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SK-N-MC人神经上皮瘤细胞[套餐促销]

英文名:SK-N-MC
货号:ZQ0977
价格:¥1350.00
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SK-N-MC人神经上皮瘤细胞[套餐促销]

¥1350.00
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SK-N-MC人神经上皮瘤细胞专用培养基

¥350.00 ¥480.00

配套完培,省时省力,单买细胞无优惠

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细胞套餐惊爆价

¥1700 ¥2280.00
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  • 产品说明
  • 产品规格
  • 参考文献
  • STR鉴定

产品名称

 人神经上皮瘤细胞SK-N-MC

货号

ZQ0977   

产品介绍

这株细胞是由BiedlerJL建立的两株神经组织来源的细胞中的一株(另一株是SK-N-SH),1971年9月分离得到。发现该细胞系具有中等的多巴胺-β-羟化酶活性以及甲醛诱导的指示细胞内儿茶酚胺的荧光。

种属

性别/年龄

女/14岁

组织

疾病

神经上皮瘤

生物安全等级

BSL-1

STR位点信息

Amelogenin: X

CSF1PO: 10

D13S317: 11

D16S539: 12

D5S818: 11

D7S820: 8

THO1: 9.3

TPOX: 9,11

vWA: 17,18

细胞类型

 肿瘤细胞

形态学

上皮样

生长方式

贴壁生长

倍增时间

 32 hours (PubMed=4748425); 23 hours (PubMed=24312454); ~32 hours (CLS=300340); ~48 hours (DSMZ=ACC-203)

培养基和添加剂

MEM(含有NEAA)(品牌:中乔新舟 货号ZQ-300+10%FBS(品牌:中乔新舟 货号:ZQ500-A+1%双抗(中乔新舟  货号:CSP006

推荐完全培养基货号

ZM0977

培养条件

95%空气,5%二氧化碳;37℃

抗原表达/受体表达

 ***

基因表达

 ***

保藏机构

ATCC; HTB-10 DSMZ; ACC-203 ECACC; 90022302 KCLB; 30010 

供应限制

仅供科研使用


货号

ZQ0977

发货规格

活细胞:T25培养瓶*1瓶或者1ml 冻存管*1支(细胞量约为5 x 10^5 cells/vial)二选一

发货形式

活细胞:常温运输;冻存管:干冰运输

储存温度

活细胞:培养箱;冻存管:液氮罐

产地

中国

供应限制

仅供科研使用

PubMed=4748425
Biedler J.L., Helson L., Spengler B.A.
Morphology and growth, tumorigenicity, and cytogenetics of human neuroblastoma cells in continuous culture.
Cancer Res. 33:2643-2652(1973)


DOI=10.1007/978-1-4757-1647-4_13
Biedler J.L.
Chromosome abnormalities in human tumor cells in culture.
(In) Human tumor cells in vitro; Fogh J. (eds.); pp.359-394; Springer; New York (1975)


PubMed=62055; DOI=10.1093/jnci/57.3.683
Biedler J.L., Spengler B.A.
A novel chromosome abnormality in human neuroblastoma and antifolate-resistant Chinese hamster cell lives in culture.
J. Natl. Cancer Inst. 57:683-695(1976)


PubMed=327080; DOI=10.1093/jnci/59.1.221
Fogh J., Fogh J.M., Orfeo T.
One hundred and twenty-seven cultured human tumor cell lines producing tumors in nude mice.
J. Natl. Cancer Inst. 59:221-226(1977)


PubMed=29704
Biedler J.L., Roffler-Tarlov S., Schachner M., Freedman L.S.
Multiple neurotransmitter synthesis by human neuroblastoma cell lines and clones.
Cancer Res. 38:3751-3757(1978)


PubMed=7459858
Rousset M., Zweibaum A., Fogh J.
Presence of glycogen and growth-related variations in 58 cultured human tumor cell lines of various tissue origins.
Cancer Res. 41:1165-1170(1981)


PubMed=7037175
Reynolds C.P., Reynolds D.A., Frenkel E.P., Smith R.G.
Selective toxicity of 6-hydroxydopamine and ascorbate for human neuroblastoma in vitro: a model for clearing marrow prior to autologous transplant.
Cancer Res. 42:1331-1336(1982)


DOI=10.1016/B978-0-12-008304-6.50015-4
Biedler J.L., Meyers M.B., Spengler B.A.
Homogeneously staining regions and double minute chromosomes, prevalent cytogenetic abnormalities of human neuroblastoma cells.
(In) Advances in cellular neurobiology, Vol. 4; Fedoroff S., Hertz L. (eds.); pp.267-307; Academic Press; New York (1983)


PubMed=6582512; DOI=10.1073/pnas.81.2.568
Mattes M.J., Cordon-Cardo C., Lewis J.L. Jr., Old L.J., Lloyd K.O.
Cell surface antigens of human ovarian and endometrial carcinoma defined by mouse monoclonal antibodies.
Proc. Natl. Acad. Sci. U.S.A. 81:568-572(1984)


PubMed=2987426; DOI=10.1007/BF00165170
Helson L., Helson C.
Human neuroblastoma cells and 13-cis-retinoic acid.
J. Neurooncol. 3:39-41(1985)


PubMed=3518877; DOI=10.3109/07357908609038260
Fogh J.
Human tumor lines for cancer research.
Cancer Invest. 4:157-184(1986)


PubMed=2784858; DOI=10.1073/pnas.86.8.2804
Knuth A., Wolfel T., Klehmann E., Boon T., Meyer zum Buschenfelde K.-H.
Cytolytic T-cell clones against an autologous human melanoma: specificity study and definition of three antigens by immunoselection.
Proc. Natl. Acad. Sci. U.S.A. 86:2804-2808(1989)


PubMed=8378080
Kovar H., Auinger A., Jug G., Aryee D.N.T., Zoubek A., Salzer-Kuntschik M., Gadner H.
Narrow spectrum of infrequent p53 mutations and absence of MDM2 amplification in Ewing tumours.
Oncogene 8:2683-2690(1993)


DOI=10.1016/B978-0-12-333530-2.50006-X
Israel M.A., Thiele C.J.
Tumor cell lines of the peripheral nervous system.
(In) Atlas of human tumor cell lines; Hay R.J., Park J.-G., Gazdar A.F. (eds.); pp.43-78; Academic Press; New York (1994)


PubMed=8040301; DOI=10.1172/JCI117360
Giovannini M., Biegel J.A., Serra M., Wang J.-Y., Wei Y.-L.H., Nycum L., Emanuel B.S., Evans G.A.
EWS-erg and EWS-Fli1 fusion transcripts in Ewing's sarcoma and primitive neuroectodermal tumors with variant translocations.
J. Clin. Invest. 94:489-496(1994)


PubMed=7591257; DOI=10.1002/ijc.2910630407
Ida K., Kobayashi S., Taki T., Hanada R., Bessho F., Yamamori S., Sugimoto T., Ohki M., Hayashi Y.
EWS-FLI-1 and EWS-ERG chimeric mRNAs in Ewing's sarcoma and primitive neuroectodermal tumor.
Int. J. Cancer 63:500-504(1995)


PubMed=8570170
van Weering D.H.J., Medema J.P., van Puijenbroek A.A.F.L., Burgering B.M.T., Baas P.D., Bos J.L.
Ret receptor tyrosine kinase activates extracellular signal-regulated kinase 2 in SK-N-MC cells.
Oncogene 11:2207-2214(1995)


PubMed=8617485; DOI=10.1016/S0046-8177(96)90115-X
Scotlandi K., Serra M., Manara M.C., Benini S., Sarti M., Maurici D., Lollini P.-L., Picci P., Bertoni F., Baldini N.
Immunostaining of the p30/32MIC2 antigen and molecular detection of EWS rearrangements for the diagnosis of Ewing's sarcoma and peripheral neuroectodermal tumor.
Hum. Pathol. 27:408-416(1996)


PubMed=8665486; DOI=10.1016/0304-3835(96)04250-4
Diccianni M.B., Chau L.S., Batova A., Vu T.Q., Yu A.L.-T.
The p16 and p18 tumor suppressor genes in neuroblastoma: implications for drug resistance.
Cancer Lett. 104:183-192(1996)


PubMed=9121763; DOI=10.1038/sj.onc.1200911
van Puijenbroek A.A.F.L., van Weering D.H.J., van den Brink C.E., Bos J.L., van der Saag P.T., de Laat S.W., den Hertog J.
Cell scattering of SK-N-MC neuroepithelioma cells in response to Ret and FGF receptor tyrosine kinase activation is correlated with sustained ERK2 activation.
Oncogene 14:1147-1157(1997)


PubMed=11668190; DOI=10.1177/002215540104901105
Quentmeier H., Osborn M., Reinhardt J., Zaborski M., Drexler H.G.
Immunocytochemical analysis of cell lines derived from solid tumors.
J. Histochem. Cytochem. 49:1369-1378(2001)


PubMed=15390183; DOI=10.1002/gcc.20096
Gebauer S., Yu A.L.-T., Omura-Minamisawa M., Batova A., Diccianni M.B.
Expression profiles and clinical relationships of ID2, CDKN1B, and CDKN2A in primary neuroblastoma.
Genes Chromosomes Cancer 41:297-308(2004)


PubMed=18160777; DOI=10.1159/000109614
Savola S., Nardi F., Scotlandi K., Picci P., Knuutila S.
Microdeletions in 9p21.3 induce false negative results in CDKN2A FISH analysis of Ewing sarcoma.
Cytogenet. Genome Res. 119:21-26(2007)


PubMed=19787792; DOI=10.1002/gcc.20717
Ottaviano L., Schaefer K.-L., Gajewski M., Huckenbeck W., Baldus S.E., Rogel U., Mackintosh C., de Alava E., Myklebost O., Kresse S.H., Meza-Zepeda L.A., Serra M., Cleton-Jansen A.-M., Hogendoorn P.C.W., Buerger H., Aigner T., Gabbert H.E., Poremba C.
Molecular characterization of commonly used cell lines for bone tumor research: a trans-European EuroBoNet effort.
Genes Chromosomes Cancer 49:40-51(2010)


PubMed=20143388; DOI=10.1002/ijc.25242
Capes-Davis A., Theodosopoulos G., Atkin I., Drexler H.G., Kohara A., MacLeod R.A.F., Masters J.R.W., Nakamura Y., Reid Y.A., Reddel R.R., Freshney R.I.
Check your cultures! A list of cross-contaminated or misidentified cell lines.
Int. J. Cancer 127:1-8(2010)


PubMed=21822310; DOI=10.1038/onc.2011.317
Mackintosh C., Ordonez J.L., Garcia-Dominguez D.J., Sevillano V., Llombart-Bosch A., Szuhai K., Scotlandi K., Alberghini M., Sciot R., Sinnaeve F., Hogendoorn P.C.W., Picci P., Knuutila S., Dirksen U., Debiec-Rychter M., Schaefer K.-L., de Alava E.
1q gain and CDT2 overexpression underlie an aggressive and highly proliferative form of Ewing sarcoma.
Oncogene 31:1287-1298(2012)


PubMed=22460905; DOI=10.1038/nature11003
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=23325432; DOI=10.1101/gr.147942.112
Varley K.E., Gertz J., Bowling K.M., Parker S.L., Reddy T.E., Pauli-Behn F., Cross M.K., Williams B.A., Stamatoyannopoulos J.A., Crawford G.E., Absher D.M., Wold B.J., Myers R.M.
Dynamic DNA methylation across diverse human cell lines and tissues.
Genome Res. 23:555-567(2013)


PubMed=24312454; DOI=10.1371/journal.pone.0080060
May W.A., Grigoryan R.S., Keshelava N., Cabral D.J., Christensen L.L., Jenabi J., Ji L.-Y., Triche T.J., Lawlor E.R., Reynolds C.P.
Characterization and drug resistance patterns of Ewing's sarcoma family tumor cell lines.
PLoS ONE 8:E80060-E80060(2013)


PubMed=25010205; DOI=10.1371/journal.pgen.1004475
Brohl A.S., Solomon D.A., Chang W., Wang J.-J., Song Y., Sindiri S., Patidar R., Hurd L., Chen L., Shern J.F., Liao H.-L., Wen X.-Y., Gerard J., Kim J.-S., Lopez Guerrero J.A., Machado I., Wai D.H., Picci P., Triche T.J., Horvai A.E., Miettinen M.M., Wei J.S., Catchpoole D., Llombart-Bosch A., Waldman T., Khan J.
The genomic landscape of the Ewing sarcoma family of tumors reveals recurrent STAG2 mutation.
PLoS Genet. 10:E1004475-E1004475(2014)


PubMed=25223734; DOI=10.1158/2159-8290.CD-14-0622
Tirode F., Surdez D., Ma X.-T., Parker M., Le Deley M.-C., Bahrami A., Zhang Z.-J., Lapouble E., Grossetete-Lalami S., Rusch M., Reynaud S., Rio-Frio T., Hedlund E., Wu G., Chen X., Pierron G., Oberlin O., Zaidi S., Lemmon G., Gupta P., Vadodaria B., Easton J., Gut M., Ding L., Mardis E.R., Wilson R.K., Shurtleff S., Laurence V., Michon J., Marec-Berard P., Gut I.G., Downing J.R., Dyer M.A., Zhang J.-H., Delattre O.
Genomic landscape of Ewing sarcoma defines an aggressive subtype with co-association of STAG2 and TP53 mutations.
Cancer Discov. 4:1342-1353(2014)


PubMed=26351324; DOI=10.1158/1535-7163.MCT-15-0074
Teicher B.A., Polley E.C., Kunkel M., Evans D., Silvers T.E., Delosh R.M., Laudeman J., Ogle C., Reinhart R., Selby M., Connelly J., Harris E., Monks A., Morris J.
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Mol. Cancer Ther. 14:2452-2462(2015)


PubMed=26428435; DOI=10.1016/j.ejca.2015.08.020
Sand L.G.L., Scotlandi K., Berghuis D., Snaar-Jagalska B.E., Picci P., Schmidt T., Szuhai K., Hogendoorn P.C.W.
CXCL14, CXCR7 expression and CXCR4 splice variant ratio associate with survival and metastases in Ewing sarcoma patients.
Eur. J. Cancer 51:2624-2633(2015)


PubMed=26589293; DOI=10.1186/s13073-015-0240-5
Scholtalbers J., Boegel S., Bukur T., Byl M., Goerges S., Sorn P., Loewer M., Sahin U., Castle J.C.
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Genome Med. 7:118.1-118.7(2015)


PubMed=30879952; DOI=10.1016/j.ymthe.2019.02.014
Kailayangiri S., Altvater B., Lesch S., Balbach S.T., Gottlich C., Kuhnemundt J., Mikesch J.-H., Schelhaas S., Jamitzky S., Meltzer J., Farwick N., Greune L., Fluegge M., Kerl K., Lode H.N., Siebert N., Muller I., Walles H., Hartmann W., Rossig C.
EZH2 inhibition in Ewing sarcoma upregulates GD2 expression for targeting with gene-modified T cells.
Mol. Ther. 27:933-946(2019)


PubMed=30894373; DOI=10.1158/0008-5472.CAN-18-2747
Dutil J., Chen Z.-H., Monteiro A.N.A., Teer J.K., Eschrich S.A.
An interactive resource to probe genetic diversity and estimated ancestry in cancer cell lines.
Cancer Res. 79:1263-1273(2019)


PubMed=31068700; DOI=10.1038/s41586-019-1186-3
Ghandi M., Huang F.W., Jane-Valbuena J., Kryukov G.V., Lo C.C., McDonald E.R. III, Barretina J.G., Gelfand E.T., Bielski C.M., Li H.-X., Hu K., Andreev-Drakhlin A.Y., Kim J., Hess J.M., Haas B.J., Aguet F., Weir B.A., Rothberg M.V., Paolella B.R., Lawrence M.S., Akbani R., Lu Y.-L., Tiv H.L., Gokhale P.C., de Weck A., Mansour A.A., Oh C., Shih J., Hadi K., Rosen Y., Bistline J., Venkatesan K., Reddy A., Sonkin D., Liu M., Lehar J., Korn J.M., Porter D.A., Jones M.D., Golji J., Caponigro G., Taylor J.E., Dunning C.M., Creech A.L., Warren A.C., McFarland J.M., Zamanighomi M., Kauffmann A., Stransky N., Imielinski M., Maruvka Y.E., Cherniack A.D., Tsherniak A., Vazquez F., Jaffe J.D., Lane A.A., Weinstock D.M., Johannessen C.M., Morrissey M.P., Stegmeier F., Schlegel R., Hahn W.C., Getz G., Mills G.B., Boehm J.S., Golub T.R., Garraway L.A., Sellers W.R.
Next-generation characterization of the Cancer Cell Line Encyclopedia.
Nature 569:503-508(2019)


PubMed=31978347; DOI=10.1016/j.cell.2019.12.023
Nusinow D.P., Szpyt J., Ghandi M., Rose C.M., McDonald E.R. III, Kalocsay M., Jane-Valbuena J., Gelfand E.T., Schweppe D.K., Jedrychowski M.P., Golji J., Porter D.A., Rejtar T., Wang Y.K., Kryukov G.V., Stegmeier F., Erickson B.K., Garraway L.A., Sellers W.R., Gygi S.P.
Quantitative proteomics of the Cancer Cell Line Encyclopedia.
Cell 180:387-402.e16(2020)


DOI=10.5282/edoc.27750
Orth M.F.
Systematic multi-omics profiling of Ewing sarcoma cell lines.
Thesis PhD (2021), Ludwig Maximilians University of Munich, Germany

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