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- 详细信息
- 文献和实验
- 技术资料
- 品系:
详见细胞说明资料
- 细胞类型:
详见细胞说明资料
- 肿瘤类型:
详见细胞说明资料
- 供应商:
上海冠导生物工程有限公司
- 库存:
≥100瓶
- 生长状态:
详见细胞说明资料
- 年限:
详见细胞说明资料
- 运输方式:
常温运输【复苏细胞】或干冰运输【冻存细胞】
- 器官来源:
详见细胞说明资料
- 是否是肿瘤细胞:
详见细胞说明资料
- 细胞形态:
详见细胞说明资料
- 免疫类型:
详见细胞说明资料
- 物种来源:
详见细胞说明资料
- 相关疾病:
详见细胞说明资料
- 组织来源:
详见细胞说明资料
- 英文名:
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
- 规格:
1*10(6)Cellls/瓶
"NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
传代方法:1:2-1:4(首次传代建议1:2)
生长特性:悬浮生长
换液频率:每周2-3次
背景资料:最初是从一名患有Burkitt's淋巴瘤的患者的肿瘤组织中分离出来的。是一种高度恶性的B细胞淋巴瘤,常见于儿童和年轻人。有EB病毒基因组。
9L Cells;背景说明:胶质瘤;Fischer 344;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:ZYM-DIEC02 Cells、Homo sapiens No. 578, tumor cells Cells、HCC1008 Cells
343 MG Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长 ;形态特性:详见产品说明;相关产品有:SUD6 Cells、alpha-TC1.6 Cells、H-747 Cells
K422 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:N2a Cells、DHL-8 Cells、Chang Cells Cells
【细胞培养中细菌、霉菌的污染情况总结】细菌:细菌在普通倒置显微镜下为黑色细沙状,根据感染细菌的不同,可有不同的外形,培养一般会浑浊变黄,对细胞生长影响明显。仔细检查一下器皿的灭菌情况,是否在GAO压灭菌时放气时间足够,压力足够!尤其是和储存培养接触的移管等物品,连续两次污染的话有可能造成储存污染,一定要注意!下次使用前检查一下培养是否存在浑浊的现象!可在培养中加相应的抗生素处理;霉菌:培养是清亮的,倒置显微镜下无杂质,37度孵箱培养2-3天,仍清亮,但出现絮状杂质,镜下可见呈细丝状的团状漂浮物,可看到明显的菌丝,细胞仍可生长,但时间长之后,细胞的活力状态变差,用铜溶擦拭CO2孵箱内,再把水盘里也加上饱和量的铜。或者在培养箱的托盘加入饱和的消毒二钠GAO盐体,可以防止霉菌污染。CO2孵箱被霉菌污染后,可把所有细胞暂时转移,采用擦洗孵箱(包括隔板,箱壁)。并把放置在孵箱内一个小时,使其蒸汽弥漫。待的气味消散后,再移入细胞。孵箱应定期清洁(2月左右),尤其在多雨的季节。其它培养箱清洗方法是:用84擦洗-清水擦洗-75%酒精擦洗-紫外灯照。预防霉菌污染,可在培养基里加3u/ml的两性霉素或制霉菌素或D或双抗;但细胞一旦污染,很难挽救,制霉菌素或D或双抗都于事无补,建议舍弃该污染细胞,将环境彻底消毒,如果所有细胞都污染,可能是系统污染,检查一下培养基和器材,如果只是个别污染,可能是操作问题,就要注意操作。
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
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产品包装形式:复苏细胞:T25培养瓶(一瓶)或冻存细胞:1ml冻存管(两支)
来源说明:细胞主要来源ATCC、DSMZ等细胞库
物种来源:Human\Mouse\Rat\Others
H1623 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;相关产品有:OCILY7 Cells、HO-8910PM Cells、mouse Inner Medullary Collecting Duct-3 Cells
L-WRN Cells;背景说明:皮下结缔组织;自发永生;雄性;C3H/An;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:LC-1 Cells、NCIH1836 Cells、CW-2 Cells
C 643 Cells;背景说明:甲状腺未分化癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:NPC-TW 01 Cells、HTh74 Cells、MDA-453 Cells
OVCAR5 Cells;背景说明:卵巢癌;腹水转移;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;相关产品有:SK-NSH Cells、C3H10T1/2 clone8 Cells、H524 Cells
如何进行细胞复苏:1)从容器中取出冻存管,直接浸入37℃温水中,并不时摇动令其尽快融化;2)从37℃水浴中取出冻存管,打开盖子,用吸管吸出细胞悬,加到离心管并滴加10倍以上培养,混匀;3)离心,1000rpm,5min;4)弃去上清,加入含10%小牛血清培养重悬细胞,计数,调整细胞密度,接种培养瓶,37℃培养箱静置培养;5)次日更换一次培养,继续培养。【温馨提醒】1)从增殖期到形成致密的单层细胞以前的培养细胞都可以用于冻存,但ZuiHAO为对数生长期细胞。在冻存前一天ZuiHAO换一次培养;2)将冻存管放入容器或从中取出时,要做HAO防护工作(戴棉手套),以免冻伤;3)冻存和复苏ZuiHAO用新配制的培养。细胞复苏的时候,有些初次实验员将冻存管从中取出后,放在室温下,经常发生冻存管爆炸,该怎么避免出现这种情况吗?其中在拧紧冻存管的时候是否有哪些细节要注意的?一般常用的方法是取出冻存管后在超净工作台中用酒精棉球擦试管口,再稍拧松盖子,再放37度水浴锅中摇溶,在将细胞转移到装有37度预热过的培养基的试管中,迅速离心,再用培养基洗一遍。
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NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
形态特性:淋巴母细胞样
在细胞传代过程中,离心操作后的上清液处理是一个关键步骤,而关于是用移液枪吸走还是直接倒掉上清液,需要综合多方面因素来考量。使用移液枪吸走上清液具有一定的优势。移液枪能够较为精准地控制吸取的量和速度,可以地减少对细胞沉淀的扰动。可以根据实际情况尽可能地吸净上清液,减少残留血清或培养基成分对后续细胞培养的潜在影响,比如残留的血清可能会改变新培养基的营养成分比例或带来一些未知的生长因子干扰。然而,直接倒掉上清液也并非不可行。在处理一些细胞数量较多、细胞耐受性较好且对实验精度要求并非极高的细胞传代时,直接倒掉上清液能够提高操作效率,节省时间。但这种方式存在一定风险,直接倾倒时较难控制力度和角度,如果操作不慎,容易使细胞沉淀随着上清液一起流出,导致细胞损失,而且可能会因液体快速流下冲击细胞沉淀造成细胞的物理性损伤。在实际的细胞传代操作中,应根据细胞的特性、实验的要求以及个人的操作熟练程度来选择合适的上清液处理方式。对于新手或者处理珍贵细胞系时,建议优先采用移液枪吸走的方式,以保障细胞的活性和传代的成功率。而在积累了丰富经验且对实验条件有充分把握的情况下,可以根据具体情况灵活运用直接倒掉上清液的方法,在保证实验质量的同时提高工作效率。
OVTOKO Cells;背景说明:卵巢透明细胞癌;脾转移;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;相关产品有:RL-65 Cells、Tn 5B1-4 Cells、ketr 3 Cells
WM115mel Cells;背景说明:黑色素瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Panc203 Cells、HTori-3.1 Cells、UCLA RO-81A-1 Cells
SU-DHL-8 Cells;背景说明:弥漫大B淋巴瘤;腹腔积液转移;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:CII Cells、HMrSV5 Cells、MCA38 Cells
Panc 04.03 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:Mono-Mac-1 Cells、T2(174 x CEM.T2) Cells、L428 Cells
KU 19-19 Cells;背景说明:膀胱癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Bovine Turbinate Cells、NCIH2141 Cells、Caco-2BBe Cells
HH [Human lymphoma] 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:NCIH1184 Cells、H-1882 Cells、C2A Cells
Oka-C1 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:H-719 Cells、NCI-H322 Cells、HHFK Cells
JB-6 Cl 30 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:U-343 MG Cells、EC-109 Cells、V79 Cells
Hs 766 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:8传代,每周换液2—3次;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:SUM52PE Cells、A172 Cells、HF-91 Cells
Abcam HCT 116 NF1 KO Cells(拥有STR基因鉴定图谱)
AG07882 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line DTM007 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line TEA178 Cells(拥有STR基因鉴定图谱)
BL8 TB1 Cells(拥有STR基因鉴定图谱)
┈订┈购┈热┈线:1┈5┈8┈0┈0┈5┈7┈6┈8┈6┈7【微信同号】┈Q┈Q:3┈3┈0┈7┈2┈0┈4┈2┈7┈1;
CLS-79 Cells(拥有STR基因鉴定图谱)
DA03495 Cells(拥有STR基因鉴定图谱)
EtOH-1 Cells(拥有STR基因鉴定图谱)
GM07278 Cells(拥有STR基因鉴定图谱)
TE-15 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:上皮样;相关产品有:MV4:11 Cells、CHOS Cells、NCI-H820 Cells
NCIH1651 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:8传代,每周换液2次;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:KG-1 Cells、HuT 78 Cells、NCIH1792 Cells
SNT-8 Cells;背景说明:NK/T细胞淋巴瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:Vero E-6 Cells、HPAEC Cells、HET-1A Cells
Mouse podocyte Cells;背景说明:肾;足 Cells;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:PANC 813 Cells、MEC-1 Cells、L5178Y-R Cells
HCEpiC Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C2BBe1 Cells、Meat Animal Research Center-145 Cells、RFL-6 Cells
SCL-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;形态特性:上皮细胞样;相关产品有:MDA-MB-175-VII Cells、SO-RB50 Cells、NCI-H1581 Cells
RH8994 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SVGp12 Cells、Opossum Kidney Cells、NCI-H3255 Cells
HPDE Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长 ;形态特性:详见产品说明;相关产品有:PC2 Cells、CTSC-3 Cells、P3X63 AG 8.653 Cells
RIN-14B Cells;背景说明:胰岛素瘤;雄性;NEDH;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Uhth-74 Cells、TE11 Cells、TE10 Cells
C4-1 Cells;背景说明:宫颈鳞癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:IOSE80UBC Cells、HeLa S 3 Cells、COR-L88 Cells
SKMES-1 Cells;背景说明:源于一位65岁患有肺鳞状细胞癌的白人男性,自转移性胸腔积液分离而来。;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:PCI-04B Cells、MDBK Cells、GES1 Cells
SHI1 Cells;背景说明:急性单核细胞白血病;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:RAG Cells、U266 Bl Cells、LIM1215 Cells
C2-C12 Cells;背景说明:该细胞株是YaffeD,SaxelO建立的小鼠成肌细胞系的亚株。该细胞分化较快,可形成能收缩的微管,产生特异的肌肉蛋白。在骨形态形成蛋白(BMP-2)的作用下,该细胞可由成肌细胞分化为成骨细胞。检测发现该细胞鼠痘病毒阴性。;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;梭形;相关产品有:AQ-Mel Cells、WEHI3 Cells、KYSE-450 Cells
AQP4(D12092-1C3-02) Cells(拥有STR基因鉴定图谱)
NCIH1385 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:P 815 Cells、NCI H345 Cells、Kobe university Oral Squamous Cell culture-2 Cells
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
H82 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:5传代,每周换液2-3次;生长特性:悬浮生长;形态特性:上皮细胞;相关产品有:FRTL-5 Cells、H596 Cells、OCM-1 Cells
Sc-1 Cells;背景说明:胚胎;自发永生;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:RS 4;11 Cells、SCI1 Cells、D283MED Cells
MC3T3-E Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SK-RC-42 Cells、LNCaP Cells、FLC7 Cells
MBMEC Cells;背景说明:脑微血管;内皮 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;相关产品有:CNLMG-B5537SKIN Cells、alphaTC1 Clone 6 Cells、UPCI:SCC90 Cells
Kupffer 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;形态特性:详见产品说明;相关产品有:Hs-729-T Cells、HN 4 Cells、SUM 190PT Cells
Hs 840.T Cells;背景说明:详见相关文献介绍;传代方法:1:4—1:8传代,每周换液2—3次;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:SUIT-2 Cells、HCC-2279 Cells、Human Liver-7702 Cells
CAL 120 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:CV-1.K Cells、D562 Cells、MRC9 Cells
GM24224 Cells(拥有STR基因鉴定图谱)
HAP1 NFIL3 (-) Cells(拥有STR基因鉴定图谱)
RGM-1 Cells;背景说明:胃黏膜;上皮细胞;自发永生;Wistar;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:RCC_7860 Cells、MDA436 Cells、HCC-1143 Cells
Ca 9-22 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:Caco-2 BBe Cells、CHL Cells、CHP212 Cells
NBL-5 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:RPMI no. 8226 Cells、PL-12 Cells、32D clone 3 Cells
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 Cells、H22 Cells、16HBE140 Cells
TE-4 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:上皮样;相关产品有:GOS-3 Cells、Hs 675.T Cells、SNT-8 Cells
COLO 680N Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SVG(P12) Cells、J45.01 Cells、5637 Cells
PE/CA-PJ34 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:HIT-T15 Cells、NS20-Y Cells、Hce8693 Cells
E.G7-OVA Cells;背景说明:详见相关文献介绍;传代方法:细胞密度保持在1×105—1×106 cells/ml,每周换液2—3次 ;生长特性:悬浮生长;形态特性:详见产品说明;相关产品有:EOC20 Cells、CAKI 1 Cells、AD-293 Cells
HQ02930 Cells(拥有STR基因鉴定图谱)
KK124 Cells(拥有STR基因鉴定图谱)
ML-DmBG1-c1 Cells(拥有STR基因鉴定图谱)
NRCAN-CF-9 Cells(拥有STR基因鉴定图谱)
rdES4 Cells(拥有STR基因鉴定图谱)
Ubigene HEK293T PKD1 KO Cells(拥有STR基因鉴定图谱)
WSBM Cells(拥有STR基因鉴定图谱)
HAP1 SMO (-) 1 Cells(拥有STR基因鉴定图谱)
Pt K1 (NBL-3) Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Jurkat 77 Cells、Hs-281-T Cells、Huh-7.5.1 Cells
X63-Ag8-653 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:CemT4 Cells、C-4-I Cells、NCIH1155 Cells
HT-115 Cells;背景说明:结肠癌;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:详见产品说明;相关产品有:32D.3 Cells、HSMC Cells、A-172 MG Cells
H1573 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;相关产品有:HUT 125 Cells、OSK-1 Cells、NK-10A Cells
NCI-H2030 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2-3次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:TK+/- (clone 3.7.2C) Cells、H-2591 Cells、BIU-87/Adr Cells
SUM-52-PE Cells;背景说明:乳腺癌;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;相关产品有:MDA MB 175 VII Cells、HN13 Cells、HuH1 Cells
Tokyo Medical and Dental university 8 Cells;背景说明:弥漫大B淋巴瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:CEK Cells、HB 611 Cells、FLC-7 Cells
SCL2 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;相关产品有:MD Anderson-Metastatic Breast-415 Cells、4175 Cells、TFK-1 Cells
TYK-nu Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:SEG-1 Cells、Mv 1 Lu (NBL-7) Cells、HTSMC Cells
Ca-Ski Cells;背景说明:这株细胞是从小肠肠系膜转移灶的细胞中建立的。 据报道,它含有完整的HPV-16(每个细胞大约600个拷贝)和HPV-18相关序列。;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:LIM1215 Cells、KPNRTBM1 Cells、L-1210 Cells
SUM52 Cells;背景说明:乳腺癌;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;相关产品有:PC-12 Cells、NCIH2081 Cells、NCI-H524 Cells
SUM-159PT Cells;背景说明:乳腺癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Hs683 Cells、OCI-LY-3 Cells、LC2/Ad Cells
CCRF CEM Cells;背景说明:G.E. Foley 等人建立了类淋巴母细胞细胞株CCRF-CEM。 细胞是1964年11月从一位四岁白人女性急性淋巴细胞白血病患者的外周血白血球衣中得到。此细胞系从香港收集而来。;传代方法:1:2传代。3天内可长满。;生长特性:悬浮生长;形态特性:淋巴母细胞样;相关产品有:ARO81-1 Cells、MKN 7 Cells、2PK-3 Cells
LCMS 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:贴壁生长;形态特性:上皮细胞样;相关产品有:KRC-Y Cells、Tj-905 Cells、CT-26 Cells
SupB15W 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:悬浮生长;形态特性:淋巴母细胞;相关产品有:SNU387 Cells、EOMA Cells、COLO-16 Cells
STBCi049-C Cells(拥有STR基因鉴定图谱)
CF-1 MEF Cells;背景说明:胚胎;成纤维细胞;CF-1;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Centre Antoine Lacassagne-62 Cells、RM1 Cells、NCI-H-82 Cells
H69 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:4传代,每周换液2次;生长特性:悬浮生长,聚团;形态特性:聚团悬浮;相关产品有:KYSE-50 Cells、Ontario Cancer Institute-Acute Myeloid Leukemia-4 Cells、PG [Human lung carcinoma] Cells
MCF-10A Cells;背景说明:乳腺;上皮细胞;自发永生;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:NALM6 Cells、Human Embryo Kidney-2 Cells、MCF7-CTRL Cells
ATC241 Cells;背景说明:纤维肉瘤;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:HT 1080.T Cells、CA922 Cells、MDBK Cells
Hs819T Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:3传代;每周换液2-3次;生长特性:贴壁生长;形态特性:成纤维;相关产品有:HS-766-T Cells、U2OS Cells、INS1-E Cells
M.D. Anderson-Prostate Cancer-2b 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:1E8-H Cells、H548 Cells、Panc-03.27 Cells
KYSE 70 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:REC Cells、Pt-K1 Cells、Kit225-K6 Cells
no-11 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:MiaPaca.2 Cells、KMB-17 Cells、HRIF Cells
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NCI-H2030 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2-3次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:TK+/- (clone 3.7.2C) Cells、H-2591 Cells、BIU-87/Adr Cells
MEL Cells;背景说明:DMSO可诱导该细胞向红系分化。;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:RS411 Cells、SKO007 Cells、UPCISCC154 Cells
KYSE 510 Cells;背景说明:食管鳞癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:NCIH1105 Cells、Pro-Lec1.3C Cells、IPECJ2 Cells
AC16 [Human hybrid] Cells;背景说明:心肌;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:SU86.86 Cells、C8-D1A Cells、TPC-1 Cells
T-98G Cells;背景说明:详见相关文献介绍;传代方法:按1:3传代;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:FHCRC-11 Cells、U87MG Cells、SU86_86 Cells
KMS18 Cells;背景说明:浆细胞骨髓瘤;男性;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;相关产品有:NALM 6 Cells、MPC-83 Cells、GM-346 Cells
BayGenomics ES cell line CSI570 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line RST672 Cells(拥有STR基因鉴定图谱)
C57MG-A5 Cells(拥有STR基因鉴定图谱)
LM142 Cells(拥有STR基因鉴定图谱)
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
R14-212-6 Cells(拥有STR基因鉴定图谱)
RLC-19 Cells(拥有STR基因鉴定图谱)
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Sensitivity of the Epstein-Barr virus transformed human lymphoid cell lines to interferon.
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Differences in the ability of human lymphoblastoid lines to exclude bromodeoxyuridine and in their sensitivity to methyl methanesulfonate and to incorporated [3H]thymidine.
Cancer Res. 39:312-320(1979)
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Klein F., Ricketts R.T., Jones W.I., DeArmon I.A., Temple M.J., Zoon K.C., Bridgen P.J.
Large-scale production and concentration of human lymphoid interferon.
Antimicrob. Agents Chemother. 15:420-427(1979)
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Povey S., Jeremiah S., Arthur E., Steel M., Klein G.
Differences in genetic stability between human cell lines from patients with and without lymphoreticular malignancy.
Ann. Hum. Genet. 44:119-133(1980)
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Benjamin D., Magrath I.T., Maguire R.T., Janus C., Todd-Kulikowsk H.D., Parsons R.G.
Immunoglobulin secretion by cell lines derived from African and American undifferentiated lymphomas of Burkitt's and non-Burkitt's type.
J. Immunol. 129:1336-1342(1982)
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Spira G., Koide N., Aman P., Ber R., Klein G.
Truncated mu chain in a Burkitt lymphoma line (P3HR-1) and its fate in various hemapoietic somatic cell hybrids.
Immunobiology 162:199-209(1982)
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Ehlin-Henriksson B., Klein G.
Distinction between Burkitt lymphoma subgroups by monoclonal antibodies: relationships between antigen expression and type of chromosomal translocation.
Int. J. Cancer 33:459-463(1984)
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Feinstein S., Traub A., Lazar A., Mizrahi A., Teitz Y.
Studies on cell binding and internalization of human lymphoblastoid (Namalva) interferon.
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Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cell lines -- 1 carboxylic esterase.
Leuk. Res. 9:209-229(1985)
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Wurm F.M., Polastri G.D., Hilfenhaus J., Harth H., Zankl H.
Long term cultivation of Namalva cells for interferon production: stable cytogenetic markers for identification of cells in spite of drastic chromosomal variation.
Dev. Biol. Stand. 60:393-403(1985)
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The cytogenetics of human B lymphoid malignancy: studies in Burkitt's lymphoma and Epstein-Barr virus-transformed lymphoblastoid cell lines.
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Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cell lines -- III Beta-hexosaminidase (E.C. 3.2.1.30).
Leuk. Res. 9:549-559(1985)
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Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cells lines -- II. Acid phosphatase.
Leuk. Res. 9:537-548(1985)
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Whitaker A.M.
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J. Biol. Stand. 13:173-175(1985)
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Heterogeneity of B-cell growth factor receptor reactivity in healthy donors and in patients with chronic lymphatic leukemia: relationship to B-cell-derived lymphokines.
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Expression of B-cell-specific markers in different Burkitt lymphoma subgroups.
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Sensitive, high-resolution chromatin and chromosome mapping in situ: presence and orientation of two closely integrated copies of EBV in a lymphoma line.
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B cell IL-7. Human B cell lines constitutively secrete IL-7 and express IL-7 receptors.
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Blood 109:271-280(2007)
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Oncol. Rep. 19:889-895(2008)
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A genome-wide screen for microdeletions reveals disruption of polarity complex genes in diverse human cancers.
Cancer Res. 70:2158-2164(2010)
PubMed=20454443; DOI=10.1155/2010/904767; PMCID=PMC2861168
Uphoff C.C., Denkmann S.A., Steube K.G., Drexler H.G.
Detection of EBV, HBV, HCV, HIV-1, HTLV-I and -II, and SMRV in human and other primate cell lines.
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PubMed=21269460; DOI=10.1186/1752-0509-5-17; PMCID=PMC3039570
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BMC Syst. Biol. 5:17.1-17.13(2011)
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The Cancer Cell Line Encyclopedia enables predictive modelling of anticancer drug sensitivity.
Nature 483:603-607(2012)
PubMed=22885699; DOI=10.1038/nature11378; PMCID=PMC3609867
Schmitz R., Young R.M., Ceribelli M., Jhavar S., Xiao W.-M., Zhang M.-L., Wright G., Shaffer A.L. 3rd, Hodson D.J., Buras E., Liu X.-L., Powell J.I., Yang Y.-D., Xu W.-H., Zhao H., Kohlhammer H., Rosenwald A., Kluin P.M., Muller-Hermelink H.-K., Ott G., Gascoyne R.D., Connors J.M., Rimsza L.M., Campo E., Jaffe E.S., Delabie J., Smeland E.B., Ogwang M.D., Reynolds S.J., Fisher R.I., Braziel R.M., Tubbs R.R., Cook J.R., Weisenburger D.D., Chan W.-C., Pittaluga S., Wilson W., Waldmann T.A., Rowe M., Mbulaiteye S.M., Rickinson A.B., Staudt L.M.
Burkitt lymphoma pathogenesis and therapeutic targets from structural and functional genomics.
Nature 490:116-120(2012)
PubMed=24590883; DOI=10.1002/gcc.22161
Murga Penas E.-M., Schilling G., Behrmann P., Klokow M., Vettorazzi E., Bokemeyer C., Dierlamm J.
Comprehensive cytogenetic and molecular cytogenetic analysis of 44 Burkitt lymphoma cell lines: secondary chromosomal changes characterization, karyotypic evolution, and comparison with primary samples.
Genes Chromosomes Cancer 53:497-515(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=25355872; DOI=10.1128/JVI.02570-14; PMCID=PMC4301145
Cao S.-B., Strong M.J., Wang X., Moss W.N., Concha M., Lin Z., O'Grady T., Baddoo M., Fewell C., Renne R., Flemington E.K.
High-throughput RNA sequencing-based virome analysis of 50 lymphoma cell lines from the Cancer Cell Line Encyclopedia project.
J. Virol. 89:713-729(2015)
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=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=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)
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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=29892436; DOI=10.1098/rsos.172472; PMCID=PMC5990783
Shioda S., Kasai F., Watanabe K., Kawakami K., Ohtani A., Iemura M., Ozawa M., Arakawa A., Hirayama N., Kawaguchi E., Tano T., Miyata S., Satoh M., Shimizu N., Kohara A.
Screening for 15 pathogenic viruses in human cell lines registered at the JCRB Cell Bank: characterization of in vitro human cells by viral infection.
R. Soc. Open Sci. 5:172472-172472(2018)
PubMed=30285677; DOI=10.1186/s12885-018-4840-5; PMCID=PMC6167786
Tan K.-T., Ding L.-W., Sun Q.-Y., Lao Z.-T., Chien W., Ren X., Xiao J.-F., Loh X.-Y., Xu L., Lill M., Mayakonda A., Lin D.-C., Yang H.H., Koeffler H.P.
Profiling the B/T cell receptor repertoire of lymphocyte derived cell lines.
BMC Cancer 18:940.1-940.13(2018)
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Uphoff C.C., Pommerenke C., Denkmann S.A., Drexler H.G.
Screening human cell lines for viral infections applying RNA-Seq data analysis.
PLoS ONE 14:E0210404-E0210404(2019)"
传代方法:1:2-1:4(首次传代建议1:2)
生长特性:悬浮生长
换液频率:每周2-3次
背景资料:最初是从一名患有Burkitt's淋巴瘤的患者的肿瘤组织中分离出来的。是一种高度恶性的B细胞淋巴瘤,常见于儿童和年轻人。有EB病毒基因组。
9L Cells;背景说明:胶质瘤;Fischer 344;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:ZYM-DIEC02 Cells、Homo sapiens No. 578, tumor cells Cells、HCC1008 Cells
343 MG Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长 ;形态特性:详见产品说明;相关产品有:SUD6 Cells、alpha-TC1.6 Cells、H-747 Cells
K422 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:N2a Cells、DHL-8 Cells、Chang Cells Cells
【细胞培养中细菌、霉菌的污染情况总结】细菌:细菌在普通倒置显微镜下为黑色细沙状,根据感染细菌的不同,可有不同的外形,培养一般会浑浊变黄,对细胞生长影响明显。仔细检查一下器皿的灭菌情况,是否在GAO压灭菌时放气时间足够,压力足够!尤其是和储存培养接触的移管等物品,连续两次污染的话有可能造成储存污染,一定要注意!下次使用前检查一下培养是否存在浑浊的现象!可在培养中加相应的抗生素处理;霉菌:培养是清亮的,倒置显微镜下无杂质,37度孵箱培养2-3天,仍清亮,但出现絮状杂质,镜下可见呈细丝状的团状漂浮物,可看到明显的菌丝,细胞仍可生长,但时间长之后,细胞的活力状态变差,用铜溶擦拭CO2孵箱内,再把水盘里也加上饱和量的铜。或者在培养箱的托盘加入饱和的消毒二钠GAO盐体,可以防止霉菌污染。CO2孵箱被霉菌污染后,可把所有细胞暂时转移,采用擦洗孵箱(包括隔板,箱壁)。并把放置在孵箱内一个小时,使其蒸汽弥漫。待的气味消散后,再移入细胞。孵箱应定期清洁(2月左右),尤其在多雨的季节。其它培养箱清洗方法是:用84擦洗-清水擦洗-75%酒精擦洗-紫外灯照。预防霉菌污染,可在培养基里加3u/ml的两性霉素或制霉菌素或D或双抗;但细胞一旦污染,很难挽救,制霉菌素或D或双抗都于事无补,建议舍弃该污染细胞,将环境彻底消毒,如果所有细胞都污染,可能是系统污染,检查一下培养基和器材,如果只是个别污染,可能是操作问题,就要注意操作。
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
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产品包装形式:复苏细胞:T25培养瓶(一瓶)或冻存细胞:1ml冻存管(两支)
来源说明:细胞主要来源ATCC、DSMZ等细胞库
物种来源:Human\Mouse\Rat\Others
H1623 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;相关产品有:OCILY7 Cells、HO-8910PM Cells、mouse Inner Medullary Collecting Duct-3 Cells
L-WRN Cells;背景说明:皮下结缔组织;自发永生;雄性;C3H/An;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:LC-1 Cells、NCIH1836 Cells、CW-2 Cells
C 643 Cells;背景说明:甲状腺未分化癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:NPC-TW 01 Cells、HTh74 Cells、MDA-453 Cells
OVCAR5 Cells;背景说明:卵巢癌;腹水转移;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;相关产品有:SK-NSH Cells、C3H10T1/2 clone8 Cells、H524 Cells
如何进行细胞复苏:1)从容器中取出冻存管,直接浸入37℃温水中,并不时摇动令其尽快融化;2)从37℃水浴中取出冻存管,打开盖子,用吸管吸出细胞悬,加到离心管并滴加10倍以上培养,混匀;3)离心,1000rpm,5min;4)弃去上清,加入含10%小牛血清培养重悬细胞,计数,调整细胞密度,接种培养瓶,37℃培养箱静置培养;5)次日更换一次培养,继续培养。【温馨提醒】1)从增殖期到形成致密的单层细胞以前的培养细胞都可以用于冻存,但ZuiHAO为对数生长期细胞。在冻存前一天ZuiHAO换一次培养;2)将冻存管放入容器或从中取出时,要做HAO防护工作(戴棉手套),以免冻伤;3)冻存和复苏ZuiHAO用新配制的培养。细胞复苏的时候,有些初次实验员将冻存管从中取出后,放在室温下,经常发生冻存管爆炸,该怎么避免出现这种情况吗?其中在拧紧冻存管的时候是否有哪些细节要注意的?一般常用的方法是取出冻存管后在超净工作台中用酒精棉球擦试管口,再稍拧松盖子,再放37度水浴锅中摇溶,在将细胞转移到装有37度预热过的培养基的试管中,迅速离心,再用培养基洗一遍。
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NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
形态特性:淋巴母细胞样
在细胞传代过程中,离心操作后的上清液处理是一个关键步骤,而关于是用移液枪吸走还是直接倒掉上清液,需要综合多方面因素来考量。使用移液枪吸走上清液具有一定的优势。移液枪能够较为精准地控制吸取的量和速度,可以地减少对细胞沉淀的扰动。可以根据实际情况尽可能地吸净上清液,减少残留血清或培养基成分对后续细胞培养的潜在影响,比如残留的血清可能会改变新培养基的营养成分比例或带来一些未知的生长因子干扰。然而,直接倒掉上清液也并非不可行。在处理一些细胞数量较多、细胞耐受性较好且对实验精度要求并非极高的细胞传代时,直接倒掉上清液能够提高操作效率,节省时间。但这种方式存在一定风险,直接倾倒时较难控制力度和角度,如果操作不慎,容易使细胞沉淀随着上清液一起流出,导致细胞损失,而且可能会因液体快速流下冲击细胞沉淀造成细胞的物理性损伤。在实际的细胞传代操作中,应根据细胞的特性、实验的要求以及个人的操作熟练程度来选择合适的上清液处理方式。对于新手或者处理珍贵细胞系时,建议优先采用移液枪吸走的方式,以保障细胞的活性和传代的成功率。而在积累了丰富经验且对实验条件有充分把握的情况下,可以根据具体情况灵活运用直接倒掉上清液的方法,在保证实验质量的同时提高工作效率。
OVTOKO Cells;背景说明:卵巢透明细胞癌;脾转移;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;相关产品有:RL-65 Cells、Tn 5B1-4 Cells、ketr 3 Cells
WM115mel Cells;背景说明:黑色素瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Panc203 Cells、HTori-3.1 Cells、UCLA RO-81A-1 Cells
SU-DHL-8 Cells;背景说明:弥漫大B淋巴瘤;腹腔积液转移;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:CII Cells、HMrSV5 Cells、MCA38 Cells
Panc 04.03 Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:上皮样;相关产品有:Mono-Mac-1 Cells、T2(174 x CEM.T2) Cells、L428 Cells
KU 19-19 Cells;背景说明:膀胱癌;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Bovine Turbinate Cells、NCIH2141 Cells、Caco-2BBe Cells
HH [Human lymphoma] 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:NCIH1184 Cells、H-1882 Cells、C2A Cells
Oka-C1 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:H-719 Cells、NCI-H322 Cells、HHFK Cells
JB-6 Cl 30 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:U-343 MG Cells、EC-109 Cells、V79 Cells
Hs 766 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:8传代,每周换液2—3次;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:SUM52PE Cells、A172 Cells、HF-91 Cells
Abcam HCT 116 NF1 KO Cells(拥有STR基因鉴定图谱)
AG07882 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line DTM007 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line TEA178 Cells(拥有STR基因鉴定图谱)
BL8 TB1 Cells(拥有STR基因鉴定图谱)
┈订┈购┈热┈线:1┈5┈8┈0┈0┈5┈7┈6┈8┈6┈7【微信同号】┈Q┈Q:3┈3┈0┈7┈2┈0┈4┈2┈7┈1;
CLS-79 Cells(拥有STR基因鉴定图谱)
DA03495 Cells(拥有STR基因鉴定图谱)
EtOH-1 Cells(拥有STR基因鉴定图谱)
GM07278 Cells(拥有STR基因鉴定图谱)
TE-15 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:上皮样;相关产品有:MV4:11 Cells、CHOS Cells、NCI-H820 Cells
NCIH1651 Cells;背景说明:详见相关文献介绍;传代方法:1:3-1:8传代,每周换液2次;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:KG-1 Cells、HuT 78 Cells、NCIH1792 Cells
SNT-8 Cells;背景说明:NK/T细胞淋巴瘤;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:Vero E-6 Cells、HPAEC Cells、HET-1A Cells
Mouse podocyte Cells;背景说明:肾;足 Cells;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:PANC 813 Cells、MEC-1 Cells、L5178Y-R Cells
HCEpiC Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:C2BBe1 Cells、Meat Animal Research Center-145 Cells、RFL-6 Cells
SCL-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;形态特性:上皮细胞样;相关产品有:MDA-MB-175-VII Cells、SO-RB50 Cells、NCI-H1581 Cells
RH8994 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SVGp12 Cells、Opossum Kidney Cells、NCI-H3255 Cells
HPDE Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长 ;形态特性:详见产品说明;相关产品有:PC2 Cells、CTSC-3 Cells、P3X63 AG 8.653 Cells
RIN-14B Cells;背景说明:胰岛素瘤;雄性;NEDH;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Uhth-74 Cells、TE11 Cells、TE10 Cells
C4-1 Cells;背景说明:宫颈鳞癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:IOSE80UBC Cells、HeLa S 3 Cells、COR-L88 Cells
SKMES-1 Cells;背景说明:源于一位65岁患有肺鳞状细胞癌的白人男性,自转移性胸腔积液分离而来。;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:PCI-04B Cells、MDBK Cells、GES1 Cells
SHI1 Cells;背景说明:急性单核细胞白血病;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:RAG Cells、U266 Bl Cells、LIM1215 Cells
C2-C12 Cells;背景说明:该细胞株是YaffeD,SaxelO建立的小鼠成肌细胞系的亚株。该细胞分化较快,可形成能收缩的微管,产生特异的肌肉蛋白。在骨形态形成蛋白(BMP-2)的作用下,该细胞可由成肌细胞分化为成骨细胞。检测发现该细胞鼠痘病毒阴性。;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;梭形;相关产品有:AQ-Mel Cells、WEHI3 Cells、KYSE-450 Cells
AQP4(D12092-1C3-02) Cells(拥有STR基因鉴定图谱)
NCIH1385 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:P 815 Cells、NCI H345 Cells、Kobe university Oral Squamous Cell culture-2 Cells
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
H82 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:5传代,每周换液2-3次;生长特性:悬浮生长;形态特性:上皮细胞;相关产品有:FRTL-5 Cells、H596 Cells、OCM-1 Cells
Sc-1 Cells;背景说明:胚胎;自发永生;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:RS 4;11 Cells、SCI1 Cells、D283MED Cells
MC3T3-E Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SK-RC-42 Cells、LNCaP Cells、FLC7 Cells
MBMEC Cells;背景说明:脑微血管;内皮 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;相关产品有:CNLMG-B5537SKIN Cells、alphaTC1 Clone 6 Cells、UPCI:SCC90 Cells
Kupffer 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;形态特性:详见产品说明;相关产品有:Hs-729-T Cells、HN 4 Cells、SUM 190PT Cells
Hs 840.T Cells;背景说明:详见相关文献介绍;传代方法:1:4—1:8传代,每周换液2—3次;生长特性:贴壁生长;形态特性:成纤维细胞;相关产品有:SUIT-2 Cells、HCC-2279 Cells、Human Liver-7702 Cells
CAL 120 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:CV-1.K Cells、D562 Cells、MRC9 Cells
GM24224 Cells(拥有STR基因鉴定图谱)
HAP1 NFIL3 (-) Cells(拥有STR基因鉴定图谱)
RGM-1 Cells;背景说明:胃黏膜;上皮细胞;自发永生;Wistar;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:RCC_7860 Cells、MDA436 Cells、HCC-1143 Cells
Ca 9-22 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁生长;形态特性:上皮细胞;相关产品有:Caco-2 BBe Cells、CHL Cells、CHP212 Cells
NBL-5 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:RPMI no. 8226 Cells、PL-12 Cells、32D clone 3 Cells
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 Cells、H22 Cells、16HBE140 Cells
TE-4 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:上皮样;相关产品有:GOS-3 Cells、Hs 675.T Cells、SNT-8 Cells
COLO 680N Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:SVG(P12) Cells、J45.01 Cells、5637 Cells
PE/CA-PJ34 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:HIT-T15 Cells、NS20-Y Cells、Hce8693 Cells
E.G7-OVA Cells;背景说明:详见相关文献介绍;传代方法:细胞密度保持在1×105—1×106 cells/ml,每周换液2—3次 ;生长特性:悬浮生长;形态特性:详见产品说明;相关产品有:EOC20 Cells、CAKI 1 Cells、AD-293 Cells
HQ02930 Cells(拥有STR基因鉴定图谱)
KK124 Cells(拥有STR基因鉴定图谱)
ML-DmBG1-c1 Cells(拥有STR基因鉴定图谱)
NRCAN-CF-9 Cells(拥有STR基因鉴定图谱)
rdES4 Cells(拥有STR基因鉴定图谱)
Ubigene HEK293T PKD1 KO Cells(拥有STR基因鉴定图谱)
WSBM Cells(拥有STR基因鉴定图谱)
HAP1 SMO (-) 1 Cells(拥有STR基因鉴定图谱)
Pt K1 (NBL-3) Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:Jurkat 77 Cells、Hs-281-T Cells、Huh-7.5.1 Cells
X63-Ag8-653 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:CemT4 Cells、C-4-I Cells、NCIH1155 Cells
HT-115 Cells;背景说明:结肠癌;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:详见产品说明;相关产品有:32D.3 Cells、HSMC Cells、A-172 MG Cells
H1573 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;相关产品有:HUT 125 Cells、OSK-1 Cells、NK-10A Cells
NCI-H2030 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2-3次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:TK+/- (clone 3.7.2C) Cells、H-2591 Cells、BIU-87/Adr Cells
SUM-52-PE Cells;背景说明:乳腺癌;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;相关产品有:MDA MB 175 VII Cells、HN13 Cells、HuH1 Cells
Tokyo Medical and Dental university 8 Cells;背景说明:弥漫大B淋巴瘤;男性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:悬浮;形态特性:详见产品说明;相关产品有:CEK Cells、HB 611 Cells、FLC-7 Cells
SCL2 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;相关产品有:MD Anderson-Metastatic Breast-415 Cells、4175 Cells、TFK-1 Cells
TYK-nu Cells;背景说明:详见相关文献介绍;传代方法:1:2传代;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:SEG-1 Cells、Mv 1 Lu (NBL-7) Cells、HTSMC Cells
Ca-Ski Cells;背景说明:这株细胞是从小肠肠系膜转移灶的细胞中建立的。 据报道,它含有完整的HPV-16(每个细胞大约600个拷贝)和HPV-18相关序列。;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:LIM1215 Cells、KPNRTBM1 Cells、L-1210 Cells
SUM52 Cells;背景说明:乳腺癌;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;相关产品有:PC-12 Cells、NCIH2081 Cells、NCI-H524 Cells
SUM-159PT Cells;背景说明:乳腺癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Hs683 Cells、OCI-LY-3 Cells、LC2/Ad Cells
CCRF CEM Cells;背景说明:G.E. Foley 等人建立了类淋巴母细胞细胞株CCRF-CEM。 细胞是1964年11月从一位四岁白人女性急性淋巴细胞白血病患者的外周血白血球衣中得到。此细胞系从香港收集而来。;传代方法:1:2传代。3天内可长满。;生长特性:悬浮生长;形态特性:淋巴母细胞样;相关产品有:ARO81-1 Cells、MKN 7 Cells、2PK-3 Cells
LCMS 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:贴壁生长;形态特性:上皮细胞样;相关产品有:KRC-Y Cells、Tj-905 Cells、CT-26 Cells
SupB15W 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:悬浮生长;形态特性:淋巴母细胞;相关产品有:SNU387 Cells、EOMA Cells、COLO-16 Cells
STBCi049-C Cells(拥有STR基因鉴定图谱)
CF-1 MEF Cells;背景说明:胚胎;成纤维细胞;CF-1;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:Centre Antoine Lacassagne-62 Cells、RM1 Cells、NCI-H-82 Cells
H69 Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:4传代,每周换液2次;生长特性:悬浮生长,聚团;形态特性:聚团悬浮;相关产品有:KYSE-50 Cells、Ontario Cancer Institute-Acute Myeloid Leukemia-4 Cells、PG [Human lung carcinoma] Cells
MCF-10A Cells;背景说明:乳腺;上皮细胞;自发永生;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:NALM6 Cells、Human Embryo Kidney-2 Cells、MCF7-CTRL Cells
ATC241 Cells;背景说明:纤维肉瘤;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:HT 1080.T Cells、CA922 Cells、MDBK Cells
Hs819T Cells;背景说明:详见相关文献介绍;传代方法:1:2—1:3传代;每周换液2-3次;生长特性:贴壁生长;形态特性:成纤维;相关产品有:HS-766-T Cells、U2OS Cells、INS1-E Cells
M.D. Anderson-Prostate Cancer-2b 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:1E8-H Cells、H548 Cells、Panc-03.27 Cells
KYSE 70 Cells;背景说明:详见相关文献介绍;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁或悬浮,详见产品说明部分;形态特性:详见产品说明;相关产品有:REC Cells、Pt-K1 Cells、Kit225-K6 Cells
no-11 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:MiaPaca.2 Cells、KMB-17 Cells、HRIF Cells
┈订┈购┈热┈线:1┈5┈8┈0┈0┈5┈7┈6┈8┈6┈7【微信同号】┈Q┈Q:3┈3┈0┈7┈2┈0┈4┈2┈7┈1;
NCI-H2030 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2-3次。;生长特性:贴壁生长;形态特性:上皮细胞样;相关产品有:TK+/- (clone 3.7.2C) Cells、H-2591 Cells、BIU-87/Adr Cells
MEL Cells;背景说明:DMSO可诱导该细胞向红系分化。;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:RS411 Cells、SKO007 Cells、UPCISCC154 Cells
KYSE 510 Cells;背景说明:食管鳞癌;女性;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:NCIH1105 Cells、Pro-Lec1.3C Cells、IPECJ2 Cells
AC16 [Human hybrid] Cells;背景说明:心肌;传代方法:1:2-1:3传代;每周换液2-3次。;生长特性:贴壁;形态特性:详见产品说明;相关产品有:SU86.86 Cells、C8-D1A Cells、TPC-1 Cells
T-98G Cells;背景说明:详见相关文献介绍;传代方法:按1:3传代;生长特性:贴壁生长;形态特性:详见产品说明;相关产品有:FHCRC-11 Cells、U87MG Cells、SU86_86 Cells
KMS18 Cells;背景说明:浆细胞骨髓瘤;男性;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;相关产品有:NALM 6 Cells、MPC-83 Cells、GM-346 Cells
BayGenomics ES cell line CSI570 Cells(拥有STR基因鉴定图谱)
BayGenomics ES cell line RST672 Cells(拥有STR基因鉴定图谱)
C57MG-A5 Cells(拥有STR基因鉴定图谱)
LM142 Cells(拥有STR基因鉴定图谱)
NAMALWA人Burkitt's淋巴瘤传代细胞活性强|送STR图谱
R14-212-6 Cells(拥有STR基因鉴定图谱)
RLC-19 Cells(拥有STR基因鉴定图谱)
" "PubMed=170370; DOI=10.1099/0022-1317-28-2-207
Adams A., Strander H., Cantell K.
Sensitivity of the Epstein-Barr virus transformed human lymphoid cell lines to interferon.
J. Gen. Virol. 28:207-217(1975)
PubMed=216485
Higgins N.P., Strauss B.S.
Differences in the ability of human lymphoblastoid lines to exclude bromodeoxyuridine and in their sensitivity to methyl methanesulfonate and to incorporated [3H]thymidine.
Cancer Res. 39:312-320(1979)
PubMed=464569; DOI=10.1128/AAC.15.3.420; PMCID=PMC352676
Klein F., Ricketts R.T., Jones W.I., DeArmon I.A., Temple M.J., Zoon K.C., Bridgen P.J.
Large-scale production and concentration of human lymphoid interferon.
Antimicrob. Agents Chemother. 15:420-427(1979)
PubMed=7316467; DOI=10.1111/j.1469-1809.1980.tb00953.x
Povey S., Jeremiah S., Arthur E., Steel M., Klein G.
Differences in genetic stability between human cell lines from patients with and without lymphoreticular malignancy.
Ann. Hum. Genet. 44:119-133(1980)
PubMed=6286763; DOI=10.4049/jimmunol.129.3.1336
Benjamin D., Magrath I.T., Maguire R.T., Janus C., Todd-Kulikowsk H.D., Parsons R.G.
Immunoglobulin secretion by cell lines derived from African and American undifferentiated lymphomas of Burkitt's and non-Burkitt's type.
J. Immunol. 129:1336-1342(1982)
PubMed=6811418; DOI=10.1016/S0171-2985(11)80031-8
Spira G., Koide N., Aman P., Ber R., Klein G.
Truncated mu chain in a Burkitt lymphoma line (P3HR-1) and its fate in various hemapoietic somatic cell hybrids.
Immunobiology 162:199-209(1982)
PubMed=6231253; DOI=10.1002/ijc.2910330407
Ehlin-Henriksson B., Klein G.
Distinction between Burkitt lymphoma subgroups by monoclonal antibodies: relationships between antigen expression and type of chromosomal translocation.
Int. J. Cancer 33:459-463(1984)
PubMed=2580922; DOI=10.1089/jir.1985.5.65
Feinstein S., Traub A., Lazar A., Mizrahi A., Teitz Y.
Studies on cell binding and internalization of human lymphoblastoid (Namalva) interferon.
J. Interferon Res. 5:65-76(1985)
PubMed=2985879; DOI=10.1016/0145-2126(85)90084-0
Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cell lines -- 1 carboxylic esterase.
Leuk. Res. 9:209-229(1985)
PubMed=2995175
Wurm F.M., Polastri G.D., Hilfenhaus J., Harth H., Zankl H.
Long term cultivation of Namalva cells for interferon production: stable cytogenetic markers for identification of cells in spite of drastic chromosomal variation.
Dev. Biol. Stand. 60:393-403(1985)
PubMed=2998993
Steel C.M., Morten J.E.N., Foster E.
The cytogenetics of human B lymphoid malignancy: studies in Burkitt's lymphoma and Epstein-Barr virus-transformed lymphoblastoid cell lines.
IARC Sci. Publ. 60:265-292(1985)
PubMed=3159941; DOI=10.1016/0145-2126(85)90134-1
Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cell lines -- III Beta-hexosaminidase (E.C. 3.2.1.30).
Leuk. Res. 9:549-559(1985)
PubMed=3874327; DOI=10.1016/0145-2126(85)90133-x
Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cells lines -- II. Acid phosphatase.
Leuk. Res. 9:537-548(1985)
PubMed=3997900; DOI=10.1016/S0092-1157(85)80024-x
Whitaker A.M.
The chromosomes of the Namalwa cell line.
J. Biol. Stand. 13:173-175(1985)
PubMed=2415623; DOI=10.4049/jimmunol.136.1.320
Goldmacher V.S., Lambert J.M., Young A.Y., Anderson J., Tinnel N.L., Kornacki M., Ritz J., Blattler W.A.
Expression of the common acute lymphoblastic leukemia antigen (CALLA) on the surface of individual cells of human lymphoblastoid lines.
J. Immunol. 136:320-325(1986)
PubMed=3080238
Sieverts H., Alabaster O., Goldschmidts W., Magrath I.T.
Expression of surface antigens during the cell cycle in different growth phases of American and African Burkitt's lymphoma cell lines.
Cancer Res. 46:1182-1188(1986)
PubMed=3100061; DOI=10.1016/0008-8749(86)90099-7
Benjamin D., Bazar L.S., Wallace B., Jacobson R.J.
Heterogeneity of B-cell growth factor receptor reactivity in healthy donors and in patients with chronic lymphatic leukemia: relationship to B-cell-derived lymphokines.
Cell. Immunol. 103:394-408(1986)
PubMed=3026973; DOI=10.1002/ijc.2910390215
Ehlin-Henriksson B., Manneborg-Sandlund A., Klein G.
Expression of B-cell-specific markers in different Burkitt lymphoma subgroups.
Int. J. Cancer 39:211-218(1987)
PubMed=2830981; DOI=10.1016/0092-8674(88)90530-2
Lawrence J.B., Villnave C.A., Singer R.H.
Sensitive, high-resolution chromatin and chromosome mapping in situ: presence and orientation of two closely integrated copies of EBV in a lymphoma line.
Cell 52:51-61(1988)
PubMed=1915267; DOI=10.1002/j.1460-2075.1991.tb07837.x; PMCID=PMC452998
Farrell P.J., Allan G.J., Shanahan F., Vousden K.H., Crook T.
p53 is frequently mutated in Burkitt's lymphoma cell lines.
EMBO J. 10:2879-2887(1991)
PubMed=2052620; DOI=10.1073/pnas.88.12.5413; PMCID=PMC51883
Gaidano G., Ballerini P., Gong J.Z., Inghirami G., Neri A., Newcomb E.W., Magrath I.T., Knowles D.M., Dalla-Favera R.
p53 mutations in human lymphoid malignancies: association with Burkitt lymphoma and chronic lymphocytic leukemia.
Proc. Natl. Acad. Sci. U.S.A. 88:5413-5417(1991)
PubMed=1325212; DOI=10.1182/blood.V80.5.1289.1289
Benjamin D., Knobloch T.J., Dayton M.A.
Human B-cell interleukin-10: B-cell lines derived from patients with acquired immunodeficiency syndrome and Burkitt's lymphoma constitutively secrete large quantities of interleukin-10.
Blood 80:1289-1298(1992)
PubMed=1339415; DOI=10.1002/ijc.2910520320
Middleton P.G., Miller S., Ross J.A., Steel C.M., Guy K.
Insertion of SMRV-H viral DNA at the c-myc gene locus of a BL cell line and presence in established cell lines.
Int. J. Cancer 52:451-454(1992)
PubMed=8344493; DOI=10.1096/fasebj.7.10.8344493
Bhatia K.G., Goldschmidts W., Gutierrez M.I., Gaidano G., Dalla-Favera R., Magrath I.T.
Hemi- or homozygosity: a requirement for some but not other p53 mutant proteins to accumulate and exert a pathogenetic effect.
FASEB J. 7:951-956(1993)
PubMed=8402660
O'Connor P.M., Jackman J., Jondle D., Bhatia K.G., Magrath I.T., Kohn K.W.
Role of the p53 tumor suppressor gene in cell cycle arrest and radiosensitivity of Burkitt's lymphoma cell lines.
Cancer Res. 53:4776-4780(1993)
PubMed=8515068; DOI=10.4049/jimmunol.150.12.5418
Jain V.K., Judde J.-G., Max E.E., Magrath I.T.
Variable IgH chain enhancer activity in Burkitt's lymphomas suggests an additional, direct mechanism of c-myc deregulation.
J. Immunol. 150:5418-5428(1993)
PubMed=8176200; DOI=10.4049/jimmunol.152.10.4749
Benjamin D., Sharma V., Knobloch T.J., Armitage R.J., Dayton M.A., Goodwin R.G.
B cell IL-7. Human B cell lines constitutively secrete IL-7 and express IL-7 receptors.
J. Immunol. 152:4749-4757(1994)
PubMed=7849311; DOI=10.1182/blood.V85.4.893.bloodjournal854893
Stranks G., Height S.E., Mitchell P., Jadayel D.M., Yuille M.A.R., De Lord C.F.M., Clutterbuck R.D., Treleaven J.G., Powles R.L., Nacheva E., Oscier D.G., Karpas A., Lenoir G.M., Smith S.D., Millar J.L., Catovsky D., Dyer M.J.S.
Deletions and rearrangement of CDKN2 in lymphoid malignancy.
Blood 85:893-901(1995)
DOI=10.11418/jtca1981.15.4_211
Matsuo Y., Okochi A., Ariyasu T., Iimura E., Ohno T.
Identification of cell lines with variable numbers of tandem repeat (VNTR) amplified by polymerase chain reaction.
Tissue Cult. Res. Commun. 15:211-219(1996)
PubMed=8558920
Dirks W.G., Zaborski M., Jager K., Challier C., Shiota M., Quentmeier H., Drexler H.G.
The (2;5)(p23;q35) translocation in cell lines derived from malignant lymphomas: absence of t(2;5) in Hodgkin-analogous cell lines.
Leukemia 10:142-149(1996)
PubMed=8568269; DOI=10.4049/jimmunol.156.4.1626
Benjamin D., Sharma V., Kubin M., Klein J.L., Sartori A., Holliday J., Trinchieri G.
IL-12 expression in AIDS-related lymphoma B cell lines.
J. Immunol. 156:1626-1637(1996)
PubMed=9192833
Cherney B.W., Bhatia K.G., Sgadari C., Gutierrez M.I., Mostowski H.S., Pike S.E., Gupta G., Magrath I.T., Tosato G.
Role of the p53 tumor suppressor gene in the tumorigenicity of Burkitt's lymphoma cells.
Cancer Res. 57:2508-2515(1997)
PubMed=9473234; DOI=10.1182/blood.V91.5.1680
Klangby U., Okan I., Magnusson K.P., Wendland M., Lind P., Wiman K.G.
p16/INK4a and p15/INK4b gene methylation and absence of p16/INK4a mRNA and protein expression in Burkitt's lymphoma.
Blood 91:1680-1687(1998)
PubMed=9973220
Gutierrez M.I., Cherney B.W., Hussain A., Mostowski H.S., Tosato G., Magrath I.T., Bhatia K.G.
Bax is frequently compromised in Burkitt's lymphomas with irreversible resistance to Fas-induced apoptosis.
Cancer Res. 59:696-703(1999)
PubMed=10739008; DOI=10.1016/S0145-2126(99)00182-4
Inoue K., Kohno T., Takakura S., Hayashi Y., Mizoguchi H., Yokota J.
Frequent microsatellite instability and BAX mutations in T cell acute lymphoblastic leukemia cell lines.
Leuk. Res. 24:255-262(2000)
PubMed=11226526; DOI=10.1016/S0145-2126(00)00121-1
Inoue K., Kohno T., Takakura S., Hayashi Y., Mizoguchi H., Yokota J.
Corrigendum to: Frequent microsatellite instability and BAX mutations in T cell acute lymphoblastic leukemia cell lines Leukemia Research 24 (2000), 255-262.
Leuk. Res. 25:275-278(2001)
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Langerak A.W., Moreau E.J., van Gastel-Mol E.J., van der Burg M., van Dongen J.J.M.
Detection of clonal EBV episomes in lymphoproliferations as a diagnostic tool.
Leukemia 16:1572-1573(2002)
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Mestre-Escorihuela C., Rubio-Moscardo F., Richter J.A., Siebert R., Climent J., Fresquet V., Beltran E., Agirre X., Marugan I., Marin M., Rosenwald A., Sugimoto K.-j., Wheat L.M., Karran E.L., Garcia J.F., Sanchez-Verde L., Prosper F., Staudt L.M., Pinkel D., Dyer M.J.S., Martinez-Climent J.A.
Homozygous deletions localize novel tumor suppressor genes in B-cell lymphomas.
Blood 109:271-280(2007)
PubMed=18357372; DOI=10.3892/or.19.4.889
Pop I., Pop L., Vitetta E.S., Ghetie M.-A.
Generation of multidrug resistant lymphoma cell lines stably expressing P-glycoprotein.
Oncol. Rep. 19:889-895(2008)
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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=20454443; DOI=10.1155/2010/904767; PMCID=PMC2861168
Uphoff C.C., Denkmann S.A., Steube K.G., Drexler H.G.
Detection of EBV, HBV, HCV, HIV-1, HTLV-I and -II, and SMRV in human and other primate cell lines.
J. Biomed. Biotechnol. 2010:904767.1-904767.23(2010)
PubMed=21269460; DOI=10.1186/1752-0509-5-17; PMCID=PMC3039570
Burkard T.R., Planyavsky M., Kaupe I., Breitwieser F.P., Burckstummer T., Bennett K.L., Superti-Furga G., Colinge J.
Initial characterization of the human central proteome.
BMC Syst. Biol. 5:17.1-17.13(2011)
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=22885699; DOI=10.1038/nature11378; PMCID=PMC3609867
Schmitz R., Young R.M., Ceribelli M., Jhavar S., Xiao W.-M., Zhang M.-L., Wright G., Shaffer A.L. 3rd, Hodson D.J., Buras E., Liu X.-L., Powell J.I., Yang Y.-D., Xu W.-H., Zhao H., Kohlhammer H., Rosenwald A., Kluin P.M., Muller-Hermelink H.-K., Ott G., Gascoyne R.D., Connors J.M., Rimsza L.M., Campo E., Jaffe E.S., Delabie J., Smeland E.B., Ogwang M.D., Reynolds S.J., Fisher R.I., Braziel R.M., Tubbs R.R., Cook J.R., Weisenburger D.D., Chan W.-C., Pittaluga S., Wilson W., Waldmann T.A., Rowe M., Mbulaiteye S.M., Rickinson A.B., Staudt L.M.
Burkitt lymphoma pathogenesis and therapeutic targets from structural and functional genomics.
Nature 490:116-120(2012)
PubMed=24590883; DOI=10.1002/gcc.22161
Murga Penas E.-M., Schilling G., Behrmann P., Klokow M., Vettorazzi E., Bokemeyer C., Dierlamm J.
Comprehensive cytogenetic and molecular cytogenetic analysis of 44 Burkitt lymphoma cell lines: secondary chromosomal changes characterization, karyotypic evolution, and comparison with primary samples.
Genes Chromosomes Cancer 53:497-515(2014)
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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=25355872; DOI=10.1128/JVI.02570-14; PMCID=PMC4301145
Cao S.-B., Strong M.J., Wang X., Moss W.N., Concha M., Lin Z., O'Grady T., Baddoo M., Fewell C., Renne R., Flemington E.K.
High-throughput RNA sequencing-based virome analysis of 50 lymphoma cell lines from the Cancer Cell Line Encyclopedia project.
J. Virol. 89:713-729(2015)
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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.
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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.
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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.
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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.
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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.
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Shioda S., Kasai F., Watanabe K., Kawakami K., Ohtani A., Iemura M., Ozawa M., Arakawa A., Hirayama N., Kawaguchi E., Tano T., Miyata S., Satoh M., Shimizu N., Kohara A.
Screening for 15 pathogenic viruses in human cell lines registered at the JCRB Cell Bank: characterization of in vitro human cells by viral infection.
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Tan K.-T., Ding L.-W., Sun Q.-Y., Lao Z.-T., Chien W., Ren X., Xiao J.-F., Loh X.-Y., Xu L., Lill M., Mayakonda A., Lin D.-C., Yang H.H., Koeffler H.P.
Profiling the B/T cell receptor repertoire of lymphocyte derived cell lines.
BMC Cancer 18:940.1-940.13(2018)
PubMed=30629668; DOI=10.1371/journal.pone.0210404; PMCID=PMC6328144
Uphoff C.C., Pommerenke C., Denkmann S.A., Drexler H.G.
Screening human cell lines for viral infections applying RNA-Seq data analysis.
PLoS ONE 14:E0210404-E0210404(2019)"
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文献和实验该产品被引用文献
"PubMed=170370; DOI=10.1099/0022-1317-28-2-207
Adams A., Strander H., Cantell K.
Sensitivity of the Epstein-Barr virus transformed human lymphoid cell lines to interferon.
J. Gen. Virol. 28:207-217(1975)
PubMed=216485
Higgins N.P., Strauss B.S.
Differences in the ability of human lymphoblastoid lines to exclude bromodeoxyuridine and in their sensitivity to methyl methanesulfonate and to incorporated [3H]thymidine.
Cancer Res. 39:312-320(1979)
PubMed=464569; DOI=10.1128/AAC.15.3.420; PMCID=PMC352676
Klein F., Ricketts R.T., Jones W.I., DeArmon I.A., Temple M.J., Zoon K.C., Bridgen P.J.
Large-scale production and concentration of human lymphoid interferon.
Antimicrob. Agents Chemother. 15:420-427(1979)
PubMed=7316467; DOI=10.1111/j.1469-1809.1980.tb00953.x
Povey S., Jeremiah S., Arthur E., Steel M., Klein G.
Differences in genetic stability between human cell lines from patients with and without lymphoreticular malignancy.
Ann. Hum. Genet. 44:119-133(1980)
PubMed=6286763; DOI=10.4049/jimmunol.129.3.1336
Benjamin D., Magrath I.T., Maguire R.T., Janus C., Todd-Kulikowsk H.D., Parsons R.G.
Immunoglobulin secretion by cell lines derived from African and American undifferentiated lymphomas of Burkitt's and non-Burkitt's type.
J. Immunol. 129:1336-1342(1982)
PubMed=6811418; DOI=10.1016/S0171-2985(11)80031-8
Spira G., Koide N., Aman P., Ber R., Klein G.
Truncated mu chain in a Burkitt lymphoma line (P3HR-1) and its fate in various hemapoietic somatic cell hybrids.
Immunobiology 162:199-209(1982)
PubMed=6231253; DOI=10.1002/ijc.2910330407
Ehlin-Henriksson B., Klein G.
Distinction between Burkitt lymphoma subgroups by monoclonal antibodies: relationships between antigen expression and type of chromosomal translocation.
Int. J. Cancer 33:459-463(1984)
PubMed=2580922; DOI=10.1089/jir.1985.5.65
Feinstein S., Traub A., Lazar A., Mizrahi A., Teitz Y.
Studies on cell binding and internalization of human lymphoblastoid (Namalva) interferon.
J. Interferon Res. 5:65-76(1985)
PubMed=2985879; DOI=10.1016/0145-2126(85)90084-0
Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cell lines -- 1 carboxylic esterase.
Leuk. Res. 9:209-229(1985)
PubMed=2995175
Wurm F.M., Polastri G.D., Hilfenhaus J., Harth H., Zankl H.
Long term cultivation of Namalva cells for interferon production: stable cytogenetic markers for identification of cells in spite of drastic chromosomal variation.
Dev. Biol. Stand. 60:393-403(1985)
PubMed=2998993
Steel C.M., Morten J.E.N., Foster E.
The cytogenetics of human B lymphoid malignancy: studies in Burkitt's lymphoma and Epstein-Barr virus-transformed lymphoblastoid cell lines.
IARC Sci. Publ. 60:265-292(1985)
PubMed=3159941; DOI=10.1016/0145-2126(85)90134-1
Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cell lines -- III Beta-hexosaminidase (E.C. 3.2.1.30).
Leuk. Res. 9:549-559(1985)
PubMed=3874327; DOI=10.1016/0145-2126(85)90133-x
Drexler H.G., Gaedicke G., Minowada J.
Isoenzyme studies in human leukemia-lymphoma cells lines -- II. Acid phosphatase.
Leuk. Res. 9:537-548(1985)
PubMed=3997900; DOI=10.1016/S0092-1157(85)80024-x
Whitaker A.M.
The chromosomes of the Namalwa cell line.
J. Biol. Stand. 13:173-175(1985)
PubMed=2415623; DOI=10.4049/jimmunol.136.1.320
Goldmacher V.S., Lambert J.M., Young A.Y., Anderson J., Tinnel N.L., Kornacki M., Ritz J., Blattler W.A.
Expression of the common acute lymphoblastic leukemia antigen (CALLA) on the surface of individual cells of human lymphoblastoid lines.
J. Immunol. 136:320-325(1986)
PubMed=3080238
Sieverts H., Alabaster O., Goldschmidts W., Magrath I.T.
Expression of surface antigens during the cell cycle in different growth phases of American and African Burkitt's lymphoma cell lines.
Cancer Res. 46:1182-1188(1986)
PubMed=3100061; DOI=10.1016/0008-8749(86)90099-7
Benjamin D., Bazar L.S., Wallace B., Jacobson R.J.
Heterogeneity of B-cell growth factor receptor reactivity in healthy donors and in patients with chronic lymphatic leukemia: relationship to B-cell-derived lymphokines.
Cell. Immunol. 103:394-408(1986)
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Ehlin-Henriksson B., Manneborg-Sandlund A., Klein G.
Expression of B-cell-specific markers in different Burkitt lymphoma subgroups.
Int. J. Cancer 39:211-218(1987)
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Lawrence J.B., Villnave C.A., Singer R.H.
Sensitive, high-resolution chromatin and chromosome mapping in situ: presence and orientation of two closely integrated copies of EBV in a lymphoma line.
Cell 52:51-61(1988)
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Farrell P.J., Allan G.J., Shanahan F., Vousden K.H., Crook T.
p53 is frequently mutated in Burkitt's lymphoma cell lines.
EMBO J. 10:2879-2887(1991)
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Gaidano G., Ballerini P., Gong J.Z., Inghirami G., Neri A., Newcomb E.W., Magrath I.T., Knowles D.M., Dalla-Favera R.
p53 mutations in human lymphoid malignancies: association with Burkitt lymphoma and chronic lymphocytic leukemia.
Proc. Natl. Acad. Sci. U.S.A. 88:5413-5417(1991)
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Benjamin D., Knobloch T.J., Dayton M.A.
Human B-cell interleukin-10: B-cell lines derived from patients with acquired immunodeficiency syndrome and Burkitt's lymphoma constitutively secrete large quantities of interleukin-10.
Blood 80:1289-1298(1992)
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Middleton P.G., Miller S., Ross J.A., Steel C.M., Guy K.
Insertion of SMRV-H viral DNA at the c-myc gene locus of a BL cell line and presence in established cell lines.
Int. J. Cancer 52:451-454(1992)
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Bhatia K.G., Goldschmidts W., Gutierrez M.I., Gaidano G., Dalla-Favera R., Magrath I.T.
Hemi- or homozygosity: a requirement for some but not other p53 mutant proteins to accumulate and exert a pathogenetic effect.
FASEB J. 7:951-956(1993)
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O'Connor P.M., Jackman J., Jondle D., Bhatia K.G., Magrath I.T., Kohn K.W.
Role of the p53 tumor suppressor gene in cell cycle arrest and radiosensitivity of Burkitt's lymphoma cell lines.
Cancer Res. 53:4776-4780(1993)
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Jain V.K., Judde J.-G., Max E.E., Magrath I.T.
Variable IgH chain enhancer activity in Burkitt's lymphomas suggests an additional, direct mechanism of c-myc deregulation.
J. Immunol. 150:5418-5428(1993)
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Benjamin D., Sharma V., Knobloch T.J., Armitage R.J., Dayton M.A., Goodwin R.G.
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Blood 85:893-901(1995)
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Matsuo Y., Okochi A., Ariyasu T., Iimura E., Ohno T.
Identification of cell lines with variable numbers of tandem repeat (VNTR) amplified by polymerase chain reaction.
Tissue Cult. Res. Commun. 15:211-219(1996)
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Dirks W.G., Zaborski M., Jager K., Challier C., Shiota M., Quentmeier H., Drexler H.G.
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Leukemia 10:142-149(1996)
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Benjamin D., Sharma V., Kubin M., Klein J.L., Sartori A., Holliday J., Trinchieri G.
IL-12 expression in AIDS-related lymphoma B cell lines.
J. Immunol. 156:1626-1637(1996)
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Cherney B.W., Bhatia K.G., Sgadari C., Gutierrez M.I., Mostowski H.S., Pike S.E., Gupta G., Magrath I.T., Tosato G.
Role of the p53 tumor suppressor gene in the tumorigenicity of Burkitt's lymphoma cells.
Cancer Res. 57:2508-2515(1997)
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Distinction between Burkitt lymphoma subgroups by monoclonal antibodies: relationships between antigen expression and type of chromosomal translocation.
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Sieverts H., Alabaster O., Goldschmidts W., Magrath I.T.
Expression of surface antigens during the cell cycle in different growth phases of American and African Burkitt's lymphoma cell lines.
Cancer Res. 46:1182-1188(1986)
PubMed=3100061; DOI=10.1016/0008-8749(86)90099-7
Benjamin D., Bazar L.S., Wallace B., Jacobson R.J.
Heterogeneity of B-cell growth factor receptor reactivity in healthy donors and in patients with chronic lymphatic leukemia: relationship to B-cell-derived lymphokines.
Cell. Immunol. 103:394-408(1986)
PubMed=3026973; DOI=10.1002/ijc.2910390215
Ehlin-Henriksson B., Manneborg-Sandlund A., Klein G.
Expression of B-cell-specific markers in different Burkitt lymphoma subgroups.
Int. J. Cancer 39:211-218(1987)
PubMed=2830981; DOI=10.1016/0092-8674(88)90530-2
Lawrence J.B., Villnave C.A., Singer R.H.
Sensitive, high-resolution chromatin and chromosome mapping in situ: presence and orientation of two closely integrated copies of EBV in a lymphoma line.
Cell 52:51-61(1988)
PubMed=1915267; DOI=10.1002/j.1460-2075.1991.tb07837.x; PMCID=PMC452998
Farrell P.J., Allan G.J., Shanahan F., Vousden K.H., Crook T.
p53 is frequently mutated in Burkitt's lymphoma cell lines.
EMBO J. 10:2879-2887(1991)
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Gaidano G., Ballerini P., Gong J.Z., Inghirami G., Neri A., Newcomb E.W., Magrath I.T., Knowles D.M., Dalla-Favera R.
p53 mutations in human lymphoid malignancies: association with Burkitt lymphoma and chronic lymphocytic leukemia.
Proc. Natl. Acad. Sci. U.S.A. 88:5413-5417(1991)
PubMed=1325212; DOI=10.1182/blood.V80.5.1289.1289
Benjamin D., Knobloch T.J., Dayton M.A.
Human B-cell interleukin-10: B-cell lines derived from patients with acquired immunodeficiency syndrome and Burkitt's lymphoma constitutively secrete large quantities of interleukin-10.
Blood 80:1289-1298(1992)
PubMed=1339415; DOI=10.1002/ijc.2910520320
Middleton P.G., Miller S., Ross J.A., Steel C.M., Guy K.
Insertion of SMRV-H viral DNA at the c-myc gene locus of a BL cell line and presence in established cell lines.
Int. J. Cancer 52:451-454(1992)
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Bhatia K.G., Goldschmidts W., Gutierrez M.I., Gaidano G., Dalla-Favera R., Magrath I.T.
Hemi- or homozygosity: a requirement for some but not other p53 mutant proteins to accumulate and exert a pathogenetic effect.
FASEB J. 7:951-956(1993)
PubMed=8402660
O'Connor P.M., Jackman J., Jondle D., Bhatia K.G., Magrath I.T., Kohn K.W.
Role of the p53 tumor suppressor gene in cell cycle arrest and radiosensitivity of Burkitt's lymphoma cell lines.
Cancer Res. 53:4776-4780(1993)
PubMed=8515068; DOI=10.4049/jimmunol.150.12.5418
Jain V.K., Judde J.-G., Max E.E., Magrath I.T.
Variable IgH chain enhancer activity in Burkitt's lymphomas suggests an additional, direct mechanism of c-myc deregulation.
J. Immunol. 150:5418-5428(1993)
PubMed=8176200; DOI=10.4049/jimmunol.152.10.4749
Benjamin D., Sharma V., Knobloch T.J., Armitage R.J., Dayton M.A., Goodwin R.G.
B cell IL-7. Human B cell lines constitutively secrete IL-7 and express IL-7 receptors.
J. Immunol. 152:4749-4757(1994)
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Stranks G., Height S.E., Mitchell P., Jadayel D.M., Yuille M.A.R., De Lord C.F.M., Clutterbuck R.D., Treleaven J.G., Powles R.L., Nacheva E., Oscier D.G., Karpas A., Lenoir G.M., Smith S.D., Millar J.L., Catovsky D., Dyer M.J.S.
Deletions and rearrangement of CDKN2 in lymphoid malignancy.
Blood 85:893-901(1995)
DOI=10.11418/jtca1981.15.4_211
Matsuo Y., Okochi A., Ariyasu T., Iimura E., Ohno T.
Identification of cell lines with variable numbers of tandem repeat (VNTR) amplified by polymerase chain reaction.
Tissue Cult. Res. Commun. 15:211-219(1996)
PubMed=8558920
Dirks W.G., Zaborski M., Jager K., Challier C., Shiota M., Quentmeier H., Drexler H.G.
The (2;5)(p23;q35) translocation in cell lines derived from malignant lymphomas: absence of t(2;5) in Hodgkin-analogous cell lines.
Leukemia 10:142-149(1996)
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Benjamin D., Sharma V., Kubin M., Klein J.L., Sartori A., Holliday J., Trinchieri G.
IL-12 expression in AIDS-related lymphoma B cell lines.
J. Immunol. 156:1626-1637(1996)
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Cherney B.W., Bhatia K.G., Sgadari C., Gutierrez M.I., Mostowski H.S., Pike S.E., Gupta G., Magrath I.T., Tosato G.
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