Human embryonic stem cells and metastatic colorectal cancer cells shared the common endogenous human microRNA-26bOne hundred and twenty-seven cultured human tumor cell lines producing tumors in nude miceCharacterization of Human Cancer Cell Lines by Reverse-phase Protein ArraysCentrosome amplification and instability occurs exclusively in aneuploid, but not in diploid colorectal cancer cell lines, and correlates with numerical chromosomal aberrations5-Fluorouracil response in a large panel of colorectal cancer cell lines is associated with mismatch repair deficiency.Genomic and biological characterization of exon 4 KRAS mutations in human cancerAnalysis of P53 mutations and their expression in 56 colorectal cancer cell lines.The Caco-2 cell line as a model of the intestinal barrier: influence of cell and culture-related factors on Caco-2 cell functional characteristics.Subtypes of primary colorectal tumors correlate with response to targeted treatment in colorectal cell linesIdentification by Real-time PCR of 13 mature microRNAs differentially expressed in colorectal cancer and non-tumoral tissues.APC mutations in sporadic colorectal tumors: A mutational "hotspot" and interdependence of the "two hits"N-glycosylation Profiling of Colorectal Cancer Cell Lines Reveals Association of Fucosylation with Differentiation and Caudal Type Homebox 1 (CDX1)/Villin mRNA Expression.Cell growth, global phosphotyrosine elevation, and c-Met phosphorylation through Src family kinases in colorectal cancer cellsBeta-catenin mutations in cell lines established from human colorectal cancers.Epigenetic and genetic features of 24 colon cancer cell linesA comprehensive transcriptional portrait of human cancer cell lines.Feasibility of label-free phosphoproteomics and application to base-line signaling of colorectal cancer cell lines.Multi-omics of 34 colorectal cancer cell lines - a resource for biomedical studies.The molecular landscape of colorectal cancer cell lines unveils clinically actionable kinase targets.Colorectal cancer cell lines are representative models of the main molecular subtypes of primary cancer.Identification of a microRNA expression signature for chemoradiosensitivity of colorectal cancer cells, involving miRNAs-320a, -224, -132 and let7g.Permeability characteristics of parental and clonal human intestinal Caco-2 cell lines differentiated in serum-supplemented and serum-free media.Comprehensive galectin fingerprinting in a panel of 61 human tumor cell lines by RT-PCR and its implications for diagnostic and therapeutic procedures.Absence of HeLa cell contamination in 169 cell lines derived from human tumors.Distinction of seventy-one cultured human tumor cell lines by polymorphic enzyme analysis.Presence of glycogen and growth-related variations in 58 cultured human tumor cell lines of various tissue origins.The Proteome of Filter-Grown Caco-2 Cells With a Focus on Proteins Involved in Drug Disposition.Pharmacoproteomic characterisation of human colon and rectal cancer.Human tumor lines for cancer research.Epithelial polarity, villin expression, and enterocytic differentiation of cultured human colon carcinoma cells: a survey of twenty cell lines.Spectral karyotype analysis of colon cancer cell lines of the tumor suppressor and mutator pathway.
P4510
Intestinal Drug Absorption Enhancement by Gel and Whole Leaf Extract: In Vitro Investigations into the Mechanisms of ActionCharacterization of Nanoparticle Intestinal Transport Using an In Vitro Co-Culture ModelImproving Transient Transfection Efficiency in a Differentiated, Polar Epithelial Cell LayerWheat Fermentation With QAUSD01 and QAUWA03 Consortia Induces Concurrent Gliadin and Phytic Acid Degradation and Inhibits Gliadin Toxicity in Caco-2 MonolayersDual Action of the PN159/KLAL/MAP Peptide: Increase of Drug Penetration across Caco-2 Intestinal Barrier Model by Modulation of Tight Junctions and Plasma Membrane PermeabilityLipolysis-Permeation Setup for Simultaneous Study of Digestion and Absorption in VitroEffects of Roxb. and L. in an In Vitro Intestinal Inflammation Model Using Immune Cells and Caco-2Directional entry and release of Zika virus from polarized epithelial cells
P921
Q54808117-904C3174-987E-45F5-8762-454830864453Q54808118-A1694DB6-73FD-42FC-9CF5-2DD8704CAE6EQ54808319-9E8A4F50-D589-41C3-9500-6CE42DDF3C40Q54808322-47C6BD49-BD0D-42D2-9738-57230F74DD70Q54808323-A3EA7C15-FF10-400F-8D0B-76856ACA58C5Q54808325-9257027E-B29E-47FC-8E0E-D4F746B0657DQ54808326-C25A01AB-CE3D-43C6-A045-127FA3884B13Q54808327-3DA41265-95E3-41D7-84EF-92F42D74A7F8Q54808328-8D26DC9A-DD78-42E8-A21F-E72622740880Q93441262-9D3DA855-E6B7-4D0E-940E-CFF12A07CB43Q93441263-A52725BA-0C43-41D7-AFFF-4B15DB207E5B
P3432
Q28292904-64F0A78F-48B7-4934-B9F4-CEABB379B2E1Q28294341-86D96C46-45EA-4A2B-86AA-F13619C070CBQ33882864-5691F0F0-3651-4915-96B4-420513DC8DD0Q33884941-72340698-09BE-4C1A-A808-D2024871859CQ34059750-0FDFEE15-2DC2-4ACD-B58B-5BD4D571E8B9Q34145806-72D39062-6076-405E-92C8-291AD477761DQ34253092-FD387C09-940E-4980-962B-685509AA6D9AQ34415669-28109E59-032D-45D5-9921-2F8CDD1487D8Q34526671-8DE81F9E-BA39-483B-833D-7BE2AB22CCCEQ34997758-F7600647-338B-45C9-A8A7-830EAA24E056Q35110017-A424A5A1-1164-4CEF-A571-806A2AE41D18Q35832746-FA2EC5D4-D816-4B11-A9EA-FAC224846B35Q36497235-E0EE6410-5FB1-41A0-8AE0-067518DC10E0Q36586200-6B1A82A7-E750-415A-AFC5-BFC44BC3B6A7Q37275764-3D8A376F-0A08-4C0F-AB3E-CD2C4BDC11EEQ37854720-D8D38737-0434-4DC1-8C36-EA05EBECB8D0Q38413872-350598C3-F6FB-404F-8064-1CBBEA49A5B2Q38690672-5381DFF0-0CBD-4C51-A832-BC3DB04817D1Q38880745-FC27ECE9-EBAD-46A9-A239-5B03ADB9B4B7Q39001975-010119CB-E4EB-495C-818A-3EBBF9715FB3Q39112884-E47E0949-85A3-40F0-B56C-6799BC3E0C6BQ40619870-50A6CE57-090B-4460-83FA-59EA62054526Q40797947-55F5D78C-A31F-40C9-A963-1884983861E3Q41761715-3E710470-E78E-4121-9F25-15B622A2E3ADQ42799986-4FE38C54-7B57-447B-83B8-6F0BD4702FF8Q42802468-EE12E6ED-8938-495A-9F40-3DB9420FA36FQ42828712-01D8473A-37CA-4D86-B0CC-4C8C7AF36B19Q47205259-52941E5C-61F6-40BE-9F49-E56B82A8D3A0Q52826141-E0C0E8EC-C96D-4D1E-958E-A1436C2E1C38Q52826934-C94F7E65-1721-4C1C-A0CC-62CA91BF7845Q52828450-06FA0757-379F-4202-A0BC-D7EEBBFB0F36
P4510
Q61813723-12E77DAA-B3C4-48D9-8FB9-9A68B69BC2E4Q61815515-F469DDC9-1AB8-44D8-B746-1D206F8802F5Q64100706-470087C2-2D9D-4F2B-8793-4576FE6DE082Q64234796-BB98E532-B911-46FD-AF6B-4A700C3AE781Q64252527-E71FC338-EE4D-46B7-8C62-48674740663CQ64283355-6CD8158C-9A6B-48A4-AF1E-921223C41EB8Q64460344-FC9BB629-FFBC-4FD7-9531-6097A1151434Q66678719-14F3CDE4-422A-4613-B4DE-3D83AAE1C9BA
P921
description
Zelllinie
@de
ceall-líne
@ga
cell line
@en
cellijn van een Homo sapiens
@nl
lignée cellulaire
@fr
name
Caco-2
@de
Caco-2
@en
Caco-2
@fr
Caco-2
@ga
Caco-2
@nl
Caco-2
@ru
Caco-2細胞
@zh
Cèl·lules Caco-2
@ca
Células Caco-2
@gl
type
label
Caco-2
@de
Caco-2
@en
Caco-2
@fr
Caco-2
@ga
Caco-2
@nl
Caco-2
@ru
Caco-2細胞
@zh
Cèl·lules Caco-2
@ca
Células Caco-2
@gl
altLabel
CACO2
@en
CaCo-2
@en
Caco 2
@en
Caco-2/ATCC
@en
prefLabel
Caco-2
@de
Caco-2
@en
Caco-2
@fr
Caco-2
@ga
Caco-2
@nl
Caco-2
@ru
Caco-2細胞
@zh
Cèl·lules Caco-2
@ca
Células Caco-2
@gl
P1343
P2888
P486
P6366
P1343
P3289
P373
Caco-2 cells