"HT-29人結(jié)腸癌細(xì)胞全年復(fù)蘇|已有STR圖譜
傳代比例:1:2-1:4(首次傳代建議1:2)
生長特性:貼壁生長
細(xì)胞系的選擇需要考慮到細(xì)胞系的功能特點�、生長速率����、鋪板效率����、生長條件和生長特征�����、克隆效率��、培養(yǎng)方式等因素�,如果您想高產(chǎn)量表達重組蛋白,您可以選擇可以懸浮生長的快速生長細(xì)胞系�。細(xì)胞培養(yǎng)的操作步驟主要包括傳代、換液���、凍存和復(fù)蘇����。這些步驟確保了細(xì)胞能夠在實驗室環(huán)境中長期存活并繼續(xù)增殖。傳代是將細(xì)胞從一個容器轉(zhuǎn)移到另一個容器的過程����,以擴大細(xì)胞數(shù)量;換液是為了清除代謝廢物并補充新鮮培養(yǎng)基�����;凍存則是為了長期保存細(xì)胞�����,而復(fù)蘇則是重新激活冷凍保存的細(xì)胞使其恢復(fù)正常生長�。
換液周期:每周2-3次
NCI-H2286 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:4傳代;每周換液2次�����。;生長特性:貼壁生長;形態(tài)特性:橢圓形;相關(guān)產(chǎn)品有:SBC-5細(xì)胞���、OVCAR.4細(xì)胞、NTera2/D1細(xì)胞
Hs-281-T Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代,每周換液2-3次�。;生長特性:貼壁生長;形態(tài)特性:成纖維細(xì)胞;相關(guān)產(chǎn)品有:NPC-TW01細(xì)胞、OVCA432_Bast細(xì)胞、HT 1080細(xì)胞
NCI H747 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2—1:4傳代�����,每周換液2次;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:NKL細(xì)胞�����、HeLa-S3細(xì)胞����、Colon 26細(xì)胞
背景信息:該細(xì)胞是1964年由FoghJ用移植培養(yǎng)方法和含15%FBS的F12培養(yǎng)從原發(fā)性腫瘤分離的。近來��,已建株的培養(yǎng)細(xì)胞用含血清的McCoy's5a培養(yǎng)基培養(yǎng)�。該細(xì)胞系在裸鼠中成瘤,也能在類固醇處理的地鼠中成瘤��。該細(xì)胞可合成IgA����、A、TGFβ結(jié)合蛋白和黏素����;表達尿激酶受體�����,但沒有檢測到血漿酶原活性����;不表達CD4�����,但細(xì)胞表面表達半乳糖神經(jīng)酰胺(HIV的可能替代受體)��。該細(xì)胞系癌基因c-myc���、K-ras�����、H-ras��、N-ras��、Myb��、sis�、fos陽性���;p53基因過表達�,并且在273位密碼子處發(fā)
HT-29人結(jié)腸癌細(xì)胞全年復(fù)蘇|已有STR圖譜
產(chǎn)品包裝:復(fù)蘇發(fā)貨:T25培養(yǎng)瓶(一瓶)或凍存發(fā)貨:1ml凍存管(兩支)
DSMZ菌株保藏中心成立于1969年���,是德國的國家菌種保藏中心�����。該中心一直致力于細(xì)菌�、真菌���、質(zhì)粒�����、抗菌素����、人體和動物細(xì)胞��、植物病毒等的分類��、鑒定和保藏工作。DSMZ菌種保藏中心是歐洲規(guī)模最大的生物資源中心���,保藏有動物細(xì)胞500多株����。Riken BRC成立于1920年�����,是英國的國家菌種保藏中心��。該中心一直致力于細(xì)菌�、真菌、植物病毒等的分類���、鑒定和保藏工作�����。日本Riken BRC(Riken生物資源保藏中心)是全球三大典型培養(yǎng)物收集中心之一�����。Riken保藏中心提供了很多細(xì)胞系�����。在世界范圍內(nèi)��,這些細(xì)胞系�����,都在醫(yī)學(xué)��、科學(xué)和獸醫(yī)中具有重要意義���。Riken生物資源中心支持了各種學(xué)術(shù)、健康�����、食品和獸醫(yī)機構(gòu)的研究工作����,并在世界各地不同組織的微生物實驗室和研究機構(gòu)中使用。
NCI H295R Cells;背景說明:腎上腺皮質(zhì)癌����;女性;傳代方法:1:2-1:3傳代����;每周換液2-3次����。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:NCI-H1092細(xì)胞、RERFLCMS細(xì)胞�����、SUIT2細(xì)胞
NIH:OVCAR-10 Cells;背景說明:卵巢癌��;女性;傳代方法:1:2-1:3傳代����;每周換液2-3次。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:RPTEC TERT1細(xì)胞�����、HONE-1細(xì)胞��、MDA MB 175 VII細(xì)胞
ROS17/28 Cells;背景說明:骨肉瘤��;ACI 9935;傳代方法:1:2-1:3傳代;每周換液2-3次�。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Immortalized Human Hepatocytes細(xì)胞、MC57G細(xì)胞�、IGROV-1細(xì)胞
4D3 [Mouse hybridoma against human unknown protein] Cells(提供STR鑒定圖譜)
來源說明:細(xì)胞主要來源ATCC、ECACC���、DSMZ�����、RIKEN等細(xì)胞庫
物種來源:人源、鼠源等其它物種來源
HT-29人結(jié)腸癌細(xì)胞全年復(fù)蘇|已有STR圖譜
形態(tài)特性:上皮細(xì)胞樣
貼壁細(xì)胞消化傳代時通常采用兩種方法:一����、加入胰酶等細(xì)胞脫落后,再加培養(yǎng)基中止胰酶作用���,離心傳代���;二、加入胰酶后���,鏡下觀察待細(xì)胞始脫落時�����,棄胰酶����,加培養(yǎng)分瓶。但前者太麻煩�����,而后者有可能對細(xì)胞施加胰酶選擇�����,因為總是貼壁不牢的細(xì)胞先脫落�,對腫瘤細(xì)胞來說,這部分細(xì)胞有可能是惡性程度較GAO的細(xì)胞亞群����。一種簡單的消化傳代方法。加入PBS洗去血清或加入胰酶先中和血清的作用(30s)�,棄之,再加入適量胰酶作用10s-40s(根據(jù)細(xì)胞消化的難易程度)�����,棄之,這樣依賴殘余的胰酶就可將細(xì)胞消化單細(xì)胞��。對于較難消化的細(xì)胞���,可以用2%利多卡因消化5-8分鐘�����,然后再棄去��,加培養(yǎng)基吹打也可以���,對細(xì)胞的影響不大。不用PBS也不用Hanks洗�����,只要把舊培養(yǎng)吸的干凈一點���,直接加酶消化應(yīng)該不會有什么問題。棄培養(yǎng)后��,用0.04%的EDA沖洗一次�,再用1/4v的0.04%的EDA室溫孵育5min,棄取大部分EDA,加入與剩余EDA等量的胰酶(預(yù)熱)總體積1/10v��。消化到有細(xì)胞脫落�����。不過有人說EDA對細(xì)胞不HAO�����,有證據(jù)嗎���?培養(yǎng)的BASMC:倒掉舊培養(yǎng)加入少量胰酶沖一下��,倒掉再加入0.125-0.25%胰酶約6-10滴或1ml(25ml bole)消化再加入適量新培養(yǎng)基中和�,并分瓶這種方法簡單��、省事��;效果很HAO并且不損失細(xì)胞��!
Caco2-BBE Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:6—1:10傳代����,每周換液2次;生長特性:貼壁生長;形態(tài)特性:上皮細(xì)胞;相關(guān)產(chǎn)品有:Hs729細(xì)胞���、OCI-AML5細(xì)胞、Embryonic Bovine Tracheal cells細(xì)胞
COLO320-DM Cells;背景說明:該細(xì)胞可產(chǎn)生5-羥色胺��、去甲���、��、ACTH和甲狀旁腺素�����。角蛋白���、波形蛋白弱陽性。培養(yǎng)條件: RPMI 1640 10%FBS;傳代方法:1:2-1:3傳代�;每周換液2-3次。;生長特性:懸浮+貼壁;形態(tài)特性:淋巴細(xì)胞;相關(guān)產(chǎn)品有:HuO9細(xì)胞���、RBMEC細(xì)胞、Cloudman S91 melanoma clone M-3細(xì)胞
RenCa Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮細(xì)胞樣;相關(guān)產(chǎn)品有:NIE 115細(xì)胞��、SVOG細(xì)胞�����、MT-2細(xì)胞
NCI-H3255 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:CATH-a細(xì)胞、C8166-CD4細(xì)胞��、H-196細(xì)胞
PLC PRF 5 Cells;背景說明:該細(xì)胞系分泌乙肝病毒表面抗原(HBsAg)�。 此細(xì)胞系原先被支原體污染,后用BM-cycline去除支原體;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:RLE-6TN細(xì)胞�、U-2932細(xì)胞、DMS-53細(xì)胞
Tu-212 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:SNU-475細(xì)胞���、NCI-H526細(xì)胞���、V79-4細(xì)胞
K 562 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代;每周換液2-3次��。;生長特性:貼壁或懸浮���,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Walker/LLC-WRC 256細(xì)胞����、RPMI2650細(xì)胞�����、H-1568細(xì)胞
NCI-SNU-5 Cells;背景說明:該細(xì)胞來源于一名低分化胃癌患者的轉(zhuǎn)移性腹水,1987年分離建立�����。該細(xì)胞表達CEA和TAG-72��。;傳代方法:2-3天補液一次���。;生長特性:多細(xì)胞聚集�、懸浮生長;形態(tài)特性:上皮細(xì)胞樣;相關(guān)產(chǎn)品有:HRMC細(xì)胞���、RIN-14B細(xì)胞���、THC-8307細(xì)胞
Mc Ardle 7777 Cells;背景說明:肝癌;雌性�����;Buffalo;傳代方法:1:2-1:3傳代���;每周換液2-3次。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:PLC-PRF-5細(xì)胞��、MBMEC細(xì)胞、SUDHL-6細(xì)胞
Hi5 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代��;每周換液2-3次����。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:JC細(xì)胞�����、SKCO1細(xì)胞�、CEMx721.174.T2細(xì)胞
PC-10 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代;每周換液2-3次�����。;生長特性:貼壁或懸浮���,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:NCI-HUT-69細(xì)胞�、NCIH2591細(xì)胞�、P3X63NS1細(xì)胞
LNCaP-Clone-FGC Cells;背景說明:人前列腺癌細(xì)胞LNCaP克隆FGC是從一位50歲白人男性(血型B+)的左鎖骨淋巴結(jié)針刺活檢中分離,該患者經(jīng)確診為前列腺癌轉(zhuǎn)移����。 這株細(xì)胞對5-α-二睪酮(生長調(diào)節(jié)子和酸性脂酶產(chǎn)物)有響應(yīng)�����。這株細(xì)胞并不形成一致的單層���,而是形成集落,在傳代時可以用滴管反復(fù)吹吸打碎�。它們僅僅輕輕地吸附在基底上,不形成匯合����,很快使培養(yǎng)基變酸。生長很慢����。傳代后48小時內(nèi)不應(yīng)擾動。當(dāng)培養(yǎng)瓶封包后���,多數(shù)細(xì)胞從培養(yǎng)瓶底分離�����,懸浮在培養(yǎng)基中��。收到后��,在通常培養(yǎng)單層細(xì)胞的條件下培養(yǎng)24到48小時��,以合細(xì)胞再貼壁���。;傳代方法:消化3-5分鐘。1:2����。3天內(nèi)可長滿。;生長特性:貼壁生長;形態(tài)特性:上皮細(xì)胞;相關(guān)產(chǎn)品有:H1954細(xì)胞���、3T6 Swiss Albino細(xì)胞�����、Tj-905細(xì)胞
Hep 3B Cells;背景說明:肝癌�;男性;傳代方法:1:2-1:3傳代���;每周換液2-3次���。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Factor Dependent Continuous-Paterson 1細(xì)胞、SNGM細(xì)胞、HEK 293 c18細(xì)胞
E0771 Cells;背景說明:惡性乳腺癌�;雌性;C57BL/6;傳代方法:1:2-1:3傳代�;每周換液2-3次。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Human Corneal Epithelial cells-Transformed細(xì)胞��、BC-3-H-I細(xì)胞��、kms 11細(xì)胞
BMF Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:4傳代;生長特性:貼壁生長;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:TK10細(xì)胞�、SW 1990細(xì)胞、N9細(xì)胞
SUNE 1 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代���;每周換液2-3次�����。;生長特性:貼壁或懸浮��,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Buffalo Rat Liver-3A細(xì)胞�����、SUDHL6細(xì)胞����、GLAG-66細(xì)胞
LC1 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代;每周換液2-3次����。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:PAa細(xì)胞�����、EA. hy 926細(xì)胞��、AN3 CA細(xì)胞
Abcam HCT 116 BRD3 KO Cells(提供STR鑒定圖譜)
AG04457 Cells(提供STR鑒定圖譜)
BayGenomics ES cell line CSI167 Cells(提供STR鑒定圖譜)
BayGenomics ES cell line RST389 Cells(提供STR鑒定圖譜)
BFTC-905-diffuse M Cells(提供STR鑒定圖譜)
CHO203PV Cells(提供STR鑒定圖譜)
DA03036 Cells(提供STR鑒定圖譜)
DDaF-1 Cells(提供STR鑒定圖譜)
GM02527 Cells(提供STR鑒定圖譜)
WC00079 Cells;背景說明:黑色素瘤�����;女性;傳代方法:1:2-1:3傳代�;每周換液2-3次�。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:A549ATCC細(xì)胞、MKN74細(xì)胞�����、D 407細(xì)胞
CLONE M3 Cells;背景說明:黑色素瘤����;雄性;DBA;傳代方法:1:2-1:3傳代;每周換液2-3次����。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:P3-X63-Ag 8.653細(xì)胞、A3細(xì)胞�、HPAF-II細(xì)胞
Moorfields/Institute of Ophthalmology-Muller 1 Cells;背景說明:視網(wǎng)膜Muller細(xì)胞;自發(fā)永生��;女性;傳代方法:1:2-1:3傳代�;每周換液2-3次。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:PC 12細(xì)胞�����、NCI-H810細(xì)胞�、Hs 578.T細(xì)胞
H-820 Cells;背景說明:乳頭狀肺腺癌;淋巴結(jié)轉(zhuǎn)移�����;男性;傳代方法:1:2-1:3傳代�����;每周換液2-3次�����。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:PC-3M IE8細(xì)胞、HNE-2細(xì)胞����、Onda 11細(xì)胞
A-375 Cells;背景說明:A375源自一位54歲女性,是Giard DJ等人建立的一系列細(xì)胞株中的一株�。該細(xì)胞可在免疫抑制小鼠上成瘤,在瓊脂上形成克隆�。;傳代方法:1:2-1:3傳代;每周換液2-3次�。;生長特性:貼壁;形態(tài)特性:上皮細(xì)胞樣;相關(guān)產(chǎn)品有:H647ell細(xì)胞��、A.704細(xì)胞��、Hs683T細(xì)胞
RPMI-1846 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代���;每周換液2-3次��。;生長特性:貼壁或懸浮��,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Hs940.T細(xì)胞���、NCI-HUT-125細(xì)胞�、HUASMC細(xì)胞
KLM-1 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代����;每周換液2-3次。;生長特性:貼壁或懸浮�����,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:RPE1細(xì)胞��、KALS1細(xì)胞�、MEL細(xì)胞
PL-9 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:IOSE-29細(xì)胞、NCIH508細(xì)胞���、NPC-039細(xì)胞
HT-29人結(jié)腸癌細(xì)胞全年復(fù)蘇|已有STR圖譜
MEL Cells;背景說明:DMSO可誘導(dǎo)該細(xì)胞向紅系分化�����。;傳代方法:1:2-1:3傳代����;每周換液2-3次���。;生長特性:貼壁;形態(tài)特性:上皮細(xì)胞樣;相關(guān)產(chǎn)品有:RS411細(xì)胞����、QGP1細(xì)胞、TE 85 ClF-5細(xì)胞
He La Cells;背景說明:HeLa是第一個來自人體組織經(jīng)連續(xù)培養(yǎng)獲得的非整倍體上皮樣細(xì)胞系����,它由GeyGO等在1951年從31歲女性黑人的宮頸癌組織建立。經(jīng)原始組織切片重新觀察�,Jones等將其診斷為腺癌。已知該細(xì)胞系含有人乳頭狀瘤病毒HPV18序列���,需在2級生物安全防護臺操作�。該細(xì)胞角蛋白陽性�,p53表達量較低,但表達正常水平的pRB(視網(wǎng)膜母細(xì)胞瘤抑制因子)�。;傳代方法:1:3傳代����,2-3天換液一次;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:C81-61細(xì)胞、EST50細(xì)胞�、M210B4細(xì)胞
GA-10 clone 4 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:每2-3天換液;生長特性:懸浮生長 ;形態(tài)特性:淋巴母細(xì)胞樣;相關(guān)產(chǎn)品有:P388.D1細(xì)胞、Hs 636 T細(xì)胞��、SNU-869細(xì)胞
Caki-1 Cells;背景說明:該細(xì)胞超微結(jié)構(gòu)中包含許多微絨毛���、少許微絲�、許多小線粒體、發(fā)達的高爾基休和內(nèi)質(zhì)網(wǎng)�、許多脂滴和多層體、次級溶酶體�,沒有發(fā)現(xiàn)病毒顆粒。;傳代方法:1:2-1:4傳代�����;每周換液2-3次�。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:NPA-87細(xì)胞、NCIH929細(xì)胞�����、GM-3573細(xì)胞
A375S2 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:H1341細(xì)胞���、PANC 1005細(xì)胞����、PNT1-a細(xì)胞
A375S2 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:H1341細(xì)胞���、PANC 1005細(xì)胞����、PNT1-a細(xì)胞
Reuber H-35 Cells;背景說明:在糖皮質(zhì)激素、胰島素或cAMP衍生物的誘導(dǎo)下可以產(chǎn)生酪酸基轉(zhuǎn)移酶�;可被逆轉(zhuǎn)錄病毒感染;可產(chǎn)生白蛋白���、轉(zhuǎn)鐵蛋白���、凝血酶原;在AxC大鼠中可以成瘤�����。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:STO細(xì)胞�����、Hs940-T細(xì)胞�、PL 5細(xì)胞
GM12601 Cells(提供STR鑒定圖譜)
HAP1 EPT1 (-) 1 Cells(提供STR鑒定圖譜)
H-1436 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:隨細(xì)胞的密度而增加;生長特性:懸浮生長;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:PNT1/A細(xì)胞���、SUM-52-PE細(xì)胞���、Hca-F細(xì)胞
TALL-104 Cells;背景說明:急性T淋巴細(xì)胞白血?�?;男性;傳代方法:1:2-1:3傳代�;每周換液2-3次。;生長特性:懸浮;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Mino細(xì)胞����、LTEP-sm 1細(xì)胞、HEK-293-EBNA細(xì)胞
Monomac-1 Cells;背景說明:急性單核細(xì)胞白血?���。荒行?傳代方法:1:2-1:3傳代���;每周換液2-3次�����。;生長特性:懸浮;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:H2228細(xì)胞�、Panc 10.05細(xì)胞�����、SUM190細(xì)胞
HT 1080.T Cells;背景說明:該細(xì)胞源自一名35歲患有纖維肉瘤的白人男性的結(jié)締組織;ras+����。;傳代方法:1:4-1:8傳代;2-3天換液1次���。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:SK-Hep1細(xì)胞���、HANK細(xì)胞、HFL細(xì)胞
HeLa/S3 Cells;背景說明:該細(xì)胞是1955年由PuckTT,MarcusPI和CieciuraSJ建系的���,含HPV-18序列�;角蛋白陽性�;可用于與染色體突變、細(xì)胞營養(yǎng)�、集落形成相關(guān)的哺乳動物細(xì)胞的克隆分析。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:Lilly Laboratories Cell-Porcine Kidney 1細(xì)胞��、NCTC1469細(xì)胞�����、GP-293細(xì)胞
JJN3 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代��;每周換液2-3次�。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:DrG細(xì)胞�����、SK-RC 39細(xì)胞�����、MiaPaca.2細(xì)胞
SKES-1 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:5傳代���;每周換液2-3次;生長特性:貼壁或懸浮�����,詳見產(chǎn)品說明書部分;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:EFM-192B細(xì)胞�����、WRL 68細(xì)胞�、KMB-17細(xì)胞
Wistar Institute-38 Cells;背景說明:LeonardHayflick建系�����;有限傳代細(xì)胞系;壽命為50±10代(倍增時間24h)��;來自妊娠3個月的正常胚胎肺組織��。該細(xì)胞系是第一個用于人制備的人二倍體細(xì)胞�����;培養(yǎng)基中添加TNFα可以加快細(xì)胞生長���。;傳代方法:1:2-1:4傳代���;2-3天換液1次;生長特性:貼壁生長;形態(tài)特性:成纖維細(xì)胞樣;相關(guān)產(chǎn)品有:PK(15)細(xì)胞、WM115細(xì)胞���、PC 61-5-3細(xì)胞
HiPS-RIKEN-2C Cells(提供STR鑒定圖譜)
iPS NIHi2 Cells(提供STR鑒定圖譜)
MB352 Cells(提供STR鑒定圖譜)
ND10565 Cells(提供STR鑒定圖譜)
PL14 [Human pancreatic adenocarcinoma] Cells(提供STR鑒定圖譜)
Ubigene HeLa TRAF5 KO Cells(提供STR鑒定圖譜)
XPH18PV Cells(提供STR鑒定圖譜)
HG02696 Cells(提供STR鑒定圖譜)
INS1 Cells;背景說明:該細(xì)胞源自X射線照射的移植胰島瘤的大鼠�����,胰島素陽性�,可合成胰島素原I和II�����,可用于beta細(xì)胞功能研究。;傳代方法:1:3—1:6傳代�����,每周換液2—3次;生長特性:貼壁生長;形態(tài)特性:不規(guī)則���,多角;相關(guān)產(chǎn)品有:OVCAR-8細(xì)胞、L5178Y TK+/- (clone 3.7.2C)細(xì)胞����、MRCV細(xì)胞
NEC Cells;背景說明:食管癌;傳代方法:1:2-1:3傳代;每周換液2-3次���。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:U14細(xì)胞��、H1355細(xì)胞��、Clone M-3細(xì)胞
WB-F344 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:NCI-H211細(xì)胞��、Kit225/K6細(xì)胞���、WM239A細(xì)胞
OVCA-432 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代;每周換液2-3次��。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:MRC-5細(xì)胞����、NCI-H209細(xì)胞、SCC90細(xì)胞
Panc10.05 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:MUGCHOR1細(xì)胞��、MLE-12細(xì)胞����、Japanese Tissue Culture-28細(xì)胞
NCIH524 Cells;背景說明:該細(xì)胞1982年建系,源自非小細(xì)胞肺癌男性患者的轉(zhuǎn)移淋巴結(jié)��。;傳代方法:1:2-1:3傳代���;每周換液2-3次��。;生長特性:懸浮生長;形態(tài)特性:圓形細(xì)胞;相關(guān)產(chǎn)品有:SDBMSC細(xì)胞��、MDA-415細(xì)胞��、Kit225細(xì)胞
Ca-Ski Cells;背景說明:這株細(xì)胞是從小腸腸系膜轉(zhuǎn)移灶的細(xì)胞中建立的����。 據(jù)報道�,它含有完整的HPV-16(每個細(xì)胞大約600個拷貝)和HPV-18相關(guān)序列����。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮細(xì)胞樣;相關(guān)產(chǎn)品有:LIM1215細(xì)胞��、KPNRTBM1細(xì)胞�����、L-1210細(xì)胞
Jiyoye Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:每周2-3次�。;生長特性:懸浮生長;形態(tài)特性:淋巴母細(xì)胞;相關(guān)產(chǎn)品有:ABC-1細(xì)胞�、LNCaP C4-2細(xì)胞、3AO細(xì)胞
COR-L279 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代���;每周換液2-3次���。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:NS1細(xì)胞��、Caov-4細(xì)胞���、HCC0015細(xì)胞
TE-15 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:消化3-5分鐘��。1:2�。3天內(nèi)可長滿。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:MV4:11細(xì)胞��、CHOS細(xì)胞�、NCI-H820細(xì)胞
NCI-H69C Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2—1:4傳代,每周換液2次;生長特性:懸浮生長���,聚團;形態(tài)特性:聚團懸浮;相關(guān)產(chǎn)品有:SK.MEL.28細(xì)胞���、KNS42細(xì)胞、HEK;293細(xì)胞
NCI-H810 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:6傳代,每周2-3次��。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:ACHN細(xì)胞�����、JB6 Cl 30-7b細(xì)胞�����、H2228細(xì)胞
GM2219C Cells;背景說明:MOLT-4與MOLT-3來源于一名19歲的男性急性淋巴細(xì)胞性白血病的復(fù)發(fā)患者����,該患者前期接受過多種藥物聯(lián)合化療。MOLT-4細(xì)胞系為T淋巴細(xì)胞起源,p53基因的第248位密碼子有一個G→A突變��,不表達p53�,不表達免疫球蛋白或EB病毒;可產(chǎn)生高水平的末端脫氧核糖轉(zhuǎn)移酶����;表達CD1(49%),CD2(35%),CD3A(26%)B(33%)C(34%),CD4(55%),CD5(72%),CD6(22%),CD7(77%)。;傳代方法:1:2傳代;生長特性:懸浮生長;形態(tài)特性:淋巴母細(xì)胞樣�����;圓形;相關(guān)產(chǎn)品有:AK細(xì)胞����、HEK 293-EBNA細(xì)胞��、Loucy細(xì)胞
CCD-841CoN Cells;背景說明:結(jié)腸上皮細(xì)胞�����;女性;傳代方法:1:2-1:3傳代��;每周換液2-3次��。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:HPF細(xì)胞��、Tsup-1細(xì)胞、hTERT-RPE細(xì)胞
HKBML Cells;背景說明:腦��;淋巴瘤�;男性;傳代方法:1:2-1:3傳代;每周換液2-3次�����。;生長特性:懸浮;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:HL-1細(xì)胞���、8226細(xì)胞��、SW 962細(xì)胞
SG5-1.13 Cells(提供STR鑒定圖譜)
PC9 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:CNE1細(xì)胞�、HME-1細(xì)胞����、SU-DHL-6細(xì)胞
ID8/MOSEC Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:QGP1細(xì)胞、NCIN87細(xì)胞�����、ADR-RES細(xì)胞
OVCAR 420 Cells;背景說明:卵巢癌�����;女性;傳代方法:1:2-1:3傳代;每周換液2-3次�。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:Panc 02.03細(xì)胞、GM01232細(xì)胞�、Hs675T細(xì)胞
NCIADRRES Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代;每周換液2-3次���。;生長特性:貼壁或懸浮�,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:RWPE-1細(xì)胞����、CEL細(xì)胞、Mesothelial cells transfected with pRSV-T 5A細(xì)胞
PA-1 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:4-1:10傳代�����;每周2-3次���。 ;生長特性:貼壁生長;形態(tài)特性:上皮細(xì)胞;相關(guān)產(chǎn)品有:Becker細(xì)胞�、NUGC-2細(xì)胞、NCIH1819細(xì)胞
Hep G2 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代���;每周換液2-3次�。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:SKLU1細(xì)胞��、NCI-H187細(xì)胞���、C8166-CD4細(xì)胞
HCC-9204 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代�����;每周換液2-3次����。;生長特性:貼壁或懸浮�,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:MNNGHOS細(xì)胞、Sp2/0-Ag-14細(xì)胞��、FTC-133細(xì)胞
MD Anderson-Metastatic Breast-435 Cells;背景說明:乳腺癌;傳代方法:1:2-1:3傳代���;每周換液2-3次�����。;生長特性:貼壁;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:LNCaP-FGC細(xì)胞���、HOC-1細(xì)胞��、CMT-64細(xì)胞
HT-29人結(jié)腸癌細(xì)胞全年復(fù)蘇|已有STR圖譜
Hs 895 T Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:4傳代��,2-3天換液1次����。;生長特性:貼壁生長;形態(tài)特性:成纖維細(xì)胞;相關(guān)產(chǎn)品有:CP-70細(xì)胞���、THP-1細(xì)胞�、MLTC-1細(xì)胞
Hs 281.T Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2傳代,每周換液2-3次��。;生長特性:貼壁生長;形態(tài)特性:成纖維細(xì)胞;相關(guān)產(chǎn)品有:COLO-320-DM細(xì)胞�����、PNT1-a細(xì)胞��、Roswell Park Memorial Institute 7951細(xì)胞
H-522 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:3-1:6傳代�����;每周換液2-3次����。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關(guān)產(chǎn)品有:HEK-293-F細(xì)胞、Hs 840.T細(xì)胞���、RWPE-1細(xì)胞
JHH-7 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代��;每周換液2-3次���。;生長特性:貼壁或懸浮,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:GM03671細(xì)胞�����、NCI-H1954細(xì)胞��、RMS1598細(xì)胞
H-735 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:2-1:3傳代�;每周換液2-3次。;生長特性:貼壁或懸浮����,詳見產(chǎn)品說明書部分;形態(tài)特性:詳見產(chǎn)品說明書;相關(guān)產(chǎn)品有:SKNBE(1)細(xì)胞、GM07404細(xì)胞�、HREC細(xì)胞
HCC-1954 Cells;背景說明:詳見相關(guān)文獻介紹;傳代方法:1:4-1:8傳代;每周換液2-3次�����。;生長特性:偶爾上皮細(xì)胞空泡;形態(tài)特性:上皮細(xì)胞樣;相關(guān)產(chǎn)品有:EM3細(xì)胞、HCC9724細(xì)胞�����、H-1568細(xì)胞
BayGenomics ES cell line DTM026 Cells(提供STR鑒定圖譜)
BayGenomics ES cell line TEA205 Cells(提供STR鑒定圖譜)
CCRC-M78 Cells(提供STR鑒定圖譜)
MA-Balb Cells(提供STR鑒定圖譜)
Royan B2 Cells(提供STR鑒定圖譜)
T3-2 [Rat tooth germ] Cells(提供STR鑒定圖譜)
" "PubMed=327080; DOI=10.1093/jnci/59.1.221
Fogh J., Fogh J.M., Orfeo T.
One hundred and twenty-seven cultured human tumor cell lines producing tumors in nude mice.
J. Natl. Cancer Inst. 59:221-226(1977)
PubMed=833871; DOI=10.1093/jnci/58.2.209
Fogh J., Wright W.C., Loveless J.D.
Absence of HeLa cell contamination in 169 cell lines derived from human tumors.
J. Natl. Cancer Inst. 58:209-214(1977)
PubMed=864752; DOI=10.1093/jnci/58.6.1743
Marshall C.J., Franks L.M., Carbonell A.W.
Markers of neoplastic transformation in epithelial cell lines derived from human carcinomas.
J. Natl. Cancer Inst. 58:1743-1751(1977)
PubMed=77569; DOI=10.1111/j.1399-0039.1978.tb01259.x
Espmark J.A., Ahlqvist-Roth L., Sarne L., Persson A.
Tissue typing of cells in culture. III. HLA antigens of established human cell lines. Attempts at typing by the mixed hemadsorption technique.
Tissue Antigens 11:279-286(1978)
PubMed=626984
Erickson L.C., Osieka R., Kohn K.W.
Differential repair of 1-(2-chloroethyl)-3-(4-methylcyclohexyl)-1- nitrosourea-induced DNA damage in two human colon tumor cell lines.
Cancer Res. 38:802-808(1978)
PubMed=468301; PMCID=PMC1457289
Trejdosiewicz L.K., Trejdosiewicz A.J., Ling N.R., Dykes P.W.
Growth enhancing property of human monocytes from normal donors and cancer patients.
Immunology 37:247-252(1979)
PubMed=6256643; DOI=10.1038/288724a0
Day R.S. 3rd, Ziolkowski C.H.J., Scudiero D.A., Meyer S.A., Lubiniecki A.S., Girardi A.J., Galloway S.M., Bynum G.D.
Defective repair of alkylated DNA by human tumour and SV40-transformed human cell strains.
Nature 288:724-727(1980)
PubMed=6445228
Kimball P.M., Brattain M.G.
Isolation of a cellular subpopulation from a human colonic carcinoma cell line.
Cancer Res. 40:1574-1579(1980)
PubMed=22282976; DOI=10.1093/carcin/1.1.21
Day R.S. 3rd, Ziolkowski C.H.J., Scudiero D.A., Meyer S.A., Mattern M.R.
Human tumor cell strains defective in the repair of alkylation damage.
Carcinogenesis 1:21-32(1980)
PubMed=7017212; DOI=10.1093/jnci/66.6.1003
Pollack M.S., Heagney S.D., Livingston P.O., Fogh J.
HLA-A, B, C and DR alloantigen expression on forty-six cultured human tumor cell lines.
J. Natl. Cancer Inst. 66:1003-1012(1981)
PubMed=7459858
Rousset M., Zweibaum A., Fogh J.
Presence of glycogen and growth-related variations in 58 cultured human tumor cell lines of various tissue origins.
Cancer Res. 41:1165-1170(1981)
PubMed=6220172
Dracopoli N.C., Fogh J.
Polymorphic enzyme analysis of cultured human tumor cell lines.
J. Natl. Cancer Inst. 70:469-476(1983)
PubMed=6825208; DOI=10.1093/carcin/4.2.199
Yarosh D.B., Foote R.S., Mitra S., Day R.S. 3rd
Repair of O6-methylguanine in DNA by demethylation is lacking in Mer- human tumor cell strains.
Carcinogenesis 4:199-205(1983)
PubMed=6500159; DOI=10.1159/000163283
Gershwin M.E., Lentz D., Owens R.B.
Relationship between karyotype of tissue culture lines and tumorigenicity in nude mice.
Exp. Cell Biol. 52:361-370(1984)
PubMed=6582512; DOI=10.1073/pnas.81.2.568; PMCID=PMC344720
Mattes M.J., Cordon-Cardo C., Lewis J.L. Jr., Old L.J., Lloyd K.O.
Cell surface antigens of human ovarian and endometrial carcinoma defined by mouse monoclonal antibodies.
Proc. Natl. Acad. Sci. U.S.A. 81:568-572(1984)
PubMed=3518877; DOI=10.3109/07357908609038260
Fogh J.
Human tumor lines for cancer research.
Cancer Invest. 4:157-184(1986)
PubMed=3472642; DOI=10.1016/0165-4608(87)90267-6
Chen T.-R., Drabkowski D.J., Hay R.J., Macy M.L., Peterson W.D. Jr.
WiDr is a derivative of another colon adenocarcinoma cell line, HT-29.
Cancer Genet. Cytogenet. 27:125-134(1987)
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=3349466
Chantret I., Barbat A., Dussaulx E., Brattain M.G., Zweibaum A.
Epithelial polarity, villin expression, and enterocytic differentiation of cultured human colon carcinoma cells: a survey of twenty cell lines.
Cancer Res. 48:1936-1942(1988)
PubMed=2288877
Hafez M.M., Infante D., Winawer S.J., Friedman E.
Transforming growth factor beta 1 acts as an autocrine-negative growth regulator in colon enterocytic differentiation but not in goblet cell maturation.
Cell Growth Differ. 1:617-626(1990)
PubMed=1778766; DOI=10.1111/j.1349-7006.1991.tb01816.x; PMCID=PMC5918361
Takeshima E., Hamaguchi M., Watanabe T., Akiyama S., Kataoka M., Ohnishi Y., Xiao H.-Y., Nagai Y., Takagi H.
Aberrant elevation of tyrosine-specific phosphorylation in human gastric cancer cells.
Jpn. J. Cancer Res. 82:1428-1435(1991)
PubMed=1937958; DOI=10.1002/ijc.2910490516
Lesuffleur T., Kornowski A., Luccioni C., Muleris M., Barbat A., Beaumatin J., Dussaulx E., Dutrillaux B., Zweibaum A.
Adaptation to 5-fluorouracil of the heterogeneous human colon tumor cell line HT-29 results in the selection of cells committed to differentiation.
Int. J. Cancer 49:721-730(1991)
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=1389533; DOI=10.1016/0959-8049(92)90031-V
Lahm H., Petral-Malec D., Yilmaz-Ceyhan A., Fischer J.R., Lorenzoni M., Givel J.-C., Odartchenko N.
Growth stimulation of a human colorectal carcinoma cell line by interleukin-1 and -6 and antagonistic effects of transforming growth factor beta 1.
Eur. J. Cancer 28A:1894-1899(1992)
PubMed=1730571; DOI=10.1007/BF02631079
Goodwin T.J., Jessup J.M., Wolf D.A.
Morphologic differentiation of colon carcinoma cell lines HT-29 and HT-29KM in rotating-wall vessels.
In Vitro Cell. Dev. Biol. Anim. 28:47-60(1992)
PubMed=8464898; DOI=10.1073/pnas.90.7.2842; PMCID=PMC46192
Browning M.J., Krausa P., Rowan A.J., Bicknell D.C., Bodmer J.G., Bodmer W.F.
Tissue typing the HLA-A locus from genomic DNA by sequence-specific PCR: comparison of HLA genotype and surface expression on colorectal tumor cell lines.
Proc. Natl. Acad. Sci. U.S.A. 90:2842-2845(1993)
PubMed=7972006; DOI=10.1073/pnas.91.23.11045; PMCID=PMC45163
Okamoto A., Demetrick D.J., Spillare E.A., Hagiwara K., Hussain S.P., Bennett W.P., Forrester K., Gerwin B.I., Serrano M., Beach D.H., Harris C.C.
Mutations and altered expression of p16INK4 in human cancer.
Proc. Natl. Acad. Sci. U.S.A. 91:11045-11049(1994)
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=8895552; DOI=10.1002/(SICI)1097-0215(19960927)68:1<126::aid-ijc22>3.0.CO;2-8
Suardet L., Li C., Little J.B.
Radio-induced modulation of transforming growth factor beta1 sensitivity in a p53 wild-type human colorectal-cancer cell line.
Int. J. Cancer 68:126-131(1996)
PubMed=9000147
Cottu P.-H., Muzeau F., Estreicher A., Flejou J.-F., Iggo R.D., Thomas G., Hamelin R.
Inverse correlation between RER+ status and p53 mutation in colorectal cancer cell lines.
Oncogene 13:2727-2730(1996)
PubMed=9000572
Hoang J.-M., Cottu P.-H., Thuille B., Salmon R.J., Thomas G., Hamelin R.
BAT-26, an indicator of the replication error phenotype in colorectal cancers and cell lines.
Cancer Res. 57:300-303(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=10612807; DOI=10.1002/(SICI)1098-2264(200002)27:2<183::aid-gcc10>3.0.CO;2-P; PMCID=PMC4721570
Ghadimi B.M., Sackett D.L., Difilippantonio M.J., Schrock E., Neumann T., Jauho A., Auer G., Ried T.
Centrosome amplification and instability occurs exclusively in aneuploid, but not in diploid colorectal cancer cell lines, and correlates with numerical chromosomal aberrations.
Genes Chromosomes Cancer 27:183-190(2000)
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=11226274; DOI=10.1073/pnas.041603298; PMCID=PMC30173
Abdel-Rahman W.M., Katsura K., Rens W., Gorman P.A., Sheer D., Bicknell D.C., Bodmer W.F., Arends M.J., Wyllie A.H., Edwards P.A.W.
Spectral karyotyping suggests additional subsets of colorectal cancers characterized by pattern of chromosome rearrangement.
Proc. Natl. Acad. Sci. U.S.A. 98:2538-2543(2001)
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=11416159; DOI=10.1073/pnas.121616198; PMCID=PMC35459
Masters J.R.W., Thomson J.A., Daly-Burns B., Reid Y.A., Dirks W.G., Packer P., Toji L.H., Ohno T., Tanabe H., Arlett C.F., Kelland L.R., Harrison M., Virmani A.K., Ward T.H., Ayres K.L., Debenham P.G.
Short tandem repeat profiling provides an international reference standard for human cell lines.
Proc. Natl. Acad. Sci. U.S.A. 98:8012-8017(2001)
PubMed=11526487; DOI=10.1038/sj.onc.1204611
Gayet J., Zhou X.-P., Duval A., Rolland S., Hoang J.-M., Cottu P.-H., Hamelin R.
Extensive characterization of genetic alterations in a series of human colorectal cancer cell lines.
Oncogene 20:5025-5032(2001)
PubMed=11668190; DOI=10.1177/002215540104901105
Quentmeier H., Osborn M., Reinhardt J., Zaborski M., Drexler H.G.
Immunocytochemical analysis of cell lines derived from solid tumors.
J. Histochem. Cytochem. 49:1369-1378(2001)
PubMed=11687795; DOI=10.1038/ng754
Snijders A.M., Nowak N.J., Segraves R., Blackwood S., Brown N., Conroy J., Hamilton G., Hindle A.K., Huey B., Kimura K., Law S., Myambo K., Palmer J., Ylstra B., Yue J.P., Gray J.W., Jain A.N., Pinkel D., Albertson D.G.
Assembly of microarrays for genome-wide measurement of DNA copy number.
Nat. Genet. 29:263-264(2001)
PubMed=11921276; DOI=10.1002/gcc.10003
Kawai K., Viars C., Arden K.C., Tarin D., Urquidi V., Goodison S.
Comprehensive karyotyping of the HT-29 colon adenocarcinoma cell line.
Genes Chromosomes Cancer 34:1-8(2002)
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=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=15900046; DOI=10.1093/jnci/dji133
Mashima T., Oh-hara T., Sato S., Mochizuki M., Sugimoto Y., Yamazaki K., Hamada J.-i., Tada M., Moriuchi T., Ishikawa Y., Kato Y., Tomoda H., Yamori T., Tsuruo T.
p53-defective tumors with a functional apoptosome-mediated pathway: a new therapeutic target.
J. Natl. Cancer Inst. 97:765-777(2005)
PubMed=16083285; DOI=10.1021/pr050048h
Kim J.-E., Tannenbaum S.R., White F.M.
Global phosphoproteome of HT-29 human colon adenocarcinoma cells.
J. Proteome Res. 4:1339-1346(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=18258742; DOI=10.1073/pnas.0712176105; PMCID=PMC2268141
Emaduddin M., Bicknell D.C., Bodmer W.F., Feller S.M.
Cell growth, global phosphotyrosine elevation, and c-Met phosphorylation through Src family kinases in colorectal cancer cells.
Proc. Natl. Acad. Sci. U.S.A. 105:2358-2362(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=19927377; DOI=10.1002/gcc.20730; PMCID=PMC2818350
Knutsen T., Padilla-Nash H.M., Wangsa D., Barenboim-Stapleton L., Camps J., McNeil N.E., Difilippantonio M.J., Ried T.
Definitive molecular cytogenetic characterization of 15 colorectal cancer cell lines.
Genes Chromosomes Cancer 49:204-223(2010)
PubMed=19941903; DOI=10.1016/j.jviromet.2009.11.022
Karger A., Bettin B., Lenk M., Mettenleiter T.C.
Rapid characterisation of cell cultures by matrix-assisted laser desorption/ionisation mass spectrometric typing.
J. Virol. Methods 164:116-121(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=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=20606684; DOI=10.1038/sj.bjc.6605780; PMCID=PMC2920028
Bracht K., Nicholls A.M., Liu Y., Bodmer W.F.
5-fluorouracil response in a large panel of colorectal cancer cell lines is associated with mismatch repair deficiency.
Br. J. Cancer 103:340-346(2010)
PubMed=20831567; DOI=10.1111/j.1582-4934.2010.01170.x; PMCID=PMC3918049
Ma Y.-L., Zhang P., Wang F., Moyer M.P., Yang J.-J., Liu Z.-H., Peng J.-Y., Chen H.-Q., Zhou Y.-K., Liu W.-J., Qin H.-L.
Human embryonic stem cells and metastatic colorectal cancer cells shared the common endogenous human microRNA-26b.
J. Cell. Mol. Med. 15:1941-1954(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=21912889; DOI=10.1007/s10637-011-9744-z
Sutherland H.S., Hwang I.Y., Marshall E.S., Lindsay B.S., Denny W.A., Gilchrist C., Joseph W.R., Greenhalgh D., Richardson E., Kestell P., Ding A., Baguley B.C.
Therapeutic reactivation of mutant p53 protein by quinazoline derivatives.
Invest. New Drugs 30:2035-2045(2012)
PubMed=22336246; DOI=10.1016/j.bmc.2012.01.017
Kong D.-X., Yamori T.
JFCR39, a panel of 39 human cancer cell lines, and its application in the discovery and development of anticancer drugs.
Bioorg. Med. Chem. 20:1947-1951(2012)
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=22940288; DOI=10.1016/j.jsbmb.2012.08.003; PMCID=PMC3695570
Hobaus J., Fetahu I.S., Khorchide M., Manhardt T., Kallay E.
Epigenetic regulation of the 1,25-dihydroxyvitamin D3 24-hydroxylase (CYP24A1) in colon cancer cells.
J. Steroid Biochem. Mol. Biol. 136:296-299(2013)
PubMed=23546019; DOI=10.3892/ijo.2013.1868
Petitprez A., Poindessous V., Ouaret D., Regairaz M., Bastian G., Guerin E., Escargueil A.E., Larsen A.K.
Acquired irinotecan resistance is accompanied by stable modifications of cell cycle dynamics independent of MSI status.
Int. J. Oncol. 42:1644-1653(2013)
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=23932154; DOI=10.1016/j.radonc.2013.06.032
Salendo J., Spitzner M., Kramer F., Zhang X., Jo P., Wolff H.A., Kitz J., Kaulfuss S., Beissbarth T., belstein M., Ghadimi M., Grade M., Gaedcke J.
Identification of a microRNA expression signature for chemoradiosensitivity of colorectal cancer cells, involving miRNAs-320a, -224, -132 and let7g.
Radiother. Oncol. 108:451-457(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=24042735; DOI=10.1038/oncsis.2013.35; PMCID=PMC3816225
Ahmed D., Eide P.W., Eilertsen I.A., Danielsen S.A., Eknaes M., Hektoen M., Lind G.E., Lothe R.A.
Epigenetic and genetic features of 24 colon cancer cell lines.
Oncogenesis 2:e71.1-e71.8(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=29787047; DOI=10.1007/978-3-319-16104-4_11
Martinez-Maqueda D., Miralles B., Recio I.
HT29 cell line.
(In book chapter) The impact of food bioactives on health. In vitro and ex vivo models; Verhoeckx K., Cotter P., Lopez-Exposito I., Kleiveland C., Lea T., Mackie A., Requena T., Swiatecka D., Wichers H. (eds.); pp.113-124; Springer; Cham; Switzerland (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=28179481; DOI=10.1158/1535-7163.MCT-16-0578
Tanaka N., Mashima T., Mizutani A., Sato A., Aoyama A., Gong B., Yoshida H., Muramatsu Y., Nakata K., Matsuura M., Katayama R., Nagayama S., Fujita N., Sugimoto Y., Seimiya H.
APC mutations as a potential biomarker for sensitivity to tankyrase inhibitors in colorectal cancer.
Mol. Cancer Ther. 16:752-762(2017)
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=29101300; DOI=10.15252/msb.20177701; PMCID=PMC5731344
Frejno M., Zenezini Chiozzi R., Wilhelm M., Koch H., Zheng R.-S., Klaeger S., Ruprecht B., Meng C., Kramer K., Jarzab A., Heinzlmeir S., Johnstone E., Domingo E., Kerr D.J., Jesinghaus M., Slotta-Huspenina J., Weichert W., Knapp S., Feller S.M., Kuster B.
Pharmacoproteomic characterisation of human colon and rectal cancer.
Mol. Syst. Biol. 13:951-951(2017)
PubMed=29207035; DOI=10.3892/ijo.2017.4206
Olejniczak A., Szarynska M., Kmiec Z.
In vitro characterization of spheres derived from colorectal cancer cell lines.
Int. J. Oncol. 52:599-612(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)
PubMed=31068700; DOI=10.1038/s41586-019-1186-3; PMCID=PMC6697103
Ghandi M., Huang F.W., Jane-Valbuena J., Kryukov G.V., Lo C.C., McDonald E.R. 3rd, Barretina J.G., Gelfand E.T., Bielski C.M., Li H.-X., Hu K., Andreev-Drakhlin A.Y., Kim J., Hess J.M., Haas B.J., Aguet F., Weir B.A., Rothberg M.V., Paolella B.R., Lawrence M.S., Akbani R., Lu Y.-L., Tiv H.L., Gokhale P.C., de Weck A., Mansour A.A., Oh C., Shih J., Hadi K., Rosen Y., Bistline J., Venkatesan K., Reddy A., Sonkin D., Liu M., Lehar J., Korn J.M., Porter D.A., Jones M.D., Golji J., Caponigro G., Taylor J.E., Dunning C.M., Creech A.L., Warren A.C., McFarland J.M., Zamanighomi M., Kauffmann A., Stransky N., Imielinski M., Maruvka Y.E., Cherniack A.D., Tsherniak A., Vazquez F., Jaffe J.D., Lane A.A., Weinstock D.M., Johannessen C.M., Morrissey M.P., Stegmeier F., Schlegel R., Hahn W.C., Getz G., Mills G.B., Boehm J.S., Golub T.R., Garraway L.A., Sellers W.R.
Next-generation characterization of the Cancer Cell Line Encyclopedia.
Nature 569:503-508(2019)
PubMed=31978347; DOI=10.1016/j.cell.2019.12.023; PMCID=PMC7339254
Nusinow D.P., Szpyt J., Ghandi M., Rose C.M., McDonald E.R. 3rd, Kalocsay M., Jane-Valbuena J., Gelfand E.T., Schweppe D.K., Jedrychowski M.P., Golji J., Porter D.A., Rejtar T., Wang Y.K., Kryukov G.V., Stegmeier F., Erickson B.K., Garraway L.A., Sellers W.R., Gygi S.P.
Quantitative proteomics of the Cancer Cell Line Encyclopedia.
Cell 180:387-402.e16(2020)
PubMed=32172478; DOI=10.1007/s12253-020-00805-3
Xu Y.-T., Zhang L., Wang Q.-L., Zheng M.-J.
Comparison of different colorectal cancer with liver metastases models using six colorectal cancer cell lines.
Pathol. Oncol. R"
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