"Hs 578T人乳腺癌复苏细胞保种中心|带STR证书
传代比例:1:2-1:4(首次传代建议1:2)
生长特性:贴壁生长
贴壁细胞的消化方法介绍:1、胰酶。这是用得Zui多的。一般浓度在0.25-0.5%。作用时间根据细胞种类、作用温度等因素而变化很大,从几分钟到几十分钟不等。0.25%的胰酶作用于单层贴壁的细胞,在37度条件下,一般消化1-5分钟就足够了。终止是用血清。主要作用于细胞间。配制时不能用含、镁的平衡,否则影响活性。保存于-20度。2、胶原酶。这种方法比较少,一般是用原代培养时,从组织消化下细胞。这种方法作用温和,对细胞损伤较小,但是,价格也较贵。中止同样是用血清。3、EDA。用得也是非常多。一般浓度在0.02%左右。作用于细胞与间质,对细胞间也有一定作用。注意,它能显著影响pH值,而且在弱碱性条件下才易溶。因此,配制时应调节HAO碱度。它不能被终和。因此,消化下来的细胞要洗一遍。4、商品化的无酶消化。个人的使用经常觉得对细胞的损伤比较大,但是分离成单细胞悬的能力确实比较强。5、物理法。直接吹打或用细胞刮子将细胞刮下来。6、冷冻法。此方法仅能用于细胞传代时。无法使组织上的细胞脱落下来。本方法的原理,我想是因细胞冷冻后收缩,从而从培养瓶上脱落下来。YOU点是:对细胞损伤小,不需要中止或洗细胞,方便,不需要另外配制消化。别适用那些贴壁不是别紧,又别娇气的细胞。不足是细胞常成小片脱落。此种方法曾用于因用其它方法传代导致大量细胞死亡操作的间充质干细胞、DC细胞的培养,效果非常满意。具体过程是:1、用较多的4度的PBS 洗涤一遍细胞(以6孔板为例,加1.5ml/孔),2、再加0.5毫升4度的PBS,静置操作台上,很快细胞就小片脱落,3、轻轻吹打,细胞即完全脱落,4、按一定比例传代。
换液周期:每周2-3次
BEL-7404 Cells;背景说明:用Northernblot方法,未能检测到细胞中1.3kbLFIRE-1/HFREP-1mRNA的表达。;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:上皮细胞样;相关产品有:CO115细胞、RPMI.8226细胞、High5细胞
PC-9S1 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:TK 10细胞、MDA-MB436细胞、RMG-I细胞
SCLC-21H Cells;背景说明:小细胞肺癌;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:详见产品说明书;相关产品有:SPCA-1细胞、NCIH2107细胞、231-luc细胞
Hs 578T人乳腺癌复苏细胞保种中心|带STR证书
背景信息:是一种来源于人的乳腺癌细胞系,最初从一名51岁女性患者的乳腺癌组织中分离得到。它与正常成纤维细胞样细胞株Hs 578Bst起源于同一位患者。Hs 578T细胞最初是多角形的,但在传代过程中选择并克隆了星形的细胞形态。电镜下观察发现,Hs 578T细胞内酪蛋白颗粒聚集、桥粒紧密连接、脂质体和光滑内质网小泡。Hs 578T细胞与Hs 578Bst细胞一样,未检测到雌激素受体和内生病毒。
细胞系的应用:1)免疫组化研究2)RNA干扰研究3)药物作用研究4)慢病毒转染研究等其它应用。细胞系通常用于实验研究,如增殖、迁移、侵袭等。细胞系在多个领域的研究中被广泛应用,包括基础医学、临床试验、药物筛选和分子生物学研究。这些研究不仅在中国,也在日本、美国和欧洲等多个国家和地区进行。
产品包装:复苏发货:T25培养瓶(一瓶)或冻存发货:1ml冻存管(两支)
来源说明:细胞主要来源ATCC、ECACC、DSMZ、RIKEN等细胞库
BC3H-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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:769P细胞、ETCC007细胞、GEO细胞
HCC0366 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:MCF/Adr细胞、RN-c细胞、NTC200细胞
HNEpC Cells;背景说明:鼻粘膜;上皮 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:详见产品说明书;相关产品有:Jurkat-77细胞、M-NFS-60细胞、C4-I细胞
OVCAR433 Cells;背景说明:卵巢癌;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:详见产品说明书;相关产品有:BEL/FU细胞、HBZY-1细胞、Lilly Laboratories Cell-Monkey Kidney 2细胞
Hs 578T人乳腺癌复苏细胞保种中心|带STR证书
物种来源:人源、鼠源等其它物种来源
形态特性:上皮细胞样
实验室细胞培养基知识简介:干粉培养基:以前大部分实验室都是用干粉培养基,但配制过程就较为繁琐,要溶解、调pH值,过滤,过程中可能会产生一些浓度误差,而且有些实验室的水质并不理想,所以培养的效果会有差异。如果使用体培养基,这种人为的误差会减少,因为毕竟是大批量工业化生产的,批间差会很小。大家是不是感觉体培养基会贵很多,以前是这样,但现在大家都认同了;无血清培养基(Serum-Free Media),通常以SFM表示,顾名思义,就是在细胞培养中不需要添加血清,但是在某些应用中可能要添加生长因子或细胞因子。无血清培养基中添加了血清的主要成分:粘附因子、生长因子、必需的营养物质和激素等,能减少上述血清带来的不利因素,使细胞培养的条件更稳定。但它也不是完美的,从有血清培养过渡到无血清培养的条件并不像想象中那么直截了当。处于发育的不同分化阶段的细胞(例如干细胞与定向前体细胞相比)需要不同的配方,对生长因子和细胞因子的选择尤为重要。而且在去除血清的同时,也去除了一些血清蛋白具有的保护、解毒作用,因此对试剂、水的纯度和仪器清洁度的要求更GAO。另外,它的价格也比普通的培养基贵很多。
U373 MG Cells;背景说明:胶质瘤;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:详见产品说明书;相关产品有:D-341细胞、NUGC-4细胞、H-1395细胞
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:详见产品说明书;相关产品有:NCI-H2023细胞、MIN6细胞、NCIH1568细胞
TE12 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:UMNSAH/DF#1细胞、Rat podocyte细胞、OCI-Ly 1细胞
K1735 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:详见产品说明书;相关产品有:C3H 10T1/2细胞、Hs 742.T细胞、LI7细胞
HSC-5 [Human skin squamous cell carcinoma] Cells;背景说明:皮肤鳞癌;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:详见产品说明书;相关产品有:Y3M细胞、HPAF2细胞、MLM细胞
Caki-1 Cells;背景说明:该细胞超微结构中包含许多微绒毛、少许微丝、许多小线粒体、发达的高尔基休和内质网、许多脂滴和多层体、次级溶酶体,没有发现病毒颗粒。;传代方法:1:2-1:4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:NPA-87细胞、NCIH929细胞、GM-3573细胞
Kit 225-K6 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:3T3-F442A细胞、PIEC细胞、SK-MEL-3细胞
NCI-H2228 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2-3次。;生长特性:贴壁生长;形态特性:详见产品说明书;相关产品有:HEM细胞、CaES-17细胞、Jiyoye(P-2003)细胞
H-1623 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:贴壁生长;形态特性:详见产品说明书;相关产品有:HOP-92细胞、Caki-2细胞、MFM-223细胞
K7M2 wt Cells;背景说明:骨肉瘤;肺转移;雌性;BALB/c;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:详见产品说明书;相关产品有:Caov-4细胞、J-774A.1细胞、Jeko1细胞
H283 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:悬浮细胞的多细胞聚集体,和一些贴壁 Cells;形态特性:上皮细胞;相关产品有:U266 Bl细胞、beta TC6细胞、Gerner 7666细胞
HBZY 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:上皮细胞样;相关产品有:HOS-MNNG细胞、HEK-293F细胞、REC1细胞
H1954 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:Eca109细胞、HEK-293-FT细胞、EAC细胞
HS578T 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:MDA-468细胞、EAhy 926细胞、LA-N-6(OAN)细胞
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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:U-251 MG细胞、Kasumi 1细胞、ID8细胞
Panc 5.04 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:WBF344细胞、CA-OV-3细胞、MESSA Dx5细胞
A-673 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:成纤维细胞;相关产品有:NCI-H2085细胞、Biopsy xenograft of Pancreatic Carcinoma line-3细胞、KG-1a细胞
Hs 578T人乳腺癌复苏细胞保种中心|带STR证书
Abcam HEK293T DCXR KO Cells(提供STR鉴定图谱)
AG09896 Cells(提供STR鉴定图谱)
BayGenomics ES cell line NPX305 Cells(提供STR鉴定图谱)
BayGenomics ES cell line XC510 Cells(提供STR鉴定图谱)
BT-474 Tam1 Cells(提供STR鉴定图谱)
COS-7-InVitrus Cells(提供STR鉴定图谱)
DA04038 Cells(提供STR鉴定图谱)
DUR 10R Cells(提供STR鉴定图谱)
GM04290 Cells(提供STR鉴定图谱)
MC-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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:HCC-1428细胞、C3A细胞、Hs 683细胞
NCI-H2052 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:6传代;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:KYSE 180细胞、H22细胞、16HBE140细胞
H1963 Cells;背景说明:详见相关文献介绍;传代方法:每周换液2次。;生长特性:悬浮生长;形态特性:详见产品说明书;相关产品有:SK Col 1细胞、GA-10 clone 4细胞、MCF-7/ADR细胞
SK-OV-3 Cells;背景说明:SK-OV-3由G.Trempe和L.J.Old在1973年从卵巢肿瘤病人的腹水分离得到。 此细胞对肿瘤坏死因子和几种细胞毒性药物包括白喉毒素、顺铂和阿霉素均耐受。 在裸鼠中致瘤,且形成与卵巢原位癌一致的中度分化的腺癌。;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:上皮细胞样;相关产品有:WM-239-A细胞、TCMK1细胞、NCIH2405细胞
NOZC-1 Cells;背景说明:患者有癌性腹膜炎。细胞为中等分化的管状胆囊癌。会分泌AFP和CEA。倍增时间48小时,板植率14-19%。细胞可在裸鼠中成瘤,形态与原发肿瘤相似。;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:上皮细胞样;相关产品有:F442A细胞、MFE-280细胞、Hs 636.T细胞
RASMC Cells;背景说明:主动脉;平滑肌 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:详见产品说明书;相关产品有:OCI-Ly8细胞、TPC-1细胞、WSU-DLCL-2细胞
776.1 Cells(提供STR鉴定图谱)
MiaPaCa-2 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:详见产品说明书;相关产品有:TW-039细胞、FET细胞、Potorous tridactylus Kidney 1细胞
H2.35 Cells;背景说明:肝;SV40转化;雌性;BALB/c;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:详见产品说明书;相关产品有:LNT-229细胞、CCD1112Sk细胞、Karpas 299细胞
OCI-LY-8 Cells;背景说明:弥漫大B淋巴瘤;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:详见产品说明书;相关产品有:SKO007细胞、NCI-H2591细胞、HOP-62细胞
MAVER-1 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:5传代;2-3天换液1次。;生长特性:悬浮生长;形态特性:淋巴母细胞;相关产品有:AML-193细胞、NCI-H2170细胞、SNU-520细胞
HT-1376 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:详见产品说明书;相关产品有:SUSM1细胞、NCI-H716细胞、KBM7细胞
H-520 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:贴壁或悬浮,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:QGP-1细胞、UPCI-SCC090细胞、CPAE细胞
MRASMC 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:Tohoku Hospital Pediatrics-1细胞、EC9706细胞、CCD-18Co细胞
NCI-H102 Cells;背景说明:详见相关文献介绍;传代方法:1:3传代,2-3天传一代;生长特性:悬浮生长 ;形态特性:圆形;淋巴母细胞样;相关产品有:KHYG1细胞、B/C3T3细胞、WIL2 S细胞
H9 AAVS1-TRE3G-NGN2 RETREG3-/- RETREG2-/- RETREG1-/- TEX264-/- Keima-REEP5 Cells(提供STR鉴定图谱)
HAP1 REPS1 (-) 2 Cells(提供STR鉴定图谱)
HEL-92 Cells;背景说明:详见相关文献介绍;传代方法:每周2-3次。;生长特性:悬浮生长;形态特性:成淋巴细胞;相关产品有:Hs 737.T细胞、NCIH1184细胞、PT-K75细胞
C3H/10T1/2-clone8 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:MSF细胞、SW-962细胞、NSC-34细胞
BNL-CL.2 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:详见产品说明书;相关产品有:NW-MEL-38细胞、HSF细胞、P31-FUJ细胞
CATH.a Cells;背景说明:神经;SV40转化;C57BL/6 x DBA/2;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:详见产品说明书;相关产品有:ECC 12细胞、NCIADRRES细胞、SUP-M2细胞
Hs 27 Cells;背景说明:包皮;成纤维细胞;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:详见产品说明书;相关产品有:TE-13细胞、A101D细胞、HEP-3B2细胞
SUM 190PT 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:详见产品说明书;相关产品有:LS174T细胞、HeLaS3细胞、NE-1细胞
Capan-2 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:4传代,2-3天换液1次。;生长特性:贴壁生长;形态特性:多边形;相关产品有:H-1341细胞、NOR 10细胞、NG10815细胞
PL-45 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:KPNRTBM1细胞、SAOS 2细胞、DHL-4细胞
HuT-12 Cells(提供STR鉴定图谱)
LA8 Cells(提供STR鉴定图谱)
MuM-2C Cells(提供STR鉴定图谱)
ORMES-6 Cells(提供STR鉴定图谱)
RP1-hiPSC11 Cells(提供STR鉴定图谱)
Ubigene HEK293 CCDC150 KO Cells(提供STR鉴定图谱)
WEHI-231 Cells(提供STR鉴定图谱)
HG01172 Cells(提供STR鉴定图谱)
D283 Med 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:悬浮细胞的多细胞聚集体,和一些贴壁 Cells;形态特性:上皮细胞;相关产品有:253JB-V细胞、L 428细胞、BC3H1细胞
H-1155 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:悬浮生长;形态特性:上皮细胞;相关产品有:143BTK-细胞、LN 229细胞、hADSCs细胞
SUDHL5 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:T98-G细胞、NEC-8细胞、KP 4细胞
Tb 1-Lu 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:详见产品说明书;相关产品有:BNL-HCC细胞、NCIH1688细胞、GM07404D细胞
KE-39 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:Hs706T细胞、SUP-B1细胞、T47D:A细胞
KE-39 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:Hs706T细胞、SUP-B1细胞、T47D:A细胞
SKGT4 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:BEND细胞、HCC15细胞、CCRF SB细胞
NOR10 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:NCI-SNU-387细胞、SL-29细胞、UM-UC14细胞
NCI-H1299 Cells;背景说明:这株细胞来源于一个淋巴结转移。患者接受了初期放疗。细胞均一性的部分缺失p53蛋白,并缺少p53蛋白表达。细胞可以合成0.1pmol/毫克蛋白的NMB蛋白,而不合成促胃液释放肽(GRP)。;传代方法:1:2传代;3天传代一次。;生长特性:贴壁生长;形态特性:上皮样;多角形;相关产品有:COR-L23细胞、Madison 109细胞、C643细胞
NG 108-15 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:GM03569B细胞、MDA-MB-436细胞、A431细胞
Kato-III Cells;背景说明:详见相关文献介绍;传代方法:1:2传代。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:Ramos 1细胞、Mel-RM细胞、ME180细胞
Kit 225 K6 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:H-1385细胞、251 MG细胞、VMM5细胞
MDAPCa2b Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:4传代,2-3天换液1次。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:TE3细胞、JM1细胞、Lieming Xu-2细胞
GA-10-Clone-4 Cells;背景说明:详见相关文献介绍;传代方法:每2-3天换液;生长特性:悬浮生长 ;形态特性:淋巴母细胞样;相关产品有:MGH-U3细胞、NCIH2135细胞、SKLMS-1细胞
WM 2664 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:详见产品说明书;相关产品有:TE-9细胞、SK-MEL24细胞、MV411细胞
T78-1 Cells(提供STR鉴定图谱)
LMTK- 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:ECV细胞、MUM2B细胞、MOLM-13细胞
RKOAS451 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:T2(174 x CEM.T2)细胞、H-2141细胞、H-820细胞
HuO9 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:SW1990细胞、MDA-436细胞、BT.549细胞
PT-K75 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:成纤维细胞样;相关产品有:KBM5细胞、NCIH548细胞、HMVEC细胞
University of Michigan-Urothelial Carcinoma-14 Cells;背景说明:肾癌;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:详见产品说明书;相关产品有:Fortner's melanotic melanoma #3细胞、3T3-442A细胞、HCCC9810细胞
MCF 7B Cells;背景说明:浸润性导管癌;胸腔积液转移;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:详见产品说明书;相关产品有:J-111细胞、CCD 1112SK细胞、Hep 2细胞
H-719 Cells;背景说明:小细胞肺癌;骨髓转移;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:半贴壁;形态特性:详见产品说明书;相关产品有:Caki2细胞、H1155细胞、HuT 102细胞
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:HCC1359细胞、CCD 841 CoTr细胞、HSKMC细胞
HB 611 Cells;背景说明:肝母细胞癌;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:详见产品说明书;相关产品有:RPMI #1846细胞、CAL12T细胞、H2405细胞
MB39 Cells;背景说明:脑瘤;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:详见产品说明书;相关产品有:Mc Ardle 7777细胞、3AA细胞、COR-L51细胞
SHG44 Cells;背景说明:SHG-44细胞株源自一例2-3级前沿淋巴结星细胞瘤。染色体组型显示89.2%的超三倍体。在Wistar大鼠和裸鼠中接种都能成功。细胞含有神经系统特有的S-100蛋白和星细胞特有的GFA蛋白;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:成纤维细胞样;相关产品有:HEK293S细胞、CFSC-2G细胞、Douglas Foster-1细胞
AMO1 Cells;背景说明:浆细胞骨髓瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:半贴壁;形态特性:详见产品说明书;相关产品有:RKO-AS-45-1细胞、PANC 327细胞、RPMI no. 8226细胞
alpha TC1-6 Cells;背景说明:胰岛素瘤;a细胞;C57BL/6xDBA/2;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:详见产品说明书;相关产品有:SKGT2细胞、GTL-16细胞、SNU-C1细胞
MGH-U3 (RN) 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,详见产品说明书部分;形态特性:详见产品说明书;相关产品有:SW 48细胞、NCI-H1793细胞、SkChA1细胞
Hs 578T人乳腺癌复苏细胞保种中心|带STR证书
BayGenomics ES cell line RRP138 Cells(提供STR鉴定图谱)
BayGenomics ES cell line YHC200 Cells(提供STR鉴定图谱)
Hep-56.1C Cells(提供STR鉴定图谱)
PCRP-CSTF2-1A11 Cells(提供STR鉴定图谱)
c-SST-2 clone 6 Cells(提供STR鉴定图谱)
HPS0584 Cells(提供STR鉴定图谱)
" "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=1961733; DOI=10.1073/pnas.88.23.10657; PMCID=PMC52989
Runnebaum I.B., Nagarajan M., Bowman M., Soto D., Sukumar S.
Mutations in p53 as potential molecular markers for human breast cancer.
Proc. Natl. Acad. Sci. U.S.A. 88:10657-10661(1991)
PubMed=7902062
de la Torre M., Hao X.-Y., Larsson R., Nygren P., Tsuruo T., Mannervik B., Bergh J.
Characterization of four doxorubicin adapted human breast cancer cell lines with respect to chemotherapeutic drug sensitivity, drug resistance associated membrane proteins and glutathione transferases.
Anticancer Res. 13:1425-1430(1993)
DOI=10.1016/B978-0-12-333530-2.50009-5
Leibovitz A.
Cell lines from human breast.
(In book chapter) Atlas of human tumor cell lines; Hay R.J., Park J.-G., Gazdar A.F. (eds.); pp.161-184; Academic Press; New York; USA (1994)
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=10969801
Forozan F., Mahlamaki E.H., Monni O., Chen Y.-D., Veldman R., Jiang Y., Gooden G.C., Ethier S.P., Kallioniemi A.H., Kallioniemi O.-P.
Comparative genomic hybridization analysis of 38 breast cancer cell lines: a basis for interpreting complementary DNA microarray data.
Cancer Res. 60:4519-4525(2000)
PubMed=15153330; DOI=10.1593/neo.3292; PMCID=PMC1502105
Watts G.S., Oshiro M.M., Junk D.J., Wozniak R.J., Watterson S.J., Domann F.E., Futscher B.W.
The acetyltransferase p300/CBP-associated factor is a p53 target gene in breast tumor cells.
Neoplasia 6:187-194(2004)
PubMed=15677628; DOI=10.1093/carcin/bgi032
Gorringe K.L., Chin S.-F., Pharoah P.D.P., Staines J.M., Oliveira C., Edwards P.A.W., Caldas C.
Evidence that both genetic instability and selection contribute to the accumulation of chromosome alterations in cancer.
Carcinogenesis 26:923-930(2005)
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=16142302; DOI=10.3892/ijo.27.4.881
de Longueville F., Lacroix M., Barbuto A.-M., Bertholet V., Gallo D., Larsimont D., Marcq L., Zammatteo N., Boffe S., Leclercq G., Remacle J.
Molecular characterization of breast cancer cell lines by a low-density microarray.
Int. J. Oncol. 27:881-892(2005)
PubMed=16397213; DOI=10.1158/0008-5472.CAN-05-2853
Elstrodt F., Hollestelle A., Nagel J.H.A., Gorin M., Wasielewski M., van den Ouweland A.M.W., Merajver S.D., Ethier S.P., Schutte M.
BRCA1 mutation analysis of 41 human breast cancer cell lines reveals three new deleterious mutants.
Cancer Res. 66:41-45(2006)
PubMed=16541312; DOI=10.1007/s10549-006-9186-z
Wasielewski M., Elstrodt F., Klijn J.G.M., Berns E.M.J.J., Schutte M.
Thirteen new p53 gene mutants identified among 41 human breast cancer cell lines.
Breast Cancer Res. Treat. 99:97-101(2006)
PubMed=16959974; DOI=10.1126/science.1133427
Sjoblom T., Jones S., Wood L.D., Parsons D.W., Lin J., Barber T.D., Mandelker D., Leary R.J., Ptak J., Silliman N., Szabo S., Buckhaults P., Farrell C., Meeh P., Markowitz S.D., Willis J.E., Dawson D., Willson J.K.V., Gazdar A.F., Hartigan J., Wu L., Liu C.-S., Parmigiani G., Park B.H., Bachman K.E., Papadopoulos N., Vogelstein B., Kinzler K.W., Velculescu V.E.
The consensus coding sequences of human breast and colorectal cancers.
Science 314:268-274(2006)
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=17157791; DOI=10.1016/j.ccr.2006.10.008; PMCID=PMC2730521
Neve R.M., Chin K., Fridlyand J., Yeh J., Baehner F.L., Fevr T., Clark L., Bayani N., Coppe J.-P., Tong F., Speed T., Spellman P.T., DeVries S., Lapuk A., Wang N.J., Kuo W.-L., Stilwell J.L., Pinkel D., Albertson D.G., Waldman F.M., McCormick F., Dickson R.B., Johnson M.D., Lippman M.E., Ethier S.P., Gazdar A.F., Gray J.W.
A collection of breast cancer cell lines for the study of functionally distinct cancer subtypes.
Cancer Cell 10:515-527(2006)
PubMed=17932254; DOI=10.1126/science.1145720
Wood L.D., Parsons D.W., Jones S., Lin J., Sjoblom T., Leary R.J., Shen D., Boca S.M., Barber T.D., Ptak J., Silliman N., Szabo S., Dezso Z., Ustyanksky V., Nikolskaya T., Nikolsky Y., Karchin R., Wilson P.A., Kaminker J.S., Zhang Z.-M., Croshaw R., Willis J.E., Dawson D., Shipitsin M., Willson J.K.V., Sukumar S., Polyak K., Park B.H., Pethiyagoda C.L., Pant P.V.K., Ballinger D.G., Sparks A.B., Hartigan J., Smith D.R., Suh E., Papadopoulos N., Buckhaults P., Markowitz S.D., Parmigiani G., Kinzler K.W., Velculescu V.E., Vogelstein B.
The genomic landscapes of human breast and colorectal cancers.
Science 318:1108-1113(2007)
PubMed=18516279; DOI=10.1016/j.molonc.2007.02.004; PMCID=PMC2391005
Kenny P.A., Lee G.Y., Myers C.A., Neve R.M., Semeiks J.R., Spellman P.T., Lorenz K., Lee E.H., Barcellos-Hoff M.H., Petersen O.W., Gray J.W., Bissell M.J.
The morphologies of breast cancer cell lines in three-dimensional assays correlate with their profiles of gene expression.
Mol. Oncol. 1:84-96(2007)
PubMed=18277095; DOI=10.4161/cbt.7.5.5712
Berglind H., Pawitan Y., Kato S., Ishioka C., Soussi T.
Analysis of p53 mutation status in human cancer cell lines: a paradigm for cell line cross-contamination.
Cancer Biol. Ther. 7:699-708(2008)
PubMed=18386134; DOI=10.1007/s10585-008-9169-z
Hughes L., Malone C., Chumsri S., Burger A.M., McDonnell S.
Characterisation of breast cancer cell lines and establishment of a novel isogenic subclone to study migration, invasion and tumourigenicity.
Clin. Exp. Metastasis 25:549-557(2008)
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=19582160; DOI=10.1371/journal.pone.0006146; PMCID=PMC2702084
Kao J., Salari K., Bocanegra M., Choi Y.-L., Girard L., Gandhi J., Kwei K.A., Hernandez-Boussard T., Wang P., Gazdar A.F., Minna J.D., Pollack J.R.
Molecular profiling of breast cancer cell lines defines relevant tumor models and provides a resource for cancer gene discovery.
PLoS ONE 4:E6146-E6146(2009)
DOI=10.25904/1912/1434
Morrison B.J.
Breast cancer stem cells: tumourspheres and implications for therapy.
Thesis PhD (2010); Griffith University; Brisbane; Australia
PubMed=19593635; DOI=10.1007/s10549-009-0460-8
Hollestelle A., Nagel J.H.A., Smid M., Lam S., Elstrodt F., Wasielewski M., Ng S.S., French P.J., Peeters J.K., Rozendaal M.J., Riaz M., Koopman D.G., ten Hagen T.L.M., de Leeuw B.H.C.G.M., Zwarthoff E.C., Teunisse A.F.A.S., van der Spek P.J., Klijn J.G.M., Dinjens W.N.M., Ethier S.P., Clevers H.C., Jochemsen A.G., den Bakker M.A., Foekens J.A., Martens J.W.M., Schutte M.
Distinct gene mutation profiles among luminal-type and basal-type breast cancer cell lines.
Breast Cancer Res. Treat. 121:53-64(2010)
PubMed=20070913; DOI=10.1186/1471-2407-10-15; PMCID=PMC2836299
Tsuji K., Kawauchi S., Saito S., Furuya T., Ikemoto K., Nakao M., Yamamoto S., Oka M., Hirano T., Sasaki K.
Breast cancer cell lines carry cell line-specific genomic alterations that are distinct from aberrations in breast cancer tissues: comparison of the CGH profiles between cancer cell lines and primary cancer tissues.
BMC Cancer 10:15.1-15.10(2010)
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=21778573; DOI=10.3233/BD-2010-0307; PMCID=PMC3532890
Chavez K.J., Garimella S.V., Lipkowitz S.
Triple negative breast cancer cell lines: one tool in the search for better treatment of triple negative breast cancer.
Breast Dis. 32:35-48(2010)
DOI=10.4172/2157-7145.S2-005
Fang R.-X., Shewale J.G., Nguyen V.T., Cardoso H., Swerdel M.R., Hart R.P., Furtado M.R.
STR profiling of human cell lines: challenges and possible solutions to the growing problem.
J. Forensic Res. 2 Suppl. 2:5-5(2011)
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=22585861; DOI=10.1158/2159-8290.CD-11-0224; PMCID=PMC5057396
Marcotte R., Brown K.R., Suarez Saiz F.J., Sayad A., Karamboulas K., Krzyzanowski P.M., Sircoulomb F., Medrano M., Fedyshyn Y., Koh J.L.-Y., van Dyk D., Fedyshyn B., Luhova M., Brito G.C., Vizeacoumar F.J., Vizeacoumar F.S., Datti A., Kasimer D., Buzina A., Mero P., Misquitta C., Normand J., Haider M., Ketela T., Wrana J.L., Rottapel R., Neel B.G., Moffat J.
Essential gene profiles in breast, pancreatic, and ovarian cancer cells.
Cancer Discov. 2:172-189(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=23151021; DOI=10.1186/1471-2164-13-619; PMCID=PMC3546428
Grigoriadis A., Mackay A., Noel E., Wu P.-J., Natrajan R., Frankum J., Reis-Filho J.S., Tutt A.
Molecular characterisation of cell line models for triple-negative breast cancers.
BMC Genomics 13:619.1-619.14(2012)
PubMed=23601657; DOI=10.1186/bcr3415; PMCID=PMC3672661
Riaz M., van Jaarsveld M.T.M., Hollestelle A., Prager-van der Smissen W.J.C., Heine A.A.J., Boersma A.W.M., Liu J.-J., Helmijr J.C.A., Ozturk B., Smid M., Wiemer E.A.C., Foekens J.A., Martens J.W.M.
miRNA expression profiling of 51 human breast cancer cell lines reveals subtype and driver mutation-specific miRNAs.
Breast Cancer Res. 15:R33.1-R33.17(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=24009699; DOI=10.1371/journal.pone.0072704; PMCID=PMC3751845
Liu X., Nie H., Zhang Y.-B., Yao Y.-F., Maitikabili A., Qu Y.-P., Shi S.-L., Chen C.-Y., Li Y.
Cell surface-specific N-glycan profiling in breast cancer.
PLoS ONE 8:E72704-E72704(2013)
PubMed=24094812; DOI=10.1016/j.ccr.2013.08.020; PMCID=PMC3931310
Timmerman L.A., Holton T., Yuneva M., Louie R.J., Padro M., Daemen A., Hu M., Chan D.A., Ethier S.P., van 't Veer L.J., Polyak K., McCormick F., Gray J.W.
Glutamine sensitivity analysis identifies the xCT antiporter as a common triple-negative breast tumor therapeutic target.
Cancer Cell 24:450-465(2013)
PubMed=24162158; DOI=10.1007/s10549-013-2743-3; PMCID=PMC3832776
Prat A., Karginova O., Parker J.S., Fan C., He X.-P., Bixby L.M., Harrell J.C., Roman E., Adamo B., Troester M.A., Perou C.M.
Characterization of cell lines derived from breast cancers and normal mammary tissues for the study of the intrinsic molecular subtypes.
Breast Cancer Res. Treat. 142:237-255(2013)
PubMed=24176112; DOI=10.1186/gb-2013-14-10-r110; PMCID=PMC3937590
Daemen A., Griffith O.L., Heiser L.M., Wang N.J., Enache O.M., Sanborn Z., Pepin F., Durinck S., Korkola J.E., Griffith M., Hur J.S., Huh N., Chung J., Cope L., Fackler M.J., Umbricht C.B., Sukumar S., Seth P., Sume V.P., Jakkula L.R., Lu Y.-L., Mills G.B., Cho R.J., Collisson E.A., van 't Veer L.J., Spellman P.T., Gray J.W.
Modeling precision treatment of breast cancer.
Genome Biol. 14:R110.1-R110.14(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=25960936; DOI=10.4161/21624011.2014.954893; PMCID=PMC4355981
Boegel S., Lower M., Bukur T., Sahin U., Castle J.C.
A catalog of HLA type, HLA expression, and neo-epitope candidates in human cancer cell lines.
OncoImmunology 3:e954893.1-e954893.12(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=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=25892236; DOI=10.1016/j.celrep.2015.03.050; PMCID=PMC4425736
Lawrence R.T., Perez E.M., Hernandez D., Miller C.P., Haas K.M., Irie H.Y., Lee S.-I., Blau C.A., Villen J.
The proteomic landscape of triple-negative breast cancer.
Cell Rep. 11:630-644(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=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=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=28287265; DOI=10.1021/acs.jproteome.6b00470; PMCID=PMC5557415
Yen T.-Y., Bowen S., Yen R., Piryatinska A., Macher B.A., Timpe L.C.
Glycoproteins in claudin-low breast cancer cell lines have a unique expression profile.
J. Proteome Res. 16:1391-1400(2017)
PubMed=28889351; DOI=10.1007/s10549-017-4496-x
Saunus J.M., Smart C.E., Kutasovic J.R., Johnston R.L., Kalita-de Croft P., Miranda M., Rozali E.N., Vargas A.C., Reid L.E., Lorsy E., Cocciardi S., Seidens T., McCart Reed A.E., Dalley A.J., Wockner L.F., Johnson J., Sarkar D., Askarian-Amiri M.E., Simpson P.T., Khanna K.K., Chenevix-Trench G., Al-Ejeh F., Lakhani S.R.
Multidimensional phenotyping of breast cancer cell lines to guide preclinical research.
Breast Cancer Res. Treat. 167:289-301(2018)
PubMed=29671673; DOI=10.1080/24701394.2018.1461852
Hedberg A., Knutsen E., Lovhaugen A.S., Jorgensen T.E., Perander M., Johansen S.D.
Cancer-specific SNPs originate from low-level heteroplasmic variants in human mitochondrial genomes of a matched cell line pair.
Mitochondrial DNA A. DNA Mapp. Seq. Anal. 30:82-91(2019)
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)"
