"BT-549人乳腺管癌細胞代次低|培養(yǎng)基|送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
公司細胞系形態(tài)漂亮���、增殖倍數高、純度高�、功能性強,細胞培養(yǎng)就跟養(yǎng)孩子一個樣�。養(yǎng)孩子要喂奶,養(yǎng)細胞要加補液�����,都需要在前期補充足夠的營養(yǎng)��,初始狀態(tài)的細胞或剛剛復蘇的細胞還要適量加入血清或細胞因子來幫助它們的存活增殖,如果營養(yǎng)物質缺乏��,細胞就會不生長甚至死亡���。養(yǎng)孩子要從小培養(yǎng)學習���,養(yǎng)細胞也得培養(yǎng)寶寶順利生下來,你會經常撫摸他��,給他看各種顏色�����,刺激他的五感����。細胞也是一樣,分離后的細胞需要使用特定的細胞因子進行活化�����、增殖��。另外加入因子的種類���、因子的濃度、加入時間、加入順序都會影響細胞最終的結果�����。養(yǎng)孩子最怕孩子生病,養(yǎng)細胞最怕被污染�,平時你會仔細觀察寶寶是否嘔吐、是否突然哭鬧����,猜測寶寶是否生病了。對于細胞�����,我們也需要時刻進行觀察的��,假如培養(yǎng)液渾濁(污染了)���,則需要換液后加抗生素;假如細胞增殖不明顯���,形態(tài)變差���,則可能是因為營養(yǎng)不足了�����,對貼壁細胞可以消化后重新用新的培養(yǎng)基接種并加倍加入細胞因子含量�;對懸浮細胞增殖能力不強的��,則不著急補液���,只是先補加血清�����、細胞因子看是否可以好轉�。培養(yǎng)時還得全程在無菌的環(huán)境���,一個小小的偏差���,細胞就會死亡。
換液周期:每周2-3次
HCC2157 Cells;背景說明:詳見相關文獻介紹;傳代方法:每周換液2—3次;生長特性:懸浮生長;形態(tài)特性:上皮樣;相關產品有:IMR-32細胞����、Panc10.05細胞����、OV433細胞
H-211 Cells;背景說明:詳見相關文獻介紹;傳代方法:3-4天換液1次�。;生長特性:懸浮生長;形態(tài)特性:詳見產品說明書;相關產品有:SUM 190細胞、HT1197細胞��、CEM C7細胞
H1238 Cells;背景說明:詳見相關文獻介紹;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�����,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:Dysplastic Oral Keratinocyte細胞���、PC-3M-IE8細胞����、A549-Taxol細胞
BT-549人乳腺管癌細胞代次低|培養(yǎng)基|送STR圖譜
背景信息:該細胞1978年由W.G.Coutinho和E.Y.Lasfargues建系�,源自一位72歲患有乳腺導管癌的白人女性����,來源組織包括乳頭及浸潤導管�����。該細胞形態(tài)包括上皮樣細胞及多核巨細胞��,可分泌一種粘性物質��。
┈訂┈購(技術服務)┈熱┈線:1┈3┈6┈4┈1┈9┈3┈0┈7┈9┈1【微信同號】┈Q┈Q:3┈1┈8┈0┈8┈0┈7┈3┈2┈4����;
細胞培養(yǎng)應用于分子生物學���、細胞生物學�、遺傳學���、免疫學�、腫瘤學及病毒學等領域����,細胞培養(yǎng)是指將細胞從動物或植物體內取出,然后在適宜的人工環(huán)境中生長的過程���。細胞可以在培養(yǎng)前直接從組織中取出并通過酶或機械方法進行解離�,也可以來源于已建立的細胞系。傳代培養(yǎng)是指當細胞生長至高密度時��,將其分殖至新的培養(yǎng)瓶中���,以維持其生長和增殖�。貼壁細胞是指在培養(yǎng)基表面附著生長的細胞���,懸浮細胞是指在培養(yǎng)基中懸浮生長的細胞�,不依附于培養(yǎng)皿表面��。半貼壁半懸浮細胞同時具備貼壁細胞和懸浮細胞的特點��,通常在培養(yǎng)基中部分附著生長���,部分懸浮于培養(yǎng)基上��。
產品包裝:復蘇發(fā)貨:T25培養(yǎng)瓶(一瓶)或凍存發(fā)貨:1ml凍存管(兩支)
來源說明:細胞主要來源ATCC����、ECACC��、DSMZ�、RIKEN等細胞庫
BT-549人乳腺管癌細胞代次低|培養(yǎng)基|送STR圖譜
物種來源:人源、鼠源等其它物種來源
NCI-H847 Cells;背景說明:詳見相關文獻介紹;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����,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:Namalwa細胞、NCI-H-128細胞����、IPLB-SF 21AE細胞
MD Anderson-Metastatic Breast-468 Cells;背景說明:該細胞是1977年由CailleauR等從一位患有轉移性乳腺癌的51歲黑人女性的胸腔積液中分離得到的。雖然供體組織的G6PD等位基因雜合�����,但此細胞株始終表現(xiàn)為G6PDA表型��。P53基因273位密碼子存在G→A突變����,從而導致Arg→His替代。每個細胞上存在1×106個EGF受體���。;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:上皮樣;相關產品有:YH-13細胞、SLK細胞�����、NCIH1869細胞
MDA-MB 361 Cells;背景說明:該細胞源自40歲女性乳腺癌的腦轉移組織���。;傳代方法: 1:2—1:6傳代�����,每周換液2—3次;生長特性:松散貼壁生長;形態(tài)特性:上皮細胞樣;相關產品有:Roswell Park Memorial Institute 6666細胞�����、HUASMC細胞�、SF-126細胞
R3/1 Cells;背景說明:肺�;Ⅰ 型上皮 Cells;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:詳見產品說明書;相關產品有:JS1細胞����、NK-10A細胞�����、HSC2細胞
┈訂┈購(技術服務)┈熱┈線:1┈3┈6┈4┈1┈9┈3┈0┈7┈9┈1【微信同號】┈Q┈Q:3┈1┈8┈0┈8┈0┈7┈3┈2┈4;
形態(tài)特性:上皮細胞樣
貼壁細胞消化傳代時通常采用兩種方法:一���、加入胰酶等細胞脫落后�����,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�,而后者有可能對細胞施加胰酶選擇,因為總是貼壁不牢的細胞先脫落�����,對腫瘤細胞來說���,這部分細胞有可能是惡性程度較GAO的細胞亞群����。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(根據細胞消化的難易程度)��,棄之��,這樣依賴殘余的胰酶就可將細胞消化單細胞。對于較難消化的細胞����,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(預熱)總體積1/10v����。消化到有細胞脫落。不過有人說EDA對細胞不HAO�,有證據嗎?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并且不損失細胞�����!
CV-1 in Origin Simian-1 Cells;背景說明:該細胞源自CV-1細胞株���,經轉染編碼野生型T抗原�、起始點缺陷突變的SV40得到��;細胞中整合有SV40基因組完整早期區(qū)段的單個拷貝�。該細胞表達T抗原,適用于需要SV40T抗原表達的載體的轉染����;保留SV40溶細胞性生長的特性;支持40℃時溫度敏感性A209病毒的復制�;支持早期區(qū)段缺失的SV40純體的復制。因含有SV40的DNA序列�,該細胞需要在2級生物安全柜中操作。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:成纖維細胞樣;相關產品有:H-1993細胞、PG-4 (S+L-)細胞�����、TF-1a細胞
H446 Cells;背景說明:該細胞是1982年由CarneyD和GazdarAF等從一位小細胞肺癌患者的胸腔積液中建立的��。細胞的原始形態(tài)并不具有小細胞肺癌特征��。這個細胞株是小細胞肺癌的生化和形態(tài)學上的變種�,表達神經元特有的烯醇酶和腦型肌酸激酶同工酶;左旋多巴脫羧酶���、蠶素、抗利尿激素��、催產素或胃泌激素釋放肽未達到可檢測水平�。與正常細胞相比,該細胞c-mycDNA序列擴增約20倍����,RNA增加15倍。最初傳代培養(yǎng)基用含有5%FBS的RPMI1640���,另外添加10nM化可的松�、0.005mg/ml胰島素、0.01mg/ml轉鐵;傳代方法:1:2傳代;生長特性:貼壁/懸浮生長��,混合;形態(tài)特性:上皮樣;相關產品有:SUIT 2細胞��、OV-CA 432細胞�、SF 767細胞
SupB15WT Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代。3天內可長滿��。;生長特性:懸浮生長;形態(tài)特性:淋巴母細胞;相關產品有:H-1944細胞����、IGROV 1細胞、ME 180細胞
NTera-2D1 Cells;背景說明:詳見相關文獻介紹;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,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:HuH7細胞��、NALM-6-M1細胞�����、TKB1細胞
U-343 MG Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產品說明書;相關產品有:MGH-U3 (RN)細胞��、H735細胞、H1385細胞
PANC0203 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:SK-BR3細胞�����、SNU423細胞����、HeLa 229細胞
OSK-1 Cells;背景說明:誘導型多能干 Cells;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:詳見產品說明書;相關產品有:REC-1細胞、Pro-5 Lec1.3c細胞�����、A-549細胞
102PT Cells;背景說明:乳腺癌���;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:詳見產品說明書;相關產品有:KMH2細胞�����、COLO 16細胞、C2C12細胞
MHCC 97-L Cells;背景說明:來源于中山醫(yī)院�����,生長較緩慢;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:CT-26 WT細胞��、U-2OS細胞�����、Colon38細胞
Hs 870.T Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2—1:3傳代���;每周換液2-3次;生長特性:貼壁生長;形態(tài)特性:成纖維細胞;相關產品有:RPVSMC細胞����、MRC5細胞����、KYSE510細胞
C81-61 Cells;背景說明:皮膚黑色素瘤;腹壁轉移��;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:詳見產品說明書;相關產品有:JB 6細胞、Hs 445細胞�����、Panc8.13細胞
H-522 Cells;背景說明:詳見相關文獻介紹;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;相關產品有:HEK-293-F細胞��、HTR8/SVneo細胞�����、H-1703細胞
Sp2/O Cells;背景說明:該細胞是由綿羊紅細胞免疫的BALB/c小鼠脾細胞和P3X63Ag8骨髓瘤細胞融合得到的��。該細胞不分泌免疫球蛋白�,對20μg/ml的8-氮鳥嘌呤有抗性,對HAT比較敏感���;該細胞可以作為細胞融合時的B細胞組分用于制備雜交瘤;鼠痘病毒陰性�。;傳代方法:1:2傳代;生長特性:懸浮生長;形態(tài)特性:淋巴母細胞樣;圓形;相關產品有:X63-AG 8.653細胞���、OUMS-23細胞�、SCC4細胞
R1610 Cells;背景說明:詳見相關文獻介紹;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,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:H510細胞�、Murine Thymic Epithelial Cell line 1細胞、HUT 28細胞
hMSC-BM Cells;背景說明:詳見相關文獻介紹;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�����,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:YT細胞��、FAO-1細胞�����、NCIH1755細胞
REC-1 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:3—1:6傳代����,2-3天換液1次;生長特性:懸浮生長 ;形態(tài)特性:淋巴母細胞樣;相關產品有:NCI-H-82細胞�、MDA-MB 361細胞���、SY5Y細胞
DHL-8 Cells;背景說明:彌漫大B淋巴瘤�;腹腔積液轉移�;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:詳見產品說明書;相關產品有:NS-1細胞��、CAL-51細胞���、PTK 2細胞
30A-5 Cells(提供STR鑒定圖譜)
Abcam HeLa STX17 KO Cells(提供STR鑒定圖譜)
AH129-NC1 Cells(提供STR鑒定圖譜)
BayGenomics ES cell line RRJ023 Cells(提供STR鑒定圖譜)
BayGenomics ES cell line XJ144 Cells(提供STR鑒定圖譜)
C2191 Cells(提供STR鑒定圖譜)
DA00191 Cells(提供STR鑒定圖譜)
DA05609 Cells(提供STR鑒定圖譜)
GILM1 Cells(提供STR鑒定圖譜)
UCLA SO M14 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:3傳代;生長特性:混合生長;形態(tài)特性:詳見產品說明書;相關產品有:H-220細胞、CEF細胞���、C2BBe 1細胞
BT-549人乳腺管癌細胞代次低|培養(yǎng)基|送STR圖譜
VSC4.1 Cells;背景說明:神經元瘤;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:詳見產品說明書;相關產品有:UCH-1細胞����、KE-37細胞、118 MG細胞
BC-3H-1 Cells;背景說明:詳見相關文獻介紹;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���,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:H766T細胞����、BALB/3T3 (clone A31)細胞�、MCA 205細胞
SKNSH Cells;背景說明:SK-N-SH細胞系由J.L.Bieder建系,它與SK-N-MC所不同的是倍增時間較長且多巴胺-β-羥基酶水平較高���。 SK-N-SH在細胞介導的細胞毒性試驗中用作靶細胞系����。;傳代方法:1:2傳代;生長特性:懸浮生長;形態(tài)特性:上皮細胞樣;相關產品有:OVCAR 432細胞�����、Pfeiffer細胞�、AR41P細胞
U-343 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產品說明書;相關產品有:P3HR1-BL細胞、HCCC9810細胞、786-0細胞
AU-565 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:4—1:6傳代�;每3-5天換一次液。;生長特性:貼壁生長;形態(tài)特性:上皮細胞;相關產品有:LCLC-103H細胞�����、Clone 166細胞���、Panc04.03細胞
20-4-4 Cells(提供STR鑒定圖譜)
AD293 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:詳見產品說明書;相關產品有:T-T細胞���、MV4:11細胞、ID8/MOSEC細胞
SCC4 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:COLO 201細胞����、SMA 560細胞、Pt K2細胞
Hs 695.T Cells;背景說明:詳見相關文獻介紹;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:上皮細胞;相關產品有:HSC6細胞、IBRS-2細胞�、CHL-11細胞
NHRF Cells;背景說明:腎;成纖維 Cells;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:詳見產品說明書;相關產品有:D-341 Med細胞、MB 157細胞�、IOSE 29細胞
SNU407 Cells;背景說明:詳見相關文獻介紹;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��,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:NCI-BL6細胞�����、SNU251細胞���、OVCAR.4細胞
GDM-1 Cells;背景說明:詳見相關文獻介紹;傳代方法:2-3天換液1次��。;生長特性:懸浮生長;形態(tài)特性:淋巴母細胞樣 ;相關產品有:MCF7-GFP細胞�����、B16 melanoma F10細胞�、UWB1289細胞
MCM Cells;背景說明:心肌;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:詳見產品說明書;相關產品有:P-36細胞��、C3H 10T1/2細胞�、MFE280細胞
PaCa2 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;;生長特性:貼壁生長;形態(tài)特性:詳見產品說明書;相關產品有:NTera-2D1細胞���、118MG細胞��、OCILY19細胞
GM13413 Cells(提供STR鑒定圖譜)
HAP1 FLOT1 (-) 1 Cells(提供STR鑒定圖譜)
SGC7901 Cells;背景說明:1979年建系���;這株細胞源自一位56歲女性胃腺癌患者的淋巴結轉移灶。RPMI-1640培養(yǎng)12天���,細胞開始生長�,首次傳代10天���;31個月中傳代186代����。免疫抑制的ICR小鼠�、乳犬皮下移植成功,家兔���、乳犬眼前房移植成功���;淋巴結轉移�,從小鼠皮下侵襲至肌層����。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:Daoy細胞、Tokyo Medical and Dental university 8細胞���、MDA-415細胞
H-196 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:4-1:6傳代;每周換液2-3次�����。;生長特性:貼壁生長;形態(tài)特性:詳見產品說明書;相關產品有:HCC941122細胞����、NCIH510細胞、X63Ag8-653細胞
Fao Cells;背景說明:詳見相關文獻介紹;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��,詳見產品說明書部分;形態(tài)特性:上皮細胞;相關產品有:RPMI #8226細胞、Keio University-19-19細胞�����、BEL 7402細胞
HCC-1599 Cells;背景說明:詳見相關文獻介紹;傳代方法:每3-4天換液;生長特性:懸浮生長;形態(tài)特性:上皮樣;相關產品有:B/C3T3細胞���、HBEpiC細胞���、Human ErythroLeukemia細胞
Functional Liver Cell-7 Cells;背景說明:詳見相關文獻介紹;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��,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:OK-WT細胞����、BC-3H-1細胞、CAMA1細胞
WIL2-S Cells;背景說明:詳見相關文獻介紹;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,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:COLO 824細胞�、TH1細胞、HRPEpiC細胞
Porcine Kidney-13 Cells;背景說明:詳見相關文獻介紹;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:上皮細胞樣;相關產品有:H-1048細胞�、P3HRI細胞��、HPAF II細胞
GM02131 Cells;背景說明:B淋巴細胞�;EBV轉化;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:詳見產品說明書;相關產品有:NCTC-3960細胞、Rat Fetal Lung-6細胞���、LICR-HN6細胞
HM [Human gestational choriocarcinoma] Cells(提供STR鑒定圖譜)
IRR-3T3 Cells(提供STR鑒定圖譜)
MCF-7-luc-F5 Cells(提供STR鑒定圖譜)
ND12921 Cells(提供STR鑒定圖譜)
PPAP-10 Cells(提供STR鑒定圖譜)
Ubigene HeLa TNFRSF1A KO Cells(提供STR鑒定圖譜)
XPH11PV Cells(提供STR鑒定圖譜)
HAP1 TMEM30A (-) 2 Cells(提供STR鑒定圖譜)
NCIH1341 Cells;背景說明:詳見相關文獻介紹;傳代方法:3-4天換液1次�。;生長特性:懸浮生長;形態(tài)特性:圓形細胞;相關產品有:L5178-R細胞�、WRL68細胞、HCC-827細胞
MB49 Cells;背景說明:膀胱癌�;雄性����;C57BL/Icrfa(t);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:詳見產品說明書;相關產品有:HOC細胞、SF-763細胞�、Mhh-Call 2細胞
87 MG Cells;背景說明:詳見相關文獻介紹;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����,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:Hs888 Lu細胞、KU.812細胞����、HSC-T6細胞
H-596 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:4-1:8傳代;每周換液2-3次��。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:H-661細胞�、CAL62細胞、Tb1Lu細胞
OAW42 Cells;背景說明:詳見相關文獻介紹;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�,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:EAC細胞、M210B4細胞�����、MDA-MB-175-VII細胞
OAW42 Cells;背景說明:詳見相關文獻介紹;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�����,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:EAC細胞���、M210B4細胞����、MDA-MB-175-VII細胞
HSAS3 Cells;背景說明:皮膚�;成纖維 Cells;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:詳見產品說明書;相關產品有:PE/CA-PJ-34細胞��、Buffalo Rat Liver-3A細胞、HUTU80細胞
HEK-AD293 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:詳見產品說明書;相關產品有:KASUMI1細胞�、ROS1728細胞、LA-N-5細胞
SUIT 2 Cells;背景說明:胰腺管癌����;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:詳見產品說明書;相關產品有:K562/ADR細胞����、P-3J細胞、SUDHL5細胞
KNS62 Cells;背景說明:詳見相關文獻介紹;傳代方法:每周換液2次����。;生長特性:貼壁生長;形態(tài)特性:上皮細胞;相關產品有:LLC-MK-2細胞、AML12細胞����、SKNEP-1細胞
OCI AML5 Cells;背景說明:急性髓系白血病細胞;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:詳見產品說明書;相關產品有:H-1693細胞��、Hs-688A-T細胞��、X63Ag8.653細胞
OCIAML2 Cells;背景說明:急性髓系白血?。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:詳見產品說明書;相關產品有:DF1細胞����、Hk-2細胞、GM00637I細胞
PanC1 Cells;背景說明:這株人胰腺癌細胞株源自于胰腺癌導管細胞�,其倍增時間為52小時。染色體研究表明�,該細胞染色體眾數為63,包括3個獨特標記的染色體和1個小環(huán)狀染色體���。該細胞的生長可被1unit/ml的左旋天冬酰胺酶抑制��;能在軟瓊脂上生長�����;能在裸鼠上成瘤。;傳代方法:1:2-1:4傳代���;每周2-3次��。;生長特性:貼壁生長;形態(tài)特性:上皮樣��;多角形;相關產品有:TB1 Lu細胞�、OLN-93細胞、M-20細胞
T24 Cells;背景說明:該細胞源自一位81歲白人女性患者的膀胱移行細胞癌組織��;來源于移行細胞癌病人的白血病和血漿對T24和相關細胞株有細胞毒性��;倍增時間為19小時�;含ras(H-ras)癌基因,表達腫瘤特有抗原。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:KCL22S細胞��、GA-10細胞��、UCLA-RO 81細胞
C-28/I2 Cells;背景說明:軟骨�;SV40轉化;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:詳見產品說明書;相關產品有:C-32細胞����、L-5178-Y-R細胞�����、BNCL-2細胞
Si-TGCT-2 Cells(提供STR鑒定圖譜)
SUM 52 Cells;背景說明:乳腺癌���;胸腔積液轉移;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:詳見產品說明書;相關產品有:MDA415細胞����、SU86-86細胞、SKRC-20細胞
P3HRI Cells;背景說明:詳見相關文獻介紹;傳代方法:每2-3天換液;生長特性:懸浮生長 ;形態(tài)特性:淋巴母細胞樣;相關產品有:SCL I細胞��、CCF-STTG1細胞�����、MDST8細胞
P30/Ohkubo Cells;背景說明:詳見相關文獻介紹;傳代方法:10^5 cells/60mm dish;生長特性:懸浮生長;形態(tài)特性:淋巴母細胞;相關產品有:OVCAR 433細胞��、SUM 149細胞�����、CEM T4細胞
HOP-62 Cells;背景說明:肺癌;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:詳見產品說明書;相關產品有:LK2細胞����、HUTU80細胞、T24細胞
GBCSD Cells;背景說明:GBC-SD 細胞株是王展明等2000年從一位61歲的男性低分化膽囊癌患者中建立的�。 細胞的形狀有多邊形、紡錘形和正方形�。 分泌CEA和CA19-9。倍增時間大約為21.4小時�。 可移植到裸鼠。 生成的腫瘤與原發(fā)腫瘤相似���。;傳代方法:1:2傳代;生長特性:貼壁生長;形態(tài)特性:上皮細胞樣;相關產品有:Vx2細胞��、IGROV細胞���、Hs 274.T細胞
TE11 Cells;背景說明:詳見相關文獻介紹;傳代方法:消化3-5分鐘。1:2�。3天內可長滿。;生長特性:貼壁生長;形態(tài)特性:上皮樣;相關產品有:Lung cancer-1/squamous細胞���、OUMS-27細胞����、U2OS細胞
BT-549人乳腺管癌細胞代次低|培養(yǎng)基|送STR圖譜
T47D Cells;背景說明:浸潤性導管癌;胸腔積液轉移���;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:詳見產品說明書;相關產品有:AR-42J細胞����、Hs895T細胞、Hs888T細胞
SN12C Cells;背景說明:詳見相關文獻介紹;傳代方法:2x10^4 cells/ml;生長特性:貼壁生長;形態(tài)特性:上皮細胞樣;相關產品有:H727細胞�、D283-MED細胞、TJ905細胞
293c18 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:4-1:10傳代��;每周2次�。;生長特性:貼壁生長;形態(tài)特性:上皮細胞樣;相關產品有:NCIH23細胞、UO31細胞�、BC-023細胞
P30/0HK Cells;背景說明:詳見相關文獻介紹;傳代方法:10^5 cells/60mm dish;生長特性:懸浮生長;形態(tài)特性:淋巴母細胞;相關產品有:UMUC3細胞、RT112細胞���、WRL 68細胞
Hs68 Cells;背景說明:該細胞1969年由Owens RB建立��。;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產品說明書;相關產品有:DMS 114細胞���、Epstein-Barr-3細胞�����、QGY-7701細胞
SCC-25 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:3-1:10傳代,2-3天換液1次�����。;生長特性:貼壁生長;形態(tài)特性:上皮細胞;相關產品有:ZR75-1細胞��、HCT 8細胞�����、H838細胞
McA-RH 8994 Cells;背景說明:詳見相關文獻介紹;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��,詳見產品說明書部分;形態(tài)特性:詳見產品說明書;相關產品有:GC1-SPG細胞�、PL5細胞�、OVCAR.5細胞
Panc-02 Cells;背景說明:詳見相關文獻介紹;傳代方法:1:2傳代;生長特性:貼壁生長 ;形態(tài)特性:詳見產品說明書;相關產品有:A10細胞����、NCI747細胞、MA-104細胞
BayGenomics ES cell line CSH440 Cells(提供STR鑒定圖譜)
BayGenomics ES cell line RRY376 Cells(提供STR鑒定圖譜)
BF10 Cells(提供STR鑒定圖譜)
KOP Cells(提供STR鑒定圖譜)
PD-L1.1 Cells(提供STR鑒定圖譜)
PC12 HTT-SW2-Q73 clone 29 Cells(提供STR鑒定圖譜)
" "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=21552935; DOI=10.3892/ijo.7.5.1079
Nangia-Makker P., Thompson E., Hogan C., Ochieng J., Raz A.
Induction of tumorigenicity by galectin-3 in a nontumorigenic human breast-carcinoma cell-line.
Int. J. Oncol. 7:1079-1087(1995)
PubMed=9561029
Warfield P.R., Nangia-Makker P., Raz A., Ochieng J.
Adhesion of human breast carcinoma to extracellular matrix proteins is modulated by galectin-3.
Invasion Metastasis 17:101-112(1997)
PubMed=9671407; DOI=10.1038/sj.onc.1201814
Sweeney K.J., Swarbrick A., Sutherland R.L., Musgrove E.A.
Lack of relationship between CDK activity and G1 cyclin expression in breast cancer cells.
Oncogene 16:2865-2878(1998)
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=10862037; DOI=10.1002/1098-2264(200007)28:3<308::AID-GCC9>3.0.CO;2-B
Kytola S., Rummukainen J., Nordgren A., Karhu R., Farnebo F., Isola J.J., Larsson C.
Chromosomal alterations in 15 breast cancer cell lines by comparative genomic hybridization and spectral karyotyping.
Genes Chromosomes Cancer 28:308-317(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=11343771; DOI=10.1016/S0165-4608(00)00387-3
Rummukainen J., Kytola S., Karhu R., Farnebo F., Larsson C., Isola J.J.
Aberrations of chromosome 8 in 16 breast cancer cell lines by comparative genomic hybridization, fluorescence in situ hybridization, and spectral karyotyping.
Cancer Genet. Cytogenet. 126:1-7(2001)
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=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=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=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=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)
PubMed=19727395; DOI=10.1371/journal.pone.0006888; PMCID=PMC2731225
Wadlow R.C., Wittner B.S., Finley S.A., Bergquist H., Upadhyay R., Finn S.P., Loda M., Mahmood U., Ramaswamy S.
Systems-level modeling of cancer-fibroblast interaction.
PLoS ONE 4:E6888-E6888(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=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=20679594; DOI=10.1093/jnci/djq279; PMCID=PMC2935474
Gazdar A.F., Girard L., Lockwood W.W., Lam W.L., Minna J.D.
Lung cancer cell lines as tools for biomedical discovery and research.
J. Natl. Cancer Inst. 102:1310-1321(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)
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=23637631; DOI=10.1371/journal.pgen.1003464; PMCID=PMC3636093
Giacomini C.P., Sun S., Varma S., Shain A.H., Giacomini M.M., Balagtas J.M.S., Sweeney R.T., Lai E., Del Vecchio C.A., Forster A.D., Clarke N., Montgomery K.D., Zhu S., Wong A.J., van de Rijn M., West R.B., Pollack J.R.
Breakpoint analysis of transcriptional and genomic profiles uncovers novel gene fusions spanning multiple human cancer types.
PLoS Genet. 9:E1003464-E1003464(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=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=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=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=30613774; DOI=10.1126/sciadv.aau7314; PMCID=PMC6314821
Vande Voorde J., Ackermann T., Pfetzer N., Sumpton D., Mackay G., Kalna G., Nixon C., Blyth K., Gottlieb E., Tardito S.
Improving the metabolic fidelity of cancer models with a physiological cell culture medium.
Sci. Adv. 5:eaau7314.1-eaau7314.14(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)"
關鍵字: BT-549人乳腺管癌細胞代次低|培養(yǎng)基;復蘇細胞系;細胞STR鑒定報告;細胞STR鑒定圖譜;ATCC|DSMZ細胞庫;
公司提供ATCC����、DSMZ、ECACC���、NCI-DTP�����、RCB(Riken)等細胞系