SNB-75Homo sapiens (Human)Cancer cell line

Also known as: Surgical Neurology Branch-75, SNB75, SNB.75

🤖 AI SummaryBased on 14 publications

Quick Overview

SNB-75 is a human cancer cell line used in cancer research.

Detailed Summary

SNB-75 is a human cancer cell line derived from a central nervous system tumor. It is part of the NCI-60 panel, a widely used collection of cancer cell lines for drug screening and research. The cell line is utilized in studies related to cancer biology, drug resistance, and molecular profiling. SNB-75 has been characterized in various studies for its genetic and molecular features, contributing to the understanding of cancer mechanisms and therapeutic strategies.

Research Applications

Cancer researchDrug screeningMolecular profilingCancer biologyDrug resistance studies

Key Characteristics

Part of the NCI-60 panelUsed in drug screeningCharacterized for genetic and molecular featuresUtilized in cancer biology studies
Generated on 6/17/2025

Basic Information

Database IDCVCL_1706
SpeciesHomo sapiens (Human)
Tissue SourceBrain[UBERON:UBERON_0000955]

Donor Information

Age75
Age CategoryAdult
SexFemale

Disease Information

DiseaseGlioblastoma
LineageCNS/Brain
SubtypeGlioblastoma
OncoTree CodeGB

DepMap Information

Source TypeAcademic lab
Source IDACH-000504_source

Known Sequence Variations

TypeGene/ProteinDescriptionZygosityNoteSource
MutationSimpleTP53p.Glu258Lys (c.772G>A)Homozygous-PubMed=18277095, PubMed=17088437, PubMed=15900046

Haplotype Information (STR Profile)

Short Tandem Repeat (STR) profile for cell line authentication.

Amelogenin
X
CSF1PO
10,12
D13S317
8,12
D16S539
11,13
D18S51
18
D19S433
13,14
D21S11
30
D2S1338
17,23
D3S1358
17
D5S818
12
D7S820
9
D8S1179
12
FGA
19,23
TH01
6,9
TPOX
8,10
vWA
16,18
Gene Expression Profile
Gene expression levels and statistical distribution
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Full DepMap dataset with combined data across cell lines

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Publications

Pan-cancer proteomic map of 949 human cell lines.";

Robinson P.J., Zhong Q., Garnett M.J., Reddel R.R.

Cancer Cell 40:835-849.e8(2022).

Next-generation characterization of the Cancer Cell Line Encyclopedia.

Sellers W.R.

Nature 569:503-508(2019).

Prioritization of cancer therapeutic targets using CRISPR-Cas9 screens.

Stronach E.A., Saez-Rodriguez J., Yusa K., Garnett M.J.

Nature 568:511-516(2019).

An interactive resource to probe genetic diversity and estimated ancestry in cancer cell lines.

Dutil J., Chen Z.-H., Monteiro A.N.A., Teer J.K., Eschrich S.A.

Cancer Res. 79:1263-1273(2019).

Characterization of human cancer cell lines by reverse-phase protein arrays.

Liang H.

Cancer Cell 31:225-239(2017).

A map of mobile DNA insertions in the NCI-60 human cancer cell panel.

Gnanakkan V.P., Cornish T.C., Boeke J.D., Burns K.H.

Mob. DNA 7:20.1-20.11(2016).

A landscape of pharmacogenomic interactions in cancer.";

Wessels L.F.A., Saez-Rodriguez J., McDermott U., Garnett M.J.

Cell 166:740-754(2016).

Long non-coding RNA expression profiling in the NCI60 cancer cell line panel using high-throughput RT-qPCR.

Vandesompele J.

Sci. Data 3:160052-160052(2016).

High resolution copy number variation data in the NCI-60 cancer cell lines from whole genome microarrays accessible through CellMiner.

Varma S., Pommier Y., Sunshine M., Weinstein J.N., Reinhold W.C.

PLoS ONE 9:E92047-E92047(2014).

The metabolic demands of cancer cells are coupled to their size and protein synthesis rates.

Hirshfield K.M., Oltvai Z.N., Vazquez A.

Cancer Metab. 1:20.1-20.13(2013).

Global proteome analysis of the NCI-60 cell line panel.";

Wilhelm M., Kuster B.

Cell Rep. 4:609-620(2013).

The exomes of the NCI-60 panel: a genomic resource for cancer biology and systems pharmacology.

Simon R.M., Doroshow J.H., Pommier Y., Meltzer P.S.

Cancer Res. 73:4372-4382(2013).

Metabolite profiling identifies a key role for glycine in rapid cancer cell proliferation.

Kafri R., Kirschner M.W., Clish C.B., Mootha V.K.

Science 336:1040-1044(2012).

Identification of cancer cell-line origins using fluorescence image-based phenomic screening.

Yoon C.N., Chang Y.-T.

PLoS ONE 7:E32096-E32096(2012).

Mass homozygotes accumulation in the NCI-60 cancer cell lines as compared to HapMap trios, and relation to fragile site location.

Ruan X.-Y., Kocher J.-P.A., Pommier Y., Liu H.-F., Reinhold W.C.

PLoS ONE 7:E31628-E31628(2012).

JFCR39, a panel of 39 human cancer cell lines, and its application in the discovery and development of anticancer drugs.

Kong D.-X., Yamori T.

Bioorg. Med. Chem. 20:1947-1951(2012).

Redefining the relevance of established cancer cell lines to the study of mechanisms of clinical anti-cancer drug resistance.

Ambudkar S.V., Gottesman M.M.

Proc. Natl. Acad. Sci. U.S.A. 108:18708-18713(2011).

Signatures of mutation and selection in the cancer genome.";

Deloukas P., Yang F.-T., Campbell P.J., Futreal P.A., Stratton M.R.

Nature 463:893-898(2010).

DNA fingerprinting of the NCI-60 cell line panel.";

Chanock S.J., Weinstein J.N.

Mol. Cancer Ther. 8:713-724(2009).

Analysis of p53 mutation status in human cancer cell lines: a paradigm for cell line cross-contamination.

Berglind H., Pawitan Y., Kato S., Ishioka C., Soussi T.

Cancer Biol. Ther. 7:699-708(2008).

Mutation analysis of 24 known cancer genes in the NCI-60 cell line set.

Reinhold W.C., Weinstein J.N., Stratton M.R., Futreal P.A., Wooster R.

Mol. Cancer Ther. 5:2606-2612(2006).

p53-defective tumors with a functional apoptosome-mediated pathway: a new therapeutic target.

Tomoda H., Yamori T., Tsuruo T.

J. Natl. Cancer Inst. 97:765-777(2005).

HLA class I and II genotype of the NCI-60 cell lines.";

Morse H.C. 3rd, Stroncek D., Marincola F.M.

J. Transl. Med. 3:11.1-11.8(2005).

Systematic variation in gene expression patterns in human cancer cell lines.

Botstein D., Brown P.O.

Nat. Genet. 24:227-235(2000).

Feasibility of drug screening with panels of human tumor cell lines using a microculture tetrazolium assay.

Fine D.L., Abbott B.J., Mayo J.G., Shoemaker R.H., Boyd M.R.

Cancer Res. 48:589-601(1988).

Plasminogen activator and inhibitor activity in human glioma cells and modulation by sodium butyrate.

Gross J.L., Behrens D.L., Mullins D.E., Kornblith P.L., Dexter D.L.

Cancer Res. 48:291-296(1988).

Feasibility of a high-flux anticancer drug screen using a diverse panel of cultured human tumor cell lines.

Gray-Goodrich M., Campbell H., Mayo J.G., Boyd M.R.

J. Natl. Cancer Inst. 83:757-766(1991).