能传代20-30次。随着传代次数的递增,细胞内部仿佛一台精密仪器的零件逐渐磨损老化。端粒酶活性降低,端粒不断缩短,染色体结构开始不稳定,基因表达也出现异常。同时,细胞的代谢速率减缓,对营养物质的摄取和利用效率大打折扣,有害物质的积累却日益增多,最终导致细胞停止分裂,走向生命的尽头。而连续细胞系则像是拥有无限活力的长跑健将,具有较强的传代能力。如Hela细胞系,自1951年从Henrietta Lacks女士的宫颈癌组织中分离出来后,便在全球生物实验室中“大放异彩”,至今已传代无数次。它能持续分裂得益于其特殊的遗传变异,使其染色体端粒能够维持稳定长度,并且细胞内的一些关键信号通路持续激活,促进细胞增殖。但这并不意味着它的传代毫无风险与限制。在漫长的传代过程中,它可能会发生新的基因突变、染色体易位等变异事件,从而改变细胞的生物学特性,如细胞形态、生长速度、对药物的敏感性等。
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GCW24 Cells(拥有STR基因鉴定图谱)
TOG Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:神经元细胞;相关产品有:Human Epidermoid carcinoma #2 Cells、H441 Cells、CCRF-SB Cells
SGC996 Cells;背景说明:胆囊癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:HEI-193 Cells、HDF-a Cells、SNU-407 Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
产品包装形式:复苏细胞:T25培养瓶(一瓶)或冻存细胞:1ml冻存管(两支)
来源说明:细胞主要来源ATCC、DSMZ等细胞库
细胞培养时分布不均匀,通常操作步骤:做细胞生物学实验,细胞铺板大概是我们Zui常见的一个实验。但有时候铺得不是很均匀:要么中间密周围稀,要么周围密中间秃。下面为大家分享几点经验。尽量消化细胞分散成单细胞悬。对于易于消化的细胞,我一般DPBS清洗一遍,加0.5ml胰酶润洗一遍(25cm2培养瓶或6孔板),弃掉胰酶,37度消化2-3分钟或室温消化5min左右,镜下观察是否细胞消化较为分散。如果不够,延长消化时间。96孔板一般以100微升每孔接种,直接用100微升移器吸取细胞悬,沿孔壁(稍离开一点孔底即可,不要离底太GAO)直接接入,移器不需完全打到Zui大,轻轻按下即可,每铺完一行换一次枪头同时轻轻混匀细胞悬。都加完后盖上盖子,左手轻轻扶住板的左边,右手轻轻敲击板的右边缘,注意把握力度(我一般轻巧敲三下),太强或次数太多会导致细胞集中成堆,将板顺时针旋转(逆时针效果不HAO),依次敲击剩余三个边,静置约5分钟,放入37度培养箱。6孔板、12孔板或24孔板,可采用将每个孔加入少量无血清培养基,晃动浸润整个孔底,然后用移枪吸至第二孔,同样方法浸润孔底,其它孔依此类推,这样整个孔底都是湿润的,细胞悬会平铺在整个孔底,注意加完细胞悬后要放工作台静置一下。这个方法就是有点慢,但操作熟练了也不慢。也可以采用轻拍的方式,但力度没有96孔板HAO掌握,效果没有96孔板HAO。培养瓶里面加HAO细胞以后(比如传代HAO/分HAO细胞以后),先顺时针摇晃3次,马上逆时针摇晃3次。然后延X轴Y轴分别水平摇动3次。放入CO2培养箱后,平放着培养瓶重复延X轴Y轴分别水平摇动3次。
物种来源:Human\Mouse\Rat\Others
SF-126 Cells;背景说明:该细胞来源于星形胶质细胞瘤;胶质纤维酸性蛋白(GFAP)阴性;可以特异地结合β-内啡肽。;传代方法:1:3传代;3-4天1次。;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:HGSMC Cells、OCIAML2 Cells、Lu-99A Cells
PY8119 Cells;背景说明:乳腺癌;雌性;C57BL/6;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Lu-165 Cells、LN382 Cells、BC-022 Cells
UPCI:SCC090 Cells;背景说明:舌鳞癌细胞;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:alpha-TC1.6 Cells、HP615 Cells、EFM-19 Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
形态特性:上皮细胞样
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ATCC细胞库(American Type Culture Colection),该中心一直致力于细胞分类、鉴定和保藏工作。ATCC是全球最大的生物资源保藏中心,ATCC通过行业标准产品、服务和创新解决方案支持全球学术、政府、生物技术、制药、食品、农业和工业领域的科学进步。ATCC提供的服务和定制解决方案包括细胞和微生物培养、鉴定、生物衍生物的开发和生产、性能测试和生物资源保藏服务。美国国家标准协会(ANSI)认可了ATCC标准开发组织,并制定了标准协议,以确保生物材料的可靠性和可重复性。ATCC的使命是为了获取、鉴定、保存、开发、标准化和分发生物资源和生物信息,以提高和应用生物科学知识。
293EBNA Cells;背景说明:详见相关文献介绍;传代方法:1:4-1:10传代;每周2次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:GM-3573 Cells、A375-MEL Cells、Hs-281-T Cells
SU86-86 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:H-4 Cells、S3 HeLa Cells、UPCI:SCC090 Cells
H82 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:5传代,每周换液2-3次;生长特性:悬浮生长;形态特性:上皮细胞;相关产品有:FRTL-5 Cells、H596 Cells、OCM-1 Cells
RPTEC TERT1 Cells;背景说明:肾;近端小管上皮;HGNC-TERT转化;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:786O Cells、H2591 Cells、CF PAC-1 Cells
CMT.64 Cells;背景说明:肺腺癌;雌性;C57;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Mv.1.Lu Cells、NCI-H2135 Cells、Mel-RM Cells
PIG3 Cells;背景说明:皮肤;黑色素 Cells;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:HT 29 Cells、786-O RCC Cells、JURKAT E-61 Cells
SJSA-1 Cells;背景说明:详见相关文献介绍;传代方法:1:5-1:10传代;每周换液2-3次。;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:PECAPJ34 Cells、HAC-84 Cells、MDA.MB.435 Cells
CHO cell clone K1 Cells;背景说明:1957年,PuckTT从成年中国仓鼠卵巢的活检组织建立了CHO细胞,CHO-K1是CHO的一个亚克隆。CHO-K1的生长需要脯酸。;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:HCC-95 Cells、SKNSH Cells、HCC9724 Cells
NT2 Cells;背景说明:畸胎瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:T1-73 Cells、C 643 Cells、NFHIOSE-80 Cells
CT-26 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Immortal Pig Intestinal-2I Cells、Hs-606-T Cells、A2780/Taxol Cells
NCI-H125 Cells;背景说明:腺鳞状肺癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:J82COT Cells、SKMEL28 Cells、HT144-mel Cells
MN 60 Cells;背景说明:B细胞白血病;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:NCI-H719 Cells、639-V Cells、MZCRC1 Cells
P388.D1 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:SKHEP1 Cells、BT 549 Cells、U-87MG ATCC Cells
MDCK-II Cells;背景说明:详见相关文献介绍;传代方法:1:3传代,3-4天传1次;生长特性:贴壁生长;形态特性:上皮样;相关产品有:C-Lu-65 Cells、MN-60 Cells、HCC94 Cells
BT.549 Cells;背景说明:该细胞1978年由W.G.Coutinho和E.Y.Lasfargues建系,源自一位72岁患有乳腺导管癌的白人女性,来源组织包括乳头及浸润导管。该细胞形态包括上皮样细胞及多核巨细胞,可分泌一种粘性物质。;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:H1755 Cells、KU19-19 Cells、DV90 Cells
H-676 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:X63-Ag 8.6.5.3 Cells、Hs742T Cells、H1238 Cells
SK-N-BE(1) Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:AZ-521 Cells、NOR-10 Cells、RAMOS2G64C10 Cells
Abcam HCT 116 CDK8 KO Cells(拥有STR基因鉴定图谱)
AG05190 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line CSI323 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line RST488 Cells(拥有STR基因鉴定图谱)
BHK-21 Cells(拥有STR基因鉴定图谱)
CHOPWT1.3 Cells(拥有STR基因鉴定图谱)
DA03098 Cells(拥有STR基因鉴定图谱)
DA05206 Cells(拥有STR基因鉴定图谱)
NCIH446 Cells;背景说明:该细胞是1982年由CarneyD和GazdarAF等从一位小细胞肺癌患者的胸腔积液中建立的。细胞的原始形态并不具有小细胞肺癌特征。这个细胞株是小细胞肺癌的生化和形态学上的变种,表达神经元特有的烯醇酶和脑型肌酸激酶同工酶;左旋多巴脱羧酶、蚕素、抗利尿激素、催产素或胃泌激素释放肽未达到可检测水平。与正常细胞相比,该细胞c-mycDNA序列扩增约20倍,RNA增加15倍。最初传代培养基用含有5%FBS的RPMI1640,另外添加10nM化可的松、0.005mg/ml胰岛素、0.01mg/ml转铁;传代方法:1:2传代;生长特性:贴壁/悬浮生长,混合;形态特性:上皮样;相关产品有:Medical University of Graz-Chordoma 1 Cells、Ketr3 Cells、HRA 19 Cells
S3-HeLa Cells;背景说明:该细胞是1955年由PuckTT,MarcusPI和CieciuraSJ建系的,含HPV-18序列;角蛋白阳性;可用于与染色体突变、细胞营养、集落形成相关的哺乳动物细胞的克隆分析。;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:Hi-five Cells、RPTEC/TERT 1 Cells、HNTEC Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
1E8-H Cells;背景说明:前列腺癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:RPMI 7666 Cells、RBSMC Cells、LNCaP Cells
159 PT Cells;背景说明:乳腺癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:T2 Cells、H526 Cells、HCC1937 Cells
H-1693 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代,每周换液2次。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:3 LL Cells、Hs 274 Cells、IHH4 Cells
BC-025 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Ramos G6.C10 Cells、Human Microglia Clone 3 Cells、NCI-H748 Cells
OCI-Ly03 Cells;背景说明:弥漫大B淋巴瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:L929 Cells、A-253 Cells、MC/9 Cells
P3X63 AG 8.653 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C33 Cells、P-2003 Cells、PANC-10-05 Cells
18B8 Cells(拥有STR基因鉴定图谱)
SK-NEP-1 Cells;背景说明:超微结构有少许微绒毛,连接复合物,形态完整的高尔基体,内质网多为光滑型,脂滴,没有病毒棵粒。;传代方法:1:2传代。3天内可长满。;生长特性:半贴壁生长;形态特性:上皮细胞;相关产品有:SCL II Cells、Dunn LM8 Cells、COLO-829 Cells
H4-II-E Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Hmy.2 CIR Cells、PANC 203 Cells、624 Cells
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DHL-6 Cells;背景说明:详见相关文献介绍;传代方法:1:3—1:6传代,3—4天换液1次;生长特性:悬浮生长 ;形态特性:淋巴母细胞样;相关产品有:MLMA Cells、H719 Cells、A549/DDP Cells
H-1563 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:4传代;每周换液2次。;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:NCI-H2023 Cells、MIN6 Cells、NCIH1568 Cells
NCI-H676B Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:J82 Cells、CPAE Cells、A-427 Cells
NCIH1435 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:6传代,每周换液2-3次;生长特性:贴壁生长,松散;形态特性:详见产品说明;相关产品有:CHG-5 Cells、293-GP Cells、JIII Cells
PL45 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:4T1 Cells、NHDF Cells、Centre Antoine Lacassagne-12T Cells
UO31 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:6传代;2-3天换液1次。;生长特性:贴壁生长;形态特性:上皮样;相关产品有:MHH-CALL-2 Cells、MV-4:11 Cells、293 HEK Cells
GM21165 Cells(拥有STR基因鉴定图谱)
HAP1 LRRC8D (-) 1 Cells(拥有STR基因鉴定图谱)
UACC893 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁生长;形态特性:上皮样;相关产品有:H-841 Cells、HEK-293FT Cells、CCRF-CEM/S Cells
SW-948 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:5传代,每周换液1-2次;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:SW 1573 Cells、CL-34 Cells、SKG-3a Cells
C643 Cells;背景说明:甲状腺未分化癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:VCaP Cells、CL1 Cells、Hepa1-6 Cells
H889 Cells;背景说明:详见相关文献介绍;传代方法:每周换液2-3次;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:上皮细胞;相关产品有:MDAMB415 Cells、MDA.MB.435 Cells、Ramos 2G6 4C10 Cells
DU 4475 Cells;背景说明:详见相关文献介绍;传代方法:每周换液2—3次;生长特性:悬浮,多细胞聚集;形态特性:上皮细胞样;相关产品有:WRL68 Cells、32D.cl3 Cells、K562/ADR Cells
Hs940T Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代,2-3天换液1次。;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:A549/ATCC Cells、OCI AML5 Cells、SGC-996 Cells
BTI-TN5B1-4 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:HASMC Cells、NTera 2/cl.D1 Cells、Human Pancreatic Duct Epithelial Cells
MMAc.SF Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:PIEC Cells、NCIH2452 Cells、CDC/EU.HMEC-1 Cells
HPSI0414i-uawq_2 Cells(拥有STR基因鉴定图谱)
K562-Red-FLuc Cells(拥有STR基因鉴定图谱)
Mel E Cells(拥有STR基因鉴定图谱)
NH50224 Cells(拥有STR基因鉴定图谱)
R-3 Cells(拥有STR基因鉴定图谱)
Ubigene A-549 ADRB2 KO Cells(拥有STR基因鉴定图谱)
UNIBSi002-A Cells(拥有STR基因鉴定图谱)
HCT116-SLC36A1-KO-c11 Cells(拥有STR基因鉴定图谱)
ACHN Cells;背景说明:该细胞1979年建系,源自一名22岁患有肾细胞腺癌的白人男性的胸腔积液。干扰素可抑制该细胞的生长,该细胞多用于干扰素及其诱导剂的抗增殖研究。;传代方法:1:2-1:3传代,每周2-3次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:HCV 29 Cells、BrCL18 Cells、MDA-MB-468 Cells
HCC-1588 Cells;背景说明:肺鳞癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:H-2087 Cells、ARH77 Cells、KU 19-19 Cells
SW 780 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Hs-695-T Cells、H82sclc Cells、H-1734 Cells
MA104 Cells;背景说明:胚肾;自发永生;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:ONS-76 Cells、MOLM16 Cells、HSC1 Cells
RT-112 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C32-mel Cells、HeLa/DDP Cells、RCC10 Cells
RT-112 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C32-mel Cells、HeLa/DDP Cells、RCC10 Cells
NBL-12 Cells;背景说明:肺;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:PT-K75 Cells、GM-637 Cells、WI 38 Cells
K-1735 Cells;背景说明:黑色素瘤; C3H/HeN;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:786.O Cells、Calu 6 Cells、HSAS3 Cells
NCI-SNU-668 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:B16-BL6 Cells、PATU-S Cells、L2 Cells
OUMS27 Cells;背景说明:软骨肉瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Tu-177 Cells、SK-GT-2 Cells、Panc_02_03 Cells
RT 112 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:PLC/PRF5 Cells、H-2291 Cells、KYSE0520 Cells
RSMC Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SU-DH-L5 Cells、TKB1 Cells、UWB1.289 Cells
PL9 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:Centre Antoine Lacassagne-78 Cells、CAKI1 Cells、MDA-MB-231-GFP Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
C57/B6-L Cells;背景说明:肺;成纤维细胞;C57;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Hs611T Cells、CCD-112CoN Cells、P3 88 D1 Cells
ATDC-5 Cells;背景说明:详见相关文献介绍;传代方法:消化3-5分钟,1:2,3天内可长满;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:KMST-6 Cells、OVCAR-3 Cells、MBMEC Cells
SR-CDF1 DBT Cells(拥有STR基因鉴定图谱)
RPMI2650 Cells;背景说明:头颈鳞癌;胸腔积液转移;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:H747 Cells、HEC-1-A Cells、HS688AT Cells
MNNG/HOS Cl #5 Cells;背景说明:骨肉瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Chinese Hamster Lung Cells、CHP-212 Cells、Hs 895 T Cells
DF-1 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:成纤维母细胞样;相关产品有:H1184 Cells、UPCI:SCC090 Cells、NCIH727 Cells
SMC-1 Cells;背景说明:胸膜间皮瘤;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:GM07404A Cells、FRTL5 Cells、Caki-2 Cells
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SKNO-1 Cells;背景说明:急性髓系白血病;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:HEC-151 Cells、IEC-18 Cells、C32 [Human melanoma] Cells
H-2330 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Soleus clone 8 Cells、RL-952 Cells、HEK293FT Cells
H847 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:FRO Cells、Huh 7.5.1 Cells、PE/CA-PJ34 (clone C12) Cells
SF-767 Cells;背景说明:脑瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:SNU251 Cells、IOSE-Mar Cells、CT 26 Cells
MRCV Cells;背景说明:MRC-5细胞系来自14周龄男性胎儿的正常肺组织,该细胞老化前能传代42~46个倍增时间。;传代方法:1:2-1:5传代;每周1-2次。;生长特性:贴壁生长;形态特性:成纤维细胞样;相关产品有:NCI-H524 Cells、BEP2D Cells、D-283 Cells
H2135 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:HCC-1143 Cells、MDA436 Cells、ARO81 Cells
Panc04.03 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:NK92 Cells、Ra No. 1 Cells、Nthy-ori 3.1 Cells
GP5d Cells;背景说明:结肠癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:SKES-1 Cells、GLRK 13 Cells、VeroC1008 Cells
Bovine Turbinate Cells;背景说明:鼻甲;自发永生;Holstein;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:MIHA Cells、LS 123 Cells、XuanWei Lung Cancer-05 Cells
LNCaP-FGC Cells;背景说明:人前列腺癌细胞LNCaP克隆FGC是从一位50岁白人男性(血型B+)的左锁骨淋巴结针刺活检中分离,该患者经确诊为前列腺癌转移。 这株细胞对5-α-二睾酮(生长调节子和酸性脂酶产物)有响应。这株细胞并不形成一致的单层,而是形成集落,在传代时可以用滴管反复吹吸打碎。它们仅仅轻轻地吸附在基底上,不形成汇合,很快使培养基变酸。生长很慢。传代后48小时内不应扰动。当培养瓶封包后,多数细胞从培养瓶底分离,悬浮在培养基中。收到后,在通常培养单层细胞的条件下培养24到48小时,以合细胞再贴壁。;传代方法:消化3-5分钟。1:2。3天内可长满。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:SNU-5 Cells、NTERA2-D1 Cells、BNL 1ME A.7R.1 Cells
BayGenomics ES cell line RRH010 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line XH102 Cells(拥有STR基因鉴定图谱)
ES[MC1R(20):tetAscl2(21)] Cells(拥有STR基因鉴定图谱)
Myc1-8F9 Cells(拥有STR基因鉴定图谱)
Ubigene ID8 Kmt2d KO Cells(拥有STR基因鉴定图谱)
Matsu Cells(拥有STR基因鉴定图谱)
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传代方法:1:2-1:4(首次传代建议1:2)
生长特性:贴壁生长
换液频率:每周2-3次
背景资料:该细胞系是1957年由T.U.Sle等从患有结肠癌的70岁男性白人的腹水中分离的。该病人在取腹水样前已用5-尿嘧啶治疗4~6周。角蛋白免疫过氧化物酶染色阳性;产生A、IL10。
关于细胞株是否都能一直传代,答案是否定的。细胞系分为有限细胞系与连续细胞系两类。有限细胞系就像一位有着既定行程的行者,其传代之旅存在明确的终点。以正常的人体肝细胞系为例,在体外培养时,它大约能传代20-30次。随着传代次数的递增,细胞内部仿佛一台精密仪器的零件逐渐磨损老化。端粒酶活性降低,端粒不断缩短,染色体结构开始不稳定,基因表达也出现异常。同时,细胞的代谢速率减缓,对营养物质的摄取和利用效率大打折扣,有害物质的积累却日益增多,最终导致细胞停止分裂,走向生命的尽头。而连续细胞系则像是拥有无限活力的长跑健将,具有较强的传代能力。如Hela细胞系,自1951年从Henrietta Lacks女士的宫颈癌组织中分离出来后,便在全球生物实验室中“大放异彩”,至今已传代无数次。它能持续分裂得益于其特殊的遗传变异,使其染色体端粒能够维持稳定长度,并且细胞内的一些关键信号通路持续激活,促进细胞增殖。但这并不意味着它的传代毫无风险与限制。在漫长的传代过程中,它可能会发生新的基因突变、染色体易位等变异事件,从而改变细胞的生物学特性,如细胞形态、生长速度、对药物的敏感性等。
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GCW24 Cells(拥有STR基因鉴定图谱)
TOG Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:神经元细胞;相关产品有:Human Epidermoid carcinoma #2 Cells、H441 Cells、CCRF-SB Cells
SGC996 Cells;背景说明:胆囊癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:HEI-193 Cells、HDF-a Cells、SNU-407 Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
产品包装形式:复苏细胞:T25培养瓶(一瓶)或冻存细胞:1ml冻存管(两支)
来源说明:细胞主要来源ATCC、DSMZ等细胞库
细胞培养时分布不均匀,通常操作步骤:做细胞生物学实验,细胞铺板大概是我们Zui常见的一个实验。但有时候铺得不是很均匀:要么中间密周围稀,要么周围密中间秃。下面为大家分享几点经验。尽量消化细胞分散成单细胞悬。对于易于消化的细胞,我一般DPBS清洗一遍,加0.5ml胰酶润洗一遍(25cm2培养瓶或6孔板),弃掉胰酶,37度消化2-3分钟或室温消化5min左右,镜下观察是否细胞消化较为分散。如果不够,延长消化时间。96孔板一般以100微升每孔接种,直接用100微升移器吸取细胞悬,沿孔壁(稍离开一点孔底即可,不要离底太GAO)直接接入,移器不需完全打到Zui大,轻轻按下即可,每铺完一行换一次枪头同时轻轻混匀细胞悬。都加完后盖上盖子,左手轻轻扶住板的左边,右手轻轻敲击板的右边缘,注意把握力度(我一般轻巧敲三下),太强或次数太多会导致细胞集中成堆,将板顺时针旋转(逆时针效果不HAO),依次敲击剩余三个边,静置约5分钟,放入37度培养箱。6孔板、12孔板或24孔板,可采用将每个孔加入少量无血清培养基,晃动浸润整个孔底,然后用移枪吸至第二孔,同样方法浸润孔底,其它孔依此类推,这样整个孔底都是湿润的,细胞悬会平铺在整个孔底,注意加完细胞悬后要放工作台静置一下。这个方法就是有点慢,但操作熟练了也不慢。也可以采用轻拍的方式,但力度没有96孔板HAO掌握,效果没有96孔板HAO。培养瓶里面加HAO细胞以后(比如传代HAO/分HAO细胞以后),先顺时针摇晃3次,马上逆时针摇晃3次。然后延X轴Y轴分别水平摇动3次。放入CO2培养箱后,平放着培养瓶重复延X轴Y轴分别水平摇动3次。
物种来源:Human\Mouse\Rat\Others
SF-126 Cells;背景说明:该细胞来源于星形胶质细胞瘤;胶质纤维酸性蛋白(GFAP)阴性;可以特异地结合β-内啡肽。;传代方法:1:3传代;3-4天1次。;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:HGSMC Cells、OCIAML2 Cells、Lu-99A Cells
PY8119 Cells;背景说明:乳腺癌;雌性;C57BL/6;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Lu-165 Cells、LN382 Cells、BC-022 Cells
UPCI:SCC090 Cells;背景说明:舌鳞癌细胞;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:alpha-TC1.6 Cells、HP615 Cells、EFM-19 Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
形态特性:上皮细胞样
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ATCC细胞库(American Type Culture Colection),该中心一直致力于细胞分类、鉴定和保藏工作。ATCC是全球最大的生物资源保藏中心,ATCC通过行业标准产品、服务和创新解决方案支持全球学术、政府、生物技术、制药、食品、农业和工业领域的科学进步。ATCC提供的服务和定制解决方案包括细胞和微生物培养、鉴定、生物衍生物的开发和生产、性能测试和生物资源保藏服务。美国国家标准协会(ANSI)认可了ATCC标准开发组织,并制定了标准协议,以确保生物材料的可靠性和可重复性。ATCC的使命是为了获取、鉴定、保存、开发、标准化和分发生物资源和生物信息,以提高和应用生物科学知识。
293EBNA Cells;背景说明:详见相关文献介绍;传代方法:1:4-1:10传代;每周2次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:GM-3573 Cells、A375-MEL Cells、Hs-281-T Cells
SU86-86 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:H-4 Cells、S3 HeLa Cells、UPCI:SCC090 Cells
H82 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:5传代,每周换液2-3次;生长特性:悬浮生长;形态特性:上皮细胞;相关产品有:FRTL-5 Cells、H596 Cells、OCM-1 Cells
RPTEC TERT1 Cells;背景说明:肾;近端小管上皮;HGNC-TERT转化;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:786O Cells、H2591 Cells、CF PAC-1 Cells
CMT.64 Cells;背景说明:肺腺癌;雌性;C57;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Mv.1.Lu Cells、NCI-H2135 Cells、Mel-RM Cells
PIG3 Cells;背景说明:皮肤;黑色素 Cells;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:HT 29 Cells、786-O RCC Cells、JURKAT E-61 Cells
SJSA-1 Cells;背景说明:详见相关文献介绍;传代方法:1:5-1:10传代;每周换液2-3次。;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:PECAPJ34 Cells、HAC-84 Cells、MDA.MB.435 Cells
CHO cell clone K1 Cells;背景说明:1957年,PuckTT从成年中国仓鼠卵巢的活检组织建立了CHO细胞,CHO-K1是CHO的一个亚克隆。CHO-K1的生长需要脯酸。;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:HCC-95 Cells、SKNSH Cells、HCC9724 Cells
NT2 Cells;背景说明:畸胎瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:T1-73 Cells、C 643 Cells、NFHIOSE-80 Cells
CT-26 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Immortal Pig Intestinal-2I Cells、Hs-606-T Cells、A2780/Taxol Cells
NCI-H125 Cells;背景说明:腺鳞状肺癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:J82COT Cells、SKMEL28 Cells、HT144-mel Cells
MN 60 Cells;背景说明:B细胞白血病;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:NCI-H719 Cells、639-V Cells、MZCRC1 Cells
P388.D1 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:SKHEP1 Cells、BT 549 Cells、U-87MG ATCC Cells
MDCK-II Cells;背景说明:详见相关文献介绍;传代方法:1:3传代,3-4天传1次;生长特性:贴壁生长;形态特性:上皮样;相关产品有:C-Lu-65 Cells、MN-60 Cells、HCC94 Cells
BT.549 Cells;背景说明:该细胞1978年由W.G.Coutinho和E.Y.Lasfargues建系,源自一位72岁患有乳腺导管癌的白人女性,来源组织包括乳头及浸润导管。该细胞形态包括上皮样细胞及多核巨细胞,可分泌一种粘性物质。;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:H1755 Cells、KU19-19 Cells、DV90 Cells
H-676 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:X63-Ag 8.6.5.3 Cells、Hs742T Cells、H1238 Cells
SK-N-BE(1) Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:AZ-521 Cells、NOR-10 Cells、RAMOS2G64C10 Cells
Abcam HCT 116 CDK8 KO Cells(拥有STR基因鉴定图谱)
AG05190 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line CSI323 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line RST488 Cells(拥有STR基因鉴定图谱)
BHK-21 Cells(拥有STR基因鉴定图谱)
CHOPWT1.3 Cells(拥有STR基因鉴定图谱)
DA03098 Cells(拥有STR基因鉴定图谱)
DA05206 Cells(拥有STR基因鉴定图谱)
NCIH446 Cells;背景说明:该细胞是1982年由CarneyD和GazdarAF等从一位小细胞肺癌患者的胸腔积液中建立的。细胞的原始形态并不具有小细胞肺癌特征。这个细胞株是小细胞肺癌的生化和形态学上的变种,表达神经元特有的烯醇酶和脑型肌酸激酶同工酶;左旋多巴脱羧酶、蚕素、抗利尿激素、催产素或胃泌激素释放肽未达到可检测水平。与正常细胞相比,该细胞c-mycDNA序列扩增约20倍,RNA增加15倍。最初传代培养基用含有5%FBS的RPMI1640,另外添加10nM化可的松、0.005mg/ml胰岛素、0.01mg/ml转铁;传代方法:1:2传代;生长特性:贴壁/悬浮生长,混合;形态特性:上皮样;相关产品有:Medical University of Graz-Chordoma 1 Cells、Ketr3 Cells、HRA 19 Cells
S3-HeLa Cells;背景说明:该细胞是1955年由PuckTT,MarcusPI和CieciuraSJ建系的,含HPV-18序列;角蛋白阳性;可用于与染色体突变、细胞营养、集落形成相关的哺乳动物细胞的克隆分析。;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:Hi-five Cells、RPTEC/TERT 1 Cells、HNTEC Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
1E8-H Cells;背景说明:前列腺癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:RPMI 7666 Cells、RBSMC Cells、LNCaP Cells
159 PT Cells;背景说明:乳腺癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:T2 Cells、H526 Cells、HCC1937 Cells
H-1693 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代,每周换液2次。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:3 LL Cells、Hs 274 Cells、IHH4 Cells
BC-025 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Ramos G6.C10 Cells、Human Microglia Clone 3 Cells、NCI-H748 Cells
OCI-Ly03 Cells;背景说明:弥漫大B淋巴瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:L929 Cells、A-253 Cells、MC/9 Cells
P3X63 AG 8.653 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C33 Cells、P-2003 Cells、PANC-10-05 Cells
18B8 Cells(拥有STR基因鉴定图谱)
SK-NEP-1 Cells;背景说明:超微结构有少许微绒毛,连接复合物,形态完整的高尔基体,内质网多为光滑型,脂滴,没有病毒棵粒。;传代方法:1:2传代。3天内可长满。;生长特性:半贴壁生长;形态特性:上皮细胞;相关产品有:SCL II Cells、Dunn LM8 Cells、COLO-829 Cells
H4-II-E Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Hmy.2 CIR Cells、PANC 203 Cells、624 Cells
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DHL-6 Cells;背景说明:详见相关文献介绍;传代方法:1:3—1:6传代,3—4天换液1次;生长特性:悬浮生长 ;形态特性:淋巴母细胞样;相关产品有:MLMA Cells、H719 Cells、A549/DDP Cells
H-1563 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:4传代;每周换液2次。;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:NCI-H2023 Cells、MIN6 Cells、NCIH1568 Cells
NCI-H676B Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:J82 Cells、CPAE Cells、A-427 Cells
NCIH1435 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:6传代,每周换液2-3次;生长特性:贴壁生长,松散;形态特性:详见产品说明;相关产品有:CHG-5 Cells、293-GP Cells、JIII Cells
PL45 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:4T1 Cells、NHDF Cells、Centre Antoine Lacassagne-12T Cells
UO31 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:6传代;2-3天换液1次。;生长特性:贴壁生长;形态特性:上皮样;相关产品有:MHH-CALL-2 Cells、MV-4:11 Cells、293 HEK Cells
GM21165 Cells(拥有STR基因鉴定图谱)
HAP1 LRRC8D (-) 1 Cells(拥有STR基因鉴定图谱)
UACC893 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁生长;形态特性:上皮样;相关产品有:H-841 Cells、HEK-293FT Cells、CCRF-CEM/S Cells
SW-948 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:5传代,每周换液1-2次;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:SW 1573 Cells、CL-34 Cells、SKG-3a Cells
C643 Cells;背景说明:甲状腺未分化癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:VCaP Cells、CL1 Cells、Hepa1-6 Cells
H889 Cells;背景说明:详见相关文献介绍;传代方法:每周换液2-3次;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:上皮细胞;相关产品有:MDAMB415 Cells、MDA.MB.435 Cells、Ramos 2G6 4C10 Cells
DU 4475 Cells;背景说明:详见相关文献介绍;传代方法:每周换液2—3次;生长特性:悬浮,多细胞聚集;形态特性:上皮细胞样;相关产品有:WRL68 Cells、32D.cl3 Cells、K562/ADR Cells
Hs940T Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代,2-3天换液1次。;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:A549/ATCC Cells、OCI AML5 Cells、SGC-996 Cells
BTI-TN5B1-4 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:HASMC Cells、NTera 2/cl.D1 Cells、Human Pancreatic Duct Epithelial Cells
MMAc.SF Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:PIEC Cells、NCIH2452 Cells、CDC/EU.HMEC-1 Cells
HPSI0414i-uawq_2 Cells(拥有STR基因鉴定图谱)
K562-Red-FLuc Cells(拥有STR基因鉴定图谱)
Mel E Cells(拥有STR基因鉴定图谱)
NH50224 Cells(拥有STR基因鉴定图谱)
R-3 Cells(拥有STR基因鉴定图谱)
Ubigene A-549 ADRB2 KO Cells(拥有STR基因鉴定图谱)
UNIBSi002-A Cells(拥有STR基因鉴定图谱)
HCT116-SLC36A1-KO-c11 Cells(拥有STR基因鉴定图谱)
ACHN Cells;背景说明:该细胞1979年建系,源自一名22岁患有肾细胞腺癌的白人男性的胸腔积液。干扰素可抑制该细胞的生长,该细胞多用于干扰素及其诱导剂的抗增殖研究。;传代方法:1:2-1:3传代,每周2-3次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:HCV 29 Cells、BrCL18 Cells、MDA-MB-468 Cells
HCC-1588 Cells;背景说明:肺鳞癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:H-2087 Cells、ARH77 Cells、KU 19-19 Cells
SW 780 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Hs-695-T Cells、H82sclc Cells、H-1734 Cells
MA104 Cells;背景说明:胚肾;自发永生;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:ONS-76 Cells、MOLM16 Cells、HSC1 Cells
RT-112 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C32-mel Cells、HeLa/DDP Cells、RCC10 Cells
RT-112 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C32-mel Cells、HeLa/DDP Cells、RCC10 Cells
NBL-12 Cells;背景说明:肺;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:PT-K75 Cells、GM-637 Cells、WI 38 Cells
K-1735 Cells;背景说明:黑色素瘤; C3H/HeN;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:786.O Cells、Calu 6 Cells、HSAS3 Cells
NCI-SNU-668 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:B16-BL6 Cells、PATU-S Cells、L2 Cells
OUMS27 Cells;背景说明:软骨肉瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Tu-177 Cells、SK-GT-2 Cells、Panc_02_03 Cells
RT 112 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:PLC/PRF5 Cells、H-2291 Cells、KYSE0520 Cells
RSMC Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SU-DH-L5 Cells、TKB1 Cells、UWB1.289 Cells
PL9 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:Centre Antoine Lacassagne-78 Cells、CAKI1 Cells、MDA-MB-231-GFP Cells
COLO 205人结肠癌传代细胞长期复苏|送STR图谱
C57/B6-L Cells;背景说明:肺;成纤维细胞;C57;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Hs611T Cells、CCD-112CoN Cells、P3 88 D1 Cells
ATDC-5 Cells;背景说明:详见相关文献介绍;传代方法:消化3-5分钟,1:2,3天内可长满;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:KMST-6 Cells、OVCAR-3 Cells、MBMEC Cells
SR-CDF1 DBT Cells(拥有STR基因鉴定图谱)
RPMI2650 Cells;背景说明:头颈鳞癌;胸腔积液转移;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:H747 Cells、HEC-1-A Cells、HS688AT Cells
MNNG/HOS Cl #5 Cells;背景说明:骨肉瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Chinese Hamster Lung Cells、CHP-212 Cells、Hs 895 T Cells
DF-1 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:成纤维母细胞样;相关产品有:H1184 Cells、UPCI:SCC090 Cells、NCIH727 Cells
SMC-1 Cells;背景说明:胸膜间皮瘤;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:GM07404A Cells、FRTL5 Cells、Caki-2 Cells
┈订┈购┈热┈线:1┈5┈8┈0┈0┈5┈7┈6┈8┈6┈7【微信同号】┈Q┈Q:3┈3┈0┈7┈2┈0┈4┈2┈7┈1;
SKNO-1 Cells;背景说明:急性髓系白血病;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:HEC-151 Cells、IEC-18 Cells、C32 [Human melanoma] Cells
H-2330 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Soleus clone 8 Cells、RL-952 Cells、HEK293FT Cells
H847 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:FRO Cells、Huh 7.5.1 Cells、PE/CA-PJ34 (clone C12) Cells
SF-767 Cells;背景说明:脑瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:SNU251 Cells、IOSE-Mar Cells、CT 26 Cells
MRCV Cells;背景说明:MRC-5细胞系来自14周龄男性胎儿的正常肺组织,该细胞老化前能传代42~46个倍增时间。;传代方法:1:2-1:5传代;每周1-2次。;生长特性:贴壁生长;形态特性:成纤维细胞样;相关产品有:NCI-H524 Cells、BEP2D Cells、D-283 Cells
H2135 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:HCC-1143 Cells、MDA436 Cells、ARO81 Cells
Panc04.03 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:NK92 Cells、Ra No. 1 Cells、Nthy-ori 3.1 Cells
GP5d Cells;背景说明:结肠癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:SKES-1 Cells、GLRK 13 Cells、VeroC1008 Cells
Bovine Turbinate Cells;背景说明:鼻甲;自发永生;Holstein;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:MIHA Cells、LS 123 Cells、XuanWei Lung Cancer-05 Cells
LNCaP-FGC Cells;背景说明:人前列腺癌细胞LNCaP克隆FGC是从一位50岁白人男性(血型B+)的左锁骨淋巴结针刺活检中分离,该患者经确诊为前列腺癌转移。 这株细胞对5-α-二睾酮(生长调节子和酸性脂酶产物)有响应。这株细胞并不形成一致的单层,而是形成集落,在传代时可以用滴管反复吹吸打碎。它们仅仅轻轻地吸附在基底上,不形成汇合,很快使培养基变酸。生长很慢。传代后48小时内不应扰动。当培养瓶封包后,多数细胞从培养瓶底分离,悬浮在培养基中。收到后,在通常培养单层细胞的条件下培养24到48小时,以合细胞再贴壁。;传代方法:消化3-5分钟。1:2。3天内可长满。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:SNU-5 Cells、NTERA2-D1 Cells、BNL 1ME A.7R.1 Cells
BayGenomics ES cell line RRH010 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line XH102 Cells(拥有STR基因鉴定图谱)
ES[MC1R(20):tetAscl2(21)] Cells(拥有STR基因鉴定图谱)
Myc1-8F9 Cells(拥有STR基因鉴定图谱)
Ubigene ID8 Kmt2d KO Cells(拥有STR基因鉴定图谱)
Matsu Cells(拥有STR基因鉴定图谱)
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文献和实验该产品被引用文献
"PubMed=3335022
Alley M.C., Scudiero D.A., Monks A., Hursey M.L., Czerwinski M.J., Fine D.L., Abbott B.J., Mayo J.G., Shoemaker R.H., Boyd M.R.
Feasibility of drug screening with panels of human tumor cell lines using a microculture tetrazolium assay.
Cancer Res. 48:589-601(1988)
PubMed=2041050; DOI=10.1093/jnci/83.11.757
Monks A., Scudiero D.A., Skehan P., Shoemaker R.H., Paull K.D., Vistica D.T., Hose C.D., Langley J., Cronise P., Vaigro-Wolff A., Gray-Goodrich M., Campbell H., Mayo J.G., Boyd M.R.
Feasibility of a high-flux anticancer drug screen using a diverse panel of cultured human tumor cell lines.
J. Natl. Cancer Inst. 83:757-766(1991)
PubMed=7651727
Kastrinakis W.V., Ramchurren N., Rieger K.M., Hess D.T., Loda M., Steele G., Summerhayes I.C.
Increased incidence of p53 mutations is associated with hepatic metastasis in colorectal neoplastic progression.
Oncogene 11:647-652(1995)
PubMed=9023415; DOI=10.1006/cimm.1996.1062
Seki N., Hoshino T., Kikuchi M., Hayashi A., Itoh K.
HLA-A locus-restricted and tumor-specific CTLs in tumor-infiltrating lymphocytes of patients with non-small cell lung cancer.
Cell. Immunol. 175:101-110(1997)
PubMed=9294210; DOI=10.1073/pnas.94.19.10330; PMCID=PMC23362
Ilyas M., Tomlinson I.P.M., Rowan A.J., Pignatelli M., Bodmer W.F.
Beta-catenin mutations in cell lines established from human colorectal cancers.
Proc. Natl. Acad. Sci. U.S.A. 94:10330-10334(1997)
PubMed=10051639; DOI=10.1073/pnas.96.5.2316; PMCID=PMC26781
Efstathiou J.A., Liu D., Wheeler J.M.D., Kim H.C., Beck N.E., Ilyas M., Karayiannakis A.J., Mortensen N.J., Kmiot W.A.W., Playford R.J., Pignatelli M., Bodmer W.F.
Mutated epithelial cadherin is associated with increased tumorigenicity and loss of adhesion and of responsiveness to the motogenic trefoil factor 2 in colon carcinoma cells.
Proc. Natl. Acad. Sci. U.S.A. 96:2316-2321(1999)
PubMed=10674020; DOI=10.1016/S0959-8049(99)00206-3
Ku J.-L., Yoon K.-A., Kim D.-Y., Park J.-G.
Mutations in hMSH6 alone are not sufficient to cause the microsatellite instability in colorectal cancer cell lines.
Eur. J. Cancer 35:1724-1729(1999)
PubMed=10700174; DOI=10.1038/73432
Ross D.T., Scherf U., Eisen M.B., Perou C.M., Rees C., Spellman P.T., Iyer V.R., Jeffrey S.S., van de Rijn M., Waltham M.C., Pergamenschikov A., Lee J.C.F., Lashkari D., Shalon D., Myers T.G., Weinstein J.N., Botstein D., Brown P.O.
Systematic variation in gene expression patterns in human cancer cell lines.
Nat. Genet. 24:227-235(2000)
PubMed=10737795; DOI=10.1073/pnas.97.7.3352; PMCID=PMC16243
Rowan A.J., Lamlum H., Ilyas M., Wheeler J.M.D., Straub J., Papadopoulou A., Bicknell D.C., Bodmer W.F., Tomlinson I.P.M.
APC mutations in sporadic colorectal tumors: a mutational 'hotspot' and interdependence of the 'two hits'.
Proc. Natl. Acad. Sci. U.S.A. 97:3352-3357(2000)
PubMed=11414198; DOI=10.1007/s004320000207
Lahm H., Andre S., Hoeflich A., Fischer J.R., Sordat B., Kaltner H., Wolf E., Gabius H.-J.
Comprehensive galectin fingerprinting in a panel of 61 human tumor cell lines by RT-PCR and its implications for diagnostic and therapeutic procedures.
J. Cancer Res. Clin. Oncol. 127:375-386(2001)
PubMed=12068308; DOI=10.1038/nature00766
Davies H.R., Bignell G.R., Cox C., Stephens P.J., Edkins S., Clegg S., Teague J.W., Woffendin H., Garnett M.J., Bottomley W., Davis N., Dicks E., Ewing R., Floyd Y., Gray K., Hall S., Hawes R., Hughes J., Kosmidou V., Menzies A., Mould C., Parker A., Stevens C., Watt S., Hooper S., Wilson R., Jayatilake H., Gusterson B.A., Cooper C.S., Shipley J.M., Hargrave D., Pritchard-Jones K., Maitland N.J., Chenevix-Trench G., Riggins G.J., Bigner D.D., Palmieri G., Cossu A., Flanagan A.M., Nicholson A., Ho J.W.C., Leung S.Y., Yuen S.T., Weber B.L., Seigler H.F., Darrow T.L., Paterson H.F., Marais R., Marshall C.J., Wooster R., Stratton M.R., Futreal P.A.
Mutations of the BRAF gene in human cancer.
Nature 417:949-954(2002)
PubMed=12584437; DOI=10.1159/000068544
Melcher R., Koehler S., Steinlein C., Schmid M., Mueller C.R., Luehrs H., Menzel T., Scheppach W., Moerk H., Scheurlen M., Koehrle J., Al-Taie O.
Spectral karyotype analysis of colon cancer cell lines of the tumor suppressor and mutator pathway.
Cytogenet. Genome Res. 98:22-28(2002)
PubMed=15748285; DOI=10.1186/1479-5876-3-11; PMCID=PMC555742
Adams S., Robbins F.-M., Chen D., Wagage D., Holbeck S.L., Morse H.C. 3rd, Stroncek D., Marincola F.M.
HLA class I and II genotype of the NCI-60 cell lines.
J. Transl. Med. 3:11.1-11.8(2005)
PubMed=17088437; DOI=10.1158/1535-7163.MCT-06-0433; PMCID=PMC2705832
Ikediobi O.N., Davies H.R., Bignell G.R., Edkins S., Stevens C., O'Meara S., Santarius T., Avis T., Barthorpe S., Brackenbury L., Buck G., Butler A.P., Clements J., Cole J., Dicks E., Forbes S., Gray K., Halliday K., Harrison R., Hills K., Hinton J., Hunter C., Jenkinson A., Jones D., Kosmidou V., Lugg R., Menzies A., Miroo T., Parker A., Perry J., Raine K.M., Richardson D., Shepherd R., Small A., Smith R., Solomon H., Stephens P.J., Teague J.W., Tofts C., Varian J., Webb T., West S., Widaa S., Yates A., Reinhold W.C., Weinstein J.N., Stratton M.R., Futreal P.A., Wooster R.
Mutation analysis of 24 known cancer genes in the NCI-60 cell line set.
Mol. Cancer Ther. 5:2606-2612(2006)
PubMed=19372543; DOI=10.1158/1535-7163.MCT-08-0921; PMCID=PMC4020356
Lorenzi P.L., Reinhold W.C., Varma S., Hutchinson A.A., Pommier Y., Chanock S.J., Weinstein J.N.
DNA fingerprinting of the NCI-60 cell line panel.
Mol. Cancer Ther. 8:713-724(2009)
PubMed=20164919; DOI=10.1038/nature08768; PMCID=PMC3145113
Bignell G.R., Greenman C.D., Davies H.R., Butler A.P., Edkins S., Andrews J.M., Buck G., Chen L., Beare D., Latimer C., Widaa S., Hinton J., Fahey C., Fu B.-Y., Swamy S., Dalgliesh G.L., Teh B.T., Deloukas P., Yang F.-T., Campbell P.J., Futreal P.A., Stratton M.R.
Signatures of mutation and selection in the cancer genome.
Nature 463:893-898(2010)
PubMed=20215515; DOI=10.1158/0008-5472.CAN-09-3458; PMCID=PMC2881662
Rothenberg S.M., Mohapatra G., Rivera M.N., Winokur D., Greninger P., Nitta M., Sadow P.M., Sooriyakumar G., Brannigan B.W., Ulman M.J., Perera R.M., Wang R., Tam A., Ma X.-J., Erlander M., Sgroi D.C., Rocco J.W., Lingen M.W., Cohen E.E.W., Louis D.N., Settleman J., Haber D.A.
A genome-wide screen for microdeletions reveals disruption of polarity complex genes in diverse human cancers.
Cancer Res. 70:2158-2164(2010)
PubMed=20570890; DOI=10.1158/0008-5472.CAN-10-0192; PMCID=PMC2943514
Janakiraman M., Vakiani E., Zeng Z.-S., Pratilas C.A., Taylor B.S., Chitale D., Halilovic E., Wilson M., Huberman K., Ricarte Filho J.C.M., Persaud Y., Levine D.A., Fagin J.A., Jhanwar S.C., Mariadason J.M., Lash A., Ladanyi M., Saltz L.B., Heguy A., Paty P.B., Solit D.B.
Genomic and biological characterization of exon 4 KRAS mutations in human cancer.
Cancer Res. 70:5901-5911(2010)
PubMed=22068913; DOI=10.1073/pnas.1111840108; PMCID=PMC3219108
Gillet J.-P., Calcagno A.M., Varma S., Marino M., Green L.J., Vora M.I., Patel C., Orina J.N., Eliseeva T.A., Singal V., Padmanabhan R., Davidson B., Ganapathi R., Sood A.K., Rueda B.R., Ambudkar S.V., Gottesman M.M.
Redefining the relevance of established cancer cell lines to the study of mechanisms of clinical anti-cancer drug resistance.
Proc. Natl. Acad. Sci. U.S.A. 108:18708-18713(2011)
PubMed=22347499; DOI=10.1371/journal.pone.0031628; PMCID=PMC3276511
Ruan X.-Y., Kocher J.-P.A., Pommier Y., Liu H.-F., Reinhold W.C.
Mass homozygotes accumulation in the NCI-60 cancer cell lines as compared to HapMap trios, and relation to fragile site location.
PLoS ONE 7:E31628-E31628(2012)
PubMed=22384151; DOI=10.1371/journal.pone.0032096; PMCID=PMC3285665
Lee J.-S., Kim Y.K., Kim H.J., Hajar S., Tan Y.L., Kang N.-Y., Ng S.H., Yoon C.N., Chang Y.-T.
Identification of cancer cell-line origins using fluorescence image-based phenomic screening.
PLoS ONE 7:E32096-E32096(2012)
PubMed=22460905; DOI=10.1038/nature11003; PMCID=PMC3320027
Barretina J.G., Caponigro G., Stransky N., Venkatesan K., Margolin A.A., Kim S., Wilson C.J., Lehar J., Kryukov G.V., Sonkin D., Reddy A., Liu M., Murray L., Berger M.F., Monahan J.E., Morais P., Meltzer J., Korejwa A., Jane-Valbuena J., Mapa F.A., Thibault J., Bric-Furlong E., Raman P., Shipway A., Engels I.H., Cheng J., Yu G.-Y.K., Yu J.-J., Aspesi P. Jr., de Silva M., Jagtap K., Jones M.D., Wang L., Hatton C., Palescandolo E., Gupta S., Mahan S., Sougnez C., Onofrio R.C., Liefeld T., MacConaill L.E., Winckler W., Reich M., Li N.-X., Mesirov J.P., Gabriel S.B., Getz G., Ardlie K., Chan V., Myer V.E., Weber B.L., Porter J., Warmuth M., Finan P., Harris J.L., Meyerson M.L., Golub T.R., Morrissey M.P., Sellers W.R., Schlegel R., Garraway L.A.
The Cancer Cell Line Encyclopedia enables predictive modelling of anticancer drug sensitivity.
Nature 483:603-607(2012)
PubMed=22628656; DOI=10.1126/science.1218595; PMCID=PMC3526189
Jain M., Nilsson R., Sharma S., Madhusudhan N., Kitami T., Souza A.L., Kafri R., Kirschner M.W., Clish C.B., Mootha V.K.
Metabolite profiling identifies a key role for glycine in rapid cancer cell proliferation.
Science 336:1040-1044(2012)
PubMed=23272949; DOI=10.1186/1755-8794-5-66; PMCID=PMC3543849
Schlicker A., Beran G., Chresta C.M., McWalter G., Pritchard A., Weston S., Runswick S., Davenport S., Heathcote K., Castro D.A., Orphanides G., French T., Wessels L.F.A.
Subtypes of primary colorectal tumors correlate with response to targeted treatment in colorectal cell lines.
BMC Med. Genomics 5:66.1-66.15(2012)
PubMed=23631600; DOI=10.1021/pr400260h
Loftus N.J., Lai L., Wilkinson R.W., Odedra R., Wilson I.D., Barnes A.J.
Global metabolite profiling of human colorectal cancer xenografts in mice using HPLC-MS/MS.
J. Proteome Res. 12:2980-2986(2013)
PubMed=23856246; DOI=10.1158/0008-5472.CAN-12-3342; PMCID=PMC4893961
Abaan O.D., Polley E.C., Davis S.R., Zhu Y.-L.J., Bilke S., Walker R.L., Pineda M.A., Gindin Y., Jiang Y., Reinhold W.C., Holbeck S.L., Simon R.M., Doroshow J.H., Pommier Y., Meltzer P.S.
The exomes of the NCI-60 panel: a genomic resource for cancer biology and systems pharmacology.
Cancer Res. 73:4372-4382(2013)
PubMed=23933261; DOI=10.1016/j.celrep.2013.07.018
Moghaddas Gholami A., Hahne H., Wu Z.-X., Auer F.J., Meng C., Wilhelm M., Kuster B.
Global proteome analysis of the NCI-60 cell line panel.
Cell Rep. 4:609-620(2013)
PubMed=24279929; DOI=10.1186/2049-3002-1-20; PMCID=PMC4178206
Dolfi S.C., Chan L.L.-Y., Qiu J., Tedeschi P.M., Bertino J.R., Hirshfield K.M., Oltvai Z.N., Vazquez A.
The metabolic demands of cancer cells are coupled to their size and protein synthesis rates.
Cancer Metab. 1:20.1-20.13(2013)
PubMed=24670534; DOI=10.1371/journal.pone.0092047; PMCID=PMC3966786
Varma S., Pommier Y., Sunshine M., Weinstein J.N., Reinhold W.C.
High resolution copy number variation data in the NCI-60 cancer cell lines from whole genome microarrays accessible through CellMiner.
PLoS ONE 9:E92047-E92047(2014)
PubMed=24755471; DOI=10.1158/0008-5472.CAN-14-0013
Mouradov D., Sloggett C., Jorissen R.N., Love C.G., Li S., Burgess A.W., Arango D., Strausberg R.L., Buchanan D., Wormald S., O'Connor L., Wilding J.L., Bicknell D.C., Tomlinson I.P.M., Bodmer W.F., Mariadason J.M., Sieber O.M.
Colorectal cancer cell lines are representative models of the main molecular subtypes of primary cancer.
Cancer Res. 74:3238-3247(2014)
PubMed=25984343; DOI=10.1038/sdata.2014.35; PMCID=PMC4432652
Cowley G.S., Weir B.A., Vazquez F., Tamayo P., Scott J.A., Rusin S., East-Seletsky A., Ali L.D., Gerath W.F.J., Pantel S.E., Lizotte P.H., Jiang G.-Z., Hsiao J., Tsherniak A., Dwinell E., Aoyama S., Okamoto M., Harrington W., Gelfand E.T., Green T.M., Tomko M.J., Gopal S., Wong T.C., Li H.-B., Howell S., Stransky N., Liefeld T., Jang D., Bistline J., Meyers B.H., Armstrong S.A., Anderson K.C., Stegmaier K., Reich M., Pellman D., Boehm J.S., Mesirov J.P., Golub T.R., Root D.E., Hahn W.C.
Parallel genome-scale loss of function screens in 216 cancer cell lines for the identification of context-specific genetic dependencies.
Sci. Data 1:140035-140035(2014)
PubMed=25485619; DOI=10.1038/nbt.3080
Klijn C., Durinck S., Stawiski E.W., Haverty P.M., Jiang Z.-S., Liu H.-B., Degenhardt J., Mayba O., Gnad F., Liu J.-F., Pau G., Reeder J., Cao Y., Mukhyala K., Selvaraj S.K., Yu M.-M., Zynda G.J., Brauer M.J., Wu T.D., Gentleman R.C., Manning G., Yauch R.L., Bourgon R., Stokoe D., Modrusan Z., Neve R.M., de Sauvage F.J., Settleman J., Seshagiri S., Zhang Z.-M.
A comprehensive transcriptional portrait of human cancer cell lines.
Nat. Biotechnol. 33:306-312(2015)
PubMed=25841592; DOI=10.1016/j.jprot.2015.03.019
Piersma S.R., Knol J.C., de Reus I., Labots M., Sampadi B.K., Pham T.V., Ishihama Y., Verheul H.M.W., Jimenez C.R.
Feasibility of label-free phosphoproteomics and application to base-line signaling of colorectal cancer cell lines.
J. Proteomics 127:247-258(2015)
PubMed=25877200; DOI=10.1038/nature14397
Yu M., Selvaraj S.K., Liang-Chu M.M.Y., Aghajani S., Busse M., Yuan J., Lee G., Peale F.V., Klijn C., Bourgon R., Kaminker J.S., Neve R.M.
A resource for cell line authentication, annotation and quality control.
Nature 520:307-311(2015)
PubMed=25926053; DOI=10.1038/ncomms8002
Medico E., Russo M., Picco G., Cancelliere C., Valtorta E., Corti G., Buscarino M., Isella C., Lamba S., Martinoglio B., Veronese S., Siena S., Sartore-Bianchi A., Beccuti M., Mottolese M., Linnebacher M., Cordero F., Di Nicolantonio F., Bardelli A.
The molecular landscape of colorectal cancer cell lines unveils clinically actionable kinase targets.
Nat. Commun. 6:7002.1-7002.10(2015)
PubMed=25944804; DOI=10.1158/1078-0432.CCR-14-2457
Bazzocco S., Dopeso H., Carton-Garcia F., Macaya I., Andretta E., Chionh F., Rodrigues P., Garrido M., Alazzouzi H., Nieto R., Sanchez A., Schwartz S. Jr., Bilic J., Mariadason J.M., Arango D.
Highly expressed genes in rapidly proliferating tumor cells as new targets for colorectal cancer treatment.
Clin. Cancer Res. 21:3695-3704(2015)
PubMed=26589293; DOI=10.1186/s13073-015-0240-5; PMCID=PMC4653878
Scholtalbers J., Boegel S., Bukur T., Byl M., Goerges S., Sorn P., Loewer M., Sahin U., Castle J.C.
TCLP: an online cancer cell line catalogue integrating HLA type, predicted neo-epitopes, virus and gene expression.
Genome Med. 7:118.1-118.7(2015)
PubMed=26537799; DOI=10.1074/mcp.M115.051235; PMCID=PMC4762531
Holst S., Deuss A.J.M., van Pelt G.W., van Vliet S.J., Garcia-Vallejo J.J., Koeleman C.A.M., Deelder A.M., Mesker W.E., Tollenaar R.A.E.M., Rombouts Y., Wuhrer M.
N-glycosylation profiling of colorectal cancer cell lines reveals association of fucosylation with differentiation and caudal type homebox 1 (CDX1)/villin mRNA expression.
Mol. Cell. Proteomics 15:124-140(2016)
PubMed=27377824; DOI=10.1038/sdata.2016.52; PMCID=PMC4932877
Mestdagh P., Lefever S., Volders P.-J., Derveaux S., Hellemans J., Vandesompele J.
Long non-coding RNA expression profiling in the NCI60 cancer cell line panel using high-throughput RT-qPCR.
Sci. Data 3:160052-160052(2016)
PubMed=27397505; DOI=10.1016/j.cell.2016.06.017; PMCID=PMC4967469
Iorio F., Knijnenburg T.A., Vis D.J., Bignell G.R., Menden M.P., Schubert M., Aben N., Goncalves E., Barthorpe S., Lightfoot H., Cokelaer T., Greninger P., van Dyk E., Chang H., de Silva H., Heyn H., Deng X.-M., Egan R.K., Liu Q.-S., Miroo T., Mitropoulos X., Richardson L., Wang J.-H., Zhang T.-H., Moran S., Sayols S., Soleimani M., Tamborero D., Lopez-Bigas N., Ross-Macdonald P., Esteller M., Gray N.S., Haber D.A., Stratton M.R., Benes C.H., Wessels L.F.A., Saez-Rodriguez J., McDermott U., Garnett M.J.
A landscape of pharmacogenomic interactions in cancer.
Cell 166:740-754(2016)
PubMed=27807467; DOI=10.1186/s13100-016-0078-4; PMCID=PMC5087121
Zampella J.G., Rodic N., Yang W.R., Huang C.R.L., Welch J., Gnanakkan V.P., Cornish T.C., Boeke J.D., Burns K.H.
A map of mobile DNA insertions in the NCI-60 human cancer cell panel.
Mob. DNA 7:20.1-20.11(2016)
PubMed=28192450; DOI=10.1371/journal.pone.0171435; PMCID=PMC5305277
Fasterius E., Raso C., Kennedy S.A., Rauch N., Lundin P., Kolch W., Uhlen M., Al-Khalili Szigyarto C.
A novel RNA sequencing data analysis method for cell line authentication.
PLoS ONE 12:E0171435-E0171435(2017)
PubMed=28196595; DOI=10.1016/j.ccell.2017.01.005; PMCID=PMC5501076
Li J., Zhao W., Akbani R., Liu W.-B., Ju Z.-L., Ling S.-Y., Vellano C.P., Roebuck P., Yu Q.-H., Eterovic A.K., Byers L.A., Davies M.A., Deng W.-L., Gopal Y.N.V., Chen G., von Euw E.M., Slamon D.J., Conklin D., Heymach J.V., Gazdar A.F., Minna J.D., Myers J.N., Lu Y.-L., Mills G.B., Liang H.
Characterization of human cancer cell lines by reverse-phase protein arrays.
Cancer Cell 31:225-239(2017)
PubMed=28683746; DOI=10.1186/s12943-017-0691-y; PMCID=PMC5498998
Berg K.C.G., Eide P.W., Eilertsen I.A., Johannessen B., Bruun J., Danielsen S.A., Bjornslett M., Meza-Zepeda L.A., Eknaes M., Lind G.E., Myklebost O., Skotheim R.I., Sveen A., Lothe R.A.
Multi-omics of 34 colorectal cancer cell lines -- a resource for biomedical studies.
Mol. Cancer 16:116.1-116.16(2017)
PubMed=28854368; DOI=10.1016/j.celrep.2017.08.010; PMCID=PMC5583477
Roumeliotis T.I., Williams S.P., Goncalves E., Alsinet C., Del Castillo Velasco-Herrera M., Aben N., Ghavidel F.Z., Michaut M., Schubert M., Price S., Wright J.C., Yu L., Yang M., Dienstmann R., Guinney J.H., Beltrao P., Brazma A., Pardo M., Stegle O., Adams D.J., Wessels L.F.A., Saez-Rodriguez J., McDermott U., Choudhary J.S.
Genomic determinants of protein abundance variation in colorectal cancer cells.
Cell Rep. 20:2201-2214(2017)
PubMed=29718670; DOI=10.1021/acs.jproteome.8b00165; PMCID=PMC6670293
Clark D.J., Hu Y.-W., Bocik W., Chen L.-J., Schnaubelt M., Roberts R.R., Shah P., Whiteley G.R., Zhang H.
Evaluation of NCI-7 cell line panel as a reference material for clinical proteomics.
J. Proteome Res. 17:2205-2215(2018)
PubMed=30894373; DOI=10.1158/0008-5472.CAN-18-2747; PMCID=PMC6445675
Dutil J., Chen Z.-H., Monteiro A.N.A., Teer J.K., Eschrich S.A.
An interactive resource to probe genetic diversity and estimated ancestry in cancer cell lines.
Cancer Res. 79:1263-1273(2019)
PubMed=30971826; DOI=10.1038/s41586-019-1103-9
Behan F.M., Iorio F., Picco G., Goncalves E., Beaver C.M., Migliardi G., Santos R., Rao Y., Sassi F., Pinnelli M., Ansari R., Harper S., Jackson D.A., McRae R., Pooley R., Wilkinson P., van der Meer D.J., Dow D., Buser-Doepner C.A., Bertotti A., Trusolino L., Stronach E.A., Saez-Rodriguez J., Yusa K., Garnett M.J.
Prioritization of cancer therapeutic targets using CRISPR-Cas9 screens.
Nature 568:511-516(2019)"
Alley M.C., Scudiero D.A., Monks A., Hursey M.L., Czerwinski M.J., Fine D.L., Abbott B.J., Mayo J.G., Shoemaker R.H., Boyd M.R.
Feasibility of drug screening with panels of human tumor cell lines using a microculture tetrazolium assay.
Cancer Res. 48:589-601(1988)
PubMed=2041050; DOI=10.1093/jnci/83.11.757
Monks A., Scudiero D.A., Skehan P., Shoemaker R.H., Paull K.D., Vistica D.T., Hose C.D., Langley J., Cronise P., Vaigro-Wolff A., Gray-Goodrich M., Campbell H., Mayo J.G., Boyd M.R.
Feasibility of a high-flux anticancer drug screen using a diverse panel of cultured human tumor cell lines.
J. Natl. Cancer Inst. 83:757-766(1991)
PubMed=7651727
Kastrinakis W.V., Ramchurren N., Rieger K.M., Hess D.T., Loda M., Steele G., Summerhayes I.C.
Increased incidence of p53 mutations is associated with hepatic metastasis in colorectal neoplastic progression.
Oncogene 11:647-652(1995)
PubMed=9023415; DOI=10.1006/cimm.1996.1062
Seki N., Hoshino T., Kikuchi M., Hayashi A., Itoh K.
HLA-A locus-restricted and tumor-specific CTLs in tumor-infiltrating lymphocytes of patients with non-small cell lung cancer.
Cell. Immunol. 175:101-110(1997)
PubMed=9294210; DOI=10.1073/pnas.94.19.10330; PMCID=PMC23362
Ilyas M., Tomlinson I.P.M., Rowan A.J., Pignatelli M., Bodmer W.F.
Beta-catenin mutations in cell lines established from human colorectal cancers.
Proc. Natl. Acad. Sci. U.S.A. 94:10330-10334(1997)
PubMed=10051639; DOI=10.1073/pnas.96.5.2316; PMCID=PMC26781
Efstathiou J.A., Liu D., Wheeler J.M.D., Kim H.C., Beck N.E., Ilyas M., Karayiannakis A.J., Mortensen N.J., Kmiot W.A.W., Playford R.J., Pignatelli M., Bodmer W.F.
Mutated epithelial cadherin is associated with increased tumorigenicity and loss of adhesion and of responsiveness to the motogenic trefoil factor 2 in colon carcinoma cells.
Proc. Natl. Acad. Sci. U.S.A. 96:2316-2321(1999)
PubMed=10674020; DOI=10.1016/S0959-8049(99)00206-3
Ku J.-L., Yoon K.-A., Kim D.-Y., Park J.-G.
Mutations in hMSH6 alone are not sufficient to cause the microsatellite instability in colorectal cancer cell lines.
Eur. J. Cancer 35:1724-1729(1999)
PubMed=10700174; DOI=10.1038/73432
Ross D.T., Scherf U., Eisen M.B., Perou C.M., Rees C., Spellman P.T., Iyer V.R., Jeffrey S.S., van de Rijn M., Waltham M.C., Pergamenschikov A., Lee J.C.F., Lashkari D., Shalon D., Myers T.G., Weinstein J.N., Botstein D., Brown P.O.
Systematic variation in gene expression patterns in human cancer cell lines.
Nat. Genet. 24:227-235(2000)
PubMed=10737795; DOI=10.1073/pnas.97.7.3352; PMCID=PMC16243
Rowan A.J., Lamlum H., Ilyas M., Wheeler J.M.D., Straub J., Papadopoulou A., Bicknell D.C., Bodmer W.F., Tomlinson I.P.M.
APC mutations in sporadic colorectal tumors: a mutational 'hotspot' and interdependence of the 'two hits'.
Proc. Natl. Acad. Sci. U.S.A. 97:3352-3357(2000)
PubMed=11414198; DOI=10.1007/s004320000207
Lahm H., Andre S., Hoeflich A., Fischer J.R., Sordat B., Kaltner H., Wolf E., Gabius H.-J.
Comprehensive galectin fingerprinting in a panel of 61 human tumor cell lines by RT-PCR and its implications for diagnostic and therapeutic procedures.
J. Cancer Res. Clin. Oncol. 127:375-386(2001)
PubMed=12068308; DOI=10.1038/nature00766
Davies H.R., Bignell G.R., Cox C., Stephens P.J., Edkins S., Clegg S., Teague J.W., Woffendin H., Garnett M.J., Bottomley W., Davis N., Dicks E., Ewing R., Floyd Y., Gray K., Hall S., Hawes R., Hughes J., Kosmidou V., Menzies A., Mould C., Parker A., Stevens C., Watt S., Hooper S., Wilson R., Jayatilake H., Gusterson B.A., Cooper C.S., Shipley J.M., Hargrave D., Pritchard-Jones K., Maitland N.J., Chenevix-Trench G., Riggins G.J., Bigner D.D., Palmieri G., Cossu A., Flanagan A.M., Nicholson A., Ho J.W.C., Leung S.Y., Yuen S.T., Weber B.L., Seigler H.F., Darrow T.L., Paterson H.F., Marais R., Marshall C.J., Wooster R., Stratton M.R., Futreal P.A.
Mutations of the BRAF gene in human cancer.
Nature 417:949-954(2002)
PubMed=12584437; DOI=10.1159/000068544
Melcher R., Koehler S., Steinlein C., Schmid M., Mueller C.R., Luehrs H., Menzel T., Scheppach W., Moerk H., Scheurlen M., Koehrle J., Al-Taie O.
Spectral karyotype analysis of colon cancer cell lines of the tumor suppressor and mutator pathway.
Cytogenet. Genome Res. 98:22-28(2002)
PubMed=15748285; DOI=10.1186/1479-5876-3-11; PMCID=PMC555742
Adams S., Robbins F.-M., Chen D., Wagage D., Holbeck S.L., Morse H.C. 3rd, Stroncek D., Marincola F.M.
HLA class I and II genotype of the NCI-60 cell lines.
J. Transl. Med. 3:11.1-11.8(2005)
PubMed=17088437; DOI=10.1158/1535-7163.MCT-06-0433; PMCID=PMC2705832
Ikediobi O.N., Davies H.R., Bignell G.R., Edkins S., Stevens C., O'Meara S., Santarius T., Avis T., Barthorpe S., Brackenbury L., Buck G., Butler A.P., Clements J., Cole J., Dicks E., Forbes S., Gray K., Halliday K., Harrison R., Hills K., Hinton J., Hunter C., Jenkinson A., Jones D., Kosmidou V., Lugg R., Menzies A., Miroo T., Parker A., Perry J., Raine K.M., Richardson D., Shepherd R., Small A., Smith R., Solomon H., Stephens P.J., Teague J.W., Tofts C., Varian J., Webb T., West S., Widaa S., Yates A., Reinhold W.C., Weinstein J.N., Stratton M.R., Futreal P.A., Wooster R.
Mutation analysis of 24 known cancer genes in the NCI-60 cell line set.
Mol. Cancer Ther. 5:2606-2612(2006)
PubMed=19372543; DOI=10.1158/1535-7163.MCT-08-0921; PMCID=PMC4020356
Lorenzi P.L., Reinhold W.C., Varma S., Hutchinson A.A., Pommier Y., Chanock S.J., Weinstein J.N.
DNA fingerprinting of the NCI-60 cell line panel.
Mol. Cancer Ther. 8:713-724(2009)
PubMed=20164919; DOI=10.1038/nature08768; PMCID=PMC3145113
Bignell G.R., Greenman C.D., Davies H.R., Butler A.P., Edkins S., Andrews J.M., Buck G., Chen L., Beare D., Latimer C., Widaa S., Hinton J., Fahey C., Fu B.-Y., Swamy S., Dalgliesh G.L., Teh B.T., Deloukas P., Yang F.-T., Campbell P.J., Futreal P.A., Stratton M.R.
Signatures of mutation and selection in the cancer genome.
Nature 463:893-898(2010)
PubMed=20215515; DOI=10.1158/0008-5472.CAN-09-3458; PMCID=PMC2881662
Rothenberg S.M., Mohapatra G., Rivera M.N., Winokur D., Greninger P., Nitta M., Sadow P.M., Sooriyakumar G., Brannigan B.W., Ulman M.J., Perera R.M., Wang R., Tam A., Ma X.-J., Erlander M., Sgroi D.C., Rocco J.W., Lingen M.W., Cohen E.E.W., Louis D.N., Settleman J., Haber D.A.
A genome-wide screen for microdeletions reveals disruption of polarity complex genes in diverse human cancers.
Cancer Res. 70:2158-2164(2010)
PubMed=20570890; DOI=10.1158/0008-5472.CAN-10-0192; PMCID=PMC2943514
Janakiraman M., Vakiani E., Zeng Z.-S., Pratilas C.A., Taylor B.S., Chitale D., Halilovic E., Wilson M., Huberman K., Ricarte Filho J.C.M., Persaud Y., Levine D.A., Fagin J.A., Jhanwar S.C., Mariadason J.M., Lash A., Ladanyi M., Saltz L.B., Heguy A., Paty P.B., Solit D.B.
Genomic and biological characterization of exon 4 KRAS mutations in human cancer.
Cancer Res. 70:5901-5911(2010)
PubMed=22068913; DOI=10.1073/pnas.1111840108; PMCID=PMC3219108
Gillet J.-P., Calcagno A.M., Varma S., Marino M., Green L.J., Vora M.I., Patel C., Orina J.N., Eliseeva T.A., Singal V., Padmanabhan R., Davidson B., Ganapathi R., Sood A.K., Rueda B.R., Ambudkar S.V., Gottesman M.M.
Redefining the relevance of established cancer cell lines to the study of mechanisms of clinical anti-cancer drug resistance.
Proc. Natl. Acad. Sci. U.S.A. 108:18708-18713(2011)
PubMed=22347499; DOI=10.1371/journal.pone.0031628; PMCID=PMC3276511
Ruan X.-Y., Kocher J.-P.A., Pommier Y., Liu H.-F., Reinhold W.C.
Mass homozygotes accumulation in the NCI-60 cancer cell lines as compared to HapMap trios, and relation to fragile site location.
PLoS ONE 7:E31628-E31628(2012)
PubMed=22384151; DOI=10.1371/journal.pone.0032096; PMCID=PMC3285665
Lee J.-S., Kim Y.K., Kim H.J., Hajar S., Tan Y.L., Kang N.-Y., Ng S.H., Yoon C.N., Chang Y.-T.
Identification of cancer cell-line origins using fluorescence image-based phenomic screening.
PLoS ONE 7:E32096-E32096(2012)
PubMed=22460905; DOI=10.1038/nature11003; PMCID=PMC3320027
Barretina J.G., Caponigro G., Stransky N., Venkatesan K., Margolin A.A., Kim S., Wilson C.J., Lehar J., Kryukov G.V., Sonkin D., Reddy A., Liu M., Murray L., Berger M.F., Monahan J.E., Morais P., Meltzer J., Korejwa A., Jane-Valbuena J., Mapa F.A., Thibault J., Bric-Furlong E., Raman P., Shipway A., Engels I.H., Cheng J., Yu G.-Y.K., Yu J.-J., Aspesi P. Jr., de Silva M., Jagtap K., Jones M.D., Wang L., Hatton C., Palescandolo E., Gupta S., Mahan S., Sougnez C., Onofrio R.C., Liefeld T., MacConaill L.E., Winckler W., Reich M., Li N.-X., Mesirov J.P., Gabriel S.B., Getz G., Ardlie K., Chan V., Myer V.E., Weber B.L., Porter J., Warmuth M., Finan P., Harris J.L., Meyerson M.L., Golub T.R., Morrissey M.P., Sellers W.R., Schlegel R., Garraway L.A.
The Cancer Cell Line Encyclopedia enables predictive modelling of anticancer drug sensitivity.
Nature 483:603-607(2012)
PubMed=22628656; DOI=10.1126/science.1218595; PMCID=PMC3526189
Jain M., Nilsson R., Sharma S., Madhusudhan N., Kitami T., Souza A.L., Kafri R., Kirschner M.W., Clish C.B., Mootha V.K.
Metabolite profiling identifies a key role for glycine in rapid cancer cell proliferation.
Science 336:1040-1044(2012)
PubMed=23272949; DOI=10.1186/1755-8794-5-66; PMCID=PMC3543849
Schlicker A., Beran G., Chresta C.M., McWalter G., Pritchard A., Weston S., Runswick S., Davenport S., Heathcote K., Castro D.A., Orphanides G., French T., Wessels L.F.A.
Subtypes of primary colorectal tumors correlate with response to targeted treatment in colorectal cell lines.
BMC Med. Genomics 5:66.1-66.15(2012)
PubMed=23631600; DOI=10.1021/pr400260h
Loftus N.J., Lai L., Wilkinson R.W., Odedra R., Wilson I.D., Barnes A.J.
Global metabolite profiling of human colorectal cancer xenografts in mice using HPLC-MS/MS.
J. Proteome Res. 12:2980-2986(2013)
PubMed=23856246; DOI=10.1158/0008-5472.CAN-12-3342; PMCID=PMC4893961
Abaan O.D., Polley E.C., Davis S.R., Zhu Y.-L.J., Bilke S., Walker R.L., Pineda M.A., Gindin Y., Jiang Y., Reinhold W.C., Holbeck S.L., Simon R.M., Doroshow J.H., Pommier Y., Meltzer P.S.
The exomes of the NCI-60 panel: a genomic resource for cancer biology and systems pharmacology.
Cancer Res. 73:4372-4382(2013)
PubMed=23933261; DOI=10.1016/j.celrep.2013.07.018
Moghaddas Gholami A., Hahne H., Wu Z.-X., Auer F.J., Meng C., Wilhelm M., Kuster B.
Global proteome analysis of the NCI-60 cell line panel.
Cell Rep. 4:609-620(2013)
PubMed=24279929; DOI=10.1186/2049-3002-1-20; PMCID=PMC4178206
Dolfi S.C., Chan L.L.-Y., Qiu J., Tedeschi P.M., Bertino J.R., Hirshfield K.M., Oltvai Z.N., Vazquez A.
The metabolic demands of cancer cells are coupled to their size and protein synthesis rates.
Cancer Metab. 1:20.1-20.13(2013)
PubMed=24670534; DOI=10.1371/journal.pone.0092047; PMCID=PMC3966786
Varma S., Pommier Y., Sunshine M., Weinstein J.N., Reinhold W.C.
High resolution copy number variation data in the NCI-60 cancer cell lines from whole genome microarrays accessible through CellMiner.
PLoS ONE 9:E92047-E92047(2014)
PubMed=24755471; DOI=10.1158/0008-5472.CAN-14-0013
Mouradov D., Sloggett C., Jorissen R.N., Love C.G., Li S., Burgess A.W., Arango D., Strausberg R.L., Buchanan D., Wormald S., O'Connor L., Wilding J.L., Bicknell D.C., Tomlinson I.P.M., Bodmer W.F., Mariadason J.M., Sieber O.M.
Colorectal cancer cell lines are representative models of the main molecular subtypes of primary cancer.
Cancer Res. 74:3238-3247(2014)
PubMed=25984343; DOI=10.1038/sdata.2014.35; PMCID=PMC4432652
Cowley G.S., Weir B.A., Vazquez F., Tamayo P., Scott J.A., Rusin S., East-Seletsky A., Ali L.D., Gerath W.F.J., Pantel S.E., Lizotte P.H., Jiang G.-Z., Hsiao J., Tsherniak A., Dwinell E., Aoyama S., Okamoto M., Harrington W., Gelfand E.T., Green T.M., Tomko M.J., Gopal S., Wong T.C., Li H.-B., Howell S., Stransky N., Liefeld T., Jang D., Bistline J., Meyers B.H., Armstrong S.A., Anderson K.C., Stegmaier K., Reich M., Pellman D., Boehm J.S., Mesirov J.P., Golub T.R., Root D.E., Hahn W.C.
Parallel genome-scale loss of function screens in 216 cancer cell lines for the identification of context-specific genetic dependencies.
Sci. Data 1:140035-140035(2014)
PubMed=25485619; DOI=10.1038/nbt.3080
Klijn C., Durinck S., Stawiski E.W., Haverty P.M., Jiang Z.-S., Liu H.-B., Degenhardt J., Mayba O., Gnad F., Liu J.-F., Pau G., Reeder J., Cao Y., Mukhyala K., Selvaraj S.K., Yu M.-M., Zynda G.J., Brauer M.J., Wu T.D., Gentleman R.C., Manning G., Yauch R.L., Bourgon R., Stokoe D., Modrusan Z., Neve R.M., de Sauvage F.J., Settleman J., Seshagiri S., Zhang Z.-M.
A comprehensive transcriptional portrait of human cancer cell lines.
Nat. Biotechnol. 33:306-312(2015)
PubMed=25841592; DOI=10.1016/j.jprot.2015.03.019
Piersma S.R., Knol J.C., de Reus I., Labots M., Sampadi B.K., Pham T.V., Ishihama Y., Verheul H.M.W., Jimenez C.R.
Feasibility of label-free phosphoproteomics and application to base-line signaling of colorectal cancer cell lines.
J. Proteomics 127:247-258(2015)
PubMed=25877200; DOI=10.1038/nature14397
Yu M., Selvaraj S.K., Liang-Chu M.M.Y., Aghajani S., Busse M., Yuan J., Lee G., Peale F.V., Klijn C., Bourgon R., Kaminker J.S., Neve R.M.
A resource for cell line authentication, annotation and quality control.
Nature 520:307-311(2015)
PubMed=25926053; DOI=10.1038/ncomms8002
Medico E., Russo M., Picco G., Cancelliere C., Valtorta E., Corti G., Buscarino M., Isella C., Lamba S., Martinoglio B., Veronese S., Siena S., Sartore-Bianchi A., Beccuti M., Mottolese M., Linnebacher M., Cordero F., Di Nicolantonio F., Bardelli A.
The molecular landscape of colorectal cancer cell lines unveils clinically actionable kinase targets.
Nat. Commun. 6:7002.1-7002.10(2015)
PubMed=25944804; DOI=10.1158/1078-0432.CCR-14-2457
Bazzocco S., Dopeso H., Carton-Garcia F., Macaya I., Andretta E., Chionh F., Rodrigues P., Garrido M., Alazzouzi H., Nieto R., Sanchez A., Schwartz S. Jr., Bilic J., Mariadason J.M., Arango D.
Highly expressed genes in rapidly proliferating tumor cells as new targets for colorectal cancer treatment.
Clin. Cancer Res. 21:3695-3704(2015)
PubMed=26589293; DOI=10.1186/s13073-015-0240-5; PMCID=PMC4653878
Scholtalbers J., Boegel S., Bukur T., Byl M., Goerges S., Sorn P., Loewer M., Sahin U., Castle J.C.
TCLP: an online cancer cell line catalogue integrating HLA type, predicted neo-epitopes, virus and gene expression.
Genome Med. 7:118.1-118.7(2015)
PubMed=26537799; DOI=10.1074/mcp.M115.051235; PMCID=PMC4762531
Holst S., Deuss A.J.M., van Pelt G.W., van Vliet S.J., Garcia-Vallejo J.J., Koeleman C.A.M., Deelder A.M., Mesker W.E., Tollenaar R.A.E.M., Rombouts Y., Wuhrer M.
N-glycosylation profiling of colorectal cancer cell lines reveals association of fucosylation with differentiation and caudal type homebox 1 (CDX1)/villin mRNA expression.
Mol. Cell. Proteomics 15:124-140(2016)
PubMed=27377824; DOI=10.1038/sdata.2016.52; PMCID=PMC4932877
Mestdagh P., Lefever S., Volders P.-J., Derveaux S., Hellemans J., Vandesompele J.
Long non-coding RNA expression profiling in the NCI60 cancer cell line panel using high-throughput RT-qPCR.
Sci. Data 3:160052-160052(2016)
PubMed=27397505; DOI=10.1016/j.cell.2016.06.017; PMCID=PMC4967469
Iorio F., Knijnenburg T.A., Vis D.J., Bignell G.R., Menden M.P., Schubert M., Aben N., Goncalves E., Barthorpe S., Lightfoot H., Cokelaer T., Greninger P., van Dyk E., Chang H., de Silva H., Heyn H., Deng X.-M., Egan R.K., Liu Q.-S., Miroo T., Mitropoulos X., Richardson L., Wang J.-H., Zhang T.-H., Moran S., Sayols S., Soleimani M., Tamborero D., Lopez-Bigas N., Ross-Macdonald P., Esteller M., Gray N.S., Haber D.A., Stratton M.R., Benes C.H., Wessels L.F.A., Saez-Rodriguez J., McDermott U., Garnett M.J.
A landscape of pharmacogenomic interactions in cancer.
Cell 166:740-754(2016)
PubMed=27807467; DOI=10.1186/s13100-016-0078-4; PMCID=PMC5087121
Zampella J.G., Rodic N., Yang W.R., Huang C.R.L., Welch J., Gnanakkan V.P., Cornish T.C., Boeke J.D., Burns K.H.
A map of mobile DNA insertions in the NCI-60 human cancer cell panel.
Mob. DNA 7:20.1-20.11(2016)
PubMed=28192450; DOI=10.1371/journal.pone.0171435; PMCID=PMC5305277
Fasterius E., Raso C., Kennedy S.A., Rauch N., Lundin P., Kolch W., Uhlen M., Al-Khalili Szigyarto C.
A novel RNA sequencing data analysis method for cell line authentication.
PLoS ONE 12:E0171435-E0171435(2017)
PubMed=28196595; DOI=10.1016/j.ccell.2017.01.005; PMCID=PMC5501076
Li J., Zhao W., Akbani R., Liu W.-B., Ju Z.-L., Ling S.-Y., Vellano C.P., Roebuck P., Yu Q.-H., Eterovic A.K., Byers L.A., Davies M.A., Deng W.-L., Gopal Y.N.V., Chen G., von Euw E.M., Slamon D.J., Conklin D., Heymach J.V., Gazdar A.F., Minna J.D., Myers J.N., Lu Y.-L., Mills G.B., Liang H.
Characterization of human cancer cell lines by reverse-phase protein arrays.
Cancer Cell 31:225-239(2017)
PubMed=28683746; DOI=10.1186/s12943-017-0691-y; PMCID=PMC5498998
Berg K.C.G., Eide P.W., Eilertsen I.A., Johannessen B., Bruun J., Danielsen S.A., Bjornslett M., Meza-Zepeda L.A., Eknaes M., Lind G.E., Myklebost O., Skotheim R.I., Sveen A., Lothe R.A.
Multi-omics of 34 colorectal cancer cell lines -- a resource for biomedical studies.
Mol. Cancer 16:116.1-116.16(2017)
PubMed=28854368; DOI=10.1016/j.celrep.2017.08.010; PMCID=PMC5583477
Roumeliotis T.I., Williams S.P., Goncalves E., Alsinet C., Del Castillo Velasco-Herrera M., Aben N., Ghavidel F.Z., Michaut M., Schubert M., Price S., Wright J.C., Yu L., Yang M., Dienstmann R., Guinney J.H., Beltrao P., Brazma A., Pardo M., Stegle O., Adams D.J., Wessels L.F.A., Saez-Rodriguez J., McDermott U., Choudhary J.S.
Genomic determinants of protein abundance variation in colorectal cancer cells.
Cell Rep. 20:2201-2214(2017)
PubMed=29718670; DOI=10.1021/acs.jproteome.8b00165; PMCID=PMC6670293
Clark D.J., Hu Y.-W., Bocik W., Chen L.-J., Schnaubelt M., Roberts R.R., Shah P., Whiteley G.R., Zhang H.
Evaluation of NCI-7 cell line panel as a reference material for clinical proteomics.
J. Proteome Res. 17:2205-2215(2018)
PubMed=30894373; DOI=10.1158/0008-5472.CAN-18-2747; PMCID=PMC6445675
Dutil J., Chen Z.-H., Monteiro A.N.A., Teer J.K., Eschrich S.A.
An interactive resource to probe genetic diversity and estimated ancestry in cancer cell lines.
Cancer Res. 79:1263-1273(2019)
PubMed=30971826; DOI=10.1038/s41586-019-1103-9
Behan F.M., Iorio F., Picco G., Goncalves E., Beaver C.M., Migliardi G., Santos R., Rao Y., Sassi F., Pinnelli M., Ansari R., Harper S., Jackson D.A., McRae R., Pooley R., Wilkinson P., van der Meer D.J., Dow D., Buser-Doepner C.A., Bertotti A., Trusolino L., Stronach E.A., Saez-Rodriguez J., Yusa K., Garnett M.J.
Prioritization of cancer therapeutic targets using CRISPR-Cas9 screens.
Nature 568:511-516(2019)"
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