Arsenic-specific stem cell selection during malignant transformation.
about
Carcinogenic effects of "whole-life" exposure to inorganic arsenic in CD1 miceArsenic Disruption of DNA Damage Responses-Potential Role in Carcinogenesis and ChemotherapyEMT and stem cell-like properties associated with HIF-2α are involved in arsenite-induced transformation of human bronchial epithelial cellsEDC-2: The Endocrine Society's Second Scientific Statement on Endocrine-Disrupting ChemicalsArsenic-induced sub-lethal stress reprograms human bronchial epithelial cells to CD61¯ cancer stem cellsArsenic transformation predisposes human skin keratinocytes to UV-induced DNA damage yet enhances their survival apparently by diminishing oxidant responseChronic inorganic arsenic exposure in vitro induces a cancer cell phenotype in human peripheral lung epithelial cellsOverabundance of putative cancer stem cells in human skin keratinocyte cells malignantly transformed by arsenicMethylarsonous acid causes oxidative DNA damage in cells independent of the ability to biomethylate inorganic arsenicPrenatal arsenic exposure alters gene expression in the adult liver to a proinflammatory state contributing to accelerated atherosclerosisEarly life inorganic lead exposure induces testicular teratoma and renal and urinary bladder preneoplasia in adult metallothionein-knockout mice but not in wild type mice.Targeting miRNAs involved in cancer stem cell and EMT regulation: An emerging concept in overcoming drug resistance.Arsenic, stem cells, and the developmental basis of adult cancer.P38/NF-κB/snail pathway is involved in caffeic acid-induced inhibition of cancer stem cells-like properties and migratory capacity in malignant human keratinocyte.Arsenic immunotoxicity: a review.Multiple drug resistance due to resistance to stem cells and stem cell treatment progress in cancer (Review).Side populations from cervical-cancer-derived cell lines have stem-cell-like properties.Clonogenicity: holoclones and meroclones contain stem cellsEnrichment of Human Stem-Like Prostate Cells with s-SHIP Promoter Activity Uncovers a Role in Stemness for the Long Noncoding RNA H19.Arsenic toxicology: translating between experimental models and human pathology.Global gene expression changes in human urothelial cells exposed to low-level monomethylarsonous acid.Differential DNA methylation profile of key genes in malignant prostate epithelial cells transformed by inorganic arsenic or cadmiumCross-regulations among NRFs and KEAP1 and effects of their silencing on arsenic-induced antioxidant response and cytotoxicity in human keratinocytesArsenic-transformed malignant prostate epithelia can convert noncontiguous normal stem cells into an oncogenic phenotype.Regulatory role of KEAP1 and NRF2 in PPARγ expression and chemoresistance in human non-small-cell lung carcinoma cells.Chronic cadmium exposure in vitro causes acquisition of multiple tumor cell characteristics in human pancreatic epithelial cells.Mechanisms Underlying Latent Disease Risk Associated with Early-Life Arsenic Exposure: Current Research Trends and Scientific Gaps.Hedgehog pathway is involved in nitidine chloride induced inhibition of epithelial-mesenchymal transition and cancer stem cells-like properties in breast cancer cellsDeconstructing the mechanisms and consequences of TGF-β-induced EMT during cancer progression.Recruitment of normal stem cells to an oncogenic phenotype by noncontiguous carcinogen-transformed epithelia depends on the transforming carcinogen.Inorganic Arsenic-Related Changes in the Stromal Tumor Microenvironment in a Prostate Cancer Cell-Conditioned Media Model.Chronic exposure of renal stem cells to inorganic arsenic induces a cancer phenotype.Aberrant microRNA expression likely controls RAS oncogene activation during malignant transformation of human prostate epithelial and stem cells by arsenic.Drug treatment of cancer cell lines: a way to select for cancer stem cells?MicroRNAs and drug resistance in prostate cancers.Mitigation of arsenic-induced acquired cancer phenotype in prostate cancer stem cells by miR-143 restoration.Chronic oxidative stress leads to malignant transformation along with acquisition of stem cell characteristics, and epithelial to mesenchymal transition in human renal epithelial cells.Oxidative DNA damage after acute exposure to arsenite and monomethylarsonous acid in biomethylation-deficient human cells.EMT and CSC-like properties mediated by the IKKβ/IκBα/RelA signal pathway via the transcriptional regulator, Snail, are involved in the arsenite-induced neoplastic transformation of human keratinocytes.A systematic approach to cancer: evolution beyond selection
P2860
Q24707869-AFED0C22-4252-488B-9AA1-D64B551BFBA2Q26781256-45BFE8DE-0727-4F38-BFF2-6533DB20BD64Q27302204-B0602FE0-C0F5-4775-96C8-8A92C799C0F8Q28383132-67BE4CC2-DE1E-4A8F-8EAD-89E85E701A85Q28385362-5D5D499E-DD99-4BFB-BC0B-1A124581F1DAQ28391764-01F6CDF7-324C-425A-907C-9C140AC8982AQ28394865-7098FEF5-93D6-4245-8E38-156AB095DB44Q28394988-57ED3994-726A-4B14-B9A5-BC674B29C784Q28397241-9EB37C1F-EFBD-4449-81FE-9948EB986A64Q28728378-B816E08E-55B7-4B30-B873-33693A3FAC62Q34180578-2C00A0F6-97A4-4DB0-A43B-B7C31A07C9EDQ34208986-FE6E3139-B333-45AC-9DCF-01B5D1E55A2EQ34593837-D50C4844-0BF6-4374-A386-0564DBFCB4AFQ34630179-5DA8552C-C141-495E-887F-C44C922637F6Q34655901-A86DA5FA-D43A-4879-9EFE-C34AA1960D43Q34795591-5269E2CF-D727-48FB-A472-05713207220FQ35085092-07054657-1383-4849-ABF9-6EE6D944B9BDQ35108180-39322249-79C4-4B80-9D36-86D52D66800FQ35586185-90D76CD7-3962-4B8F-9135-09AE45D233B2Q35591935-2663FAAD-A611-4087-A5B9-56B012B3FCCDQ35633033-26587B1A-93C8-4840-9B53-C4CCB074AA59Q35706402-5476CE60-61DA-4943-AED4-736CABD5D79FQ35920278-1BEB972D-B692-4C65-9492-9F582954C46FQ36064793-D7CC70BB-571B-43D3-B0AB-437DA245E394Q36162095-8A10FF37-59DA-4FF8-AFAA-AA5300C02BA9Q36229244-92F7B7CD-064C-40EC-B83D-9684274D5AC1Q36567337-A3648ADB-EA1E-4587-9C54-10E9B2C6B033Q37010958-72099509-74A7-42ED-9FDC-F94AC9799070Q37044614-C8645701-F645-40F7-8272-9DB9886973A0Q37072641-E74FD8DB-FEDA-4510-89D9-7EBCC482473DQ37077753-433CCA6D-FA56-4F69-A2B9-2E87AF15F7CFQ37579448-5619A32C-D656-46A6-9CEC-BCA703FB3263Q37669900-0E7BCB9E-73AD-49C1-B85E-915DCB734A6CQ38161343-537418F4-4047-4737-8C12-3902720A115EQ38205266-C5DB1309-F31D-422D-8801-9EC6359CD522Q38807462-639E148E-EFCB-4A16-B253-1E9EF3E4E8B9Q38924677-ACD2BCC8-81C7-42E5-9A2E-1B59FD440273Q39213570-0FEF07BA-C9DF-4704-A640-8A73D3A9527DQ39258711-78B0E7C5-289E-4EA7-9CCF-189BDB6ED671Q40629103-1FFCD644-700A-4DC9-A643-6DBA45ECC0E7
P2860
Arsenic-specific stem cell selection during malignant transformation.
description
2010 nî lūn-bûn
@nan
2010 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի մարտին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Arsenic-specific stem cell selection during malignant transformation.
@ast
Arsenic-specific stem cell selection during malignant transformation.
@en
type
label
Arsenic-specific stem cell selection during malignant transformation.
@ast
Arsenic-specific stem cell selection during malignant transformation.
@en
prefLabel
Arsenic-specific stem cell selection during malignant transformation.
@ast
Arsenic-specific stem cell selection during malignant transformation.
@en
P2093
P2860
P356
P1476
Arsenic-specific stem cell selection during malignant transformation.
@en
P2093
Erik J Tokar
James M Phang
Michael P Waalkes
Mukta M Webber
P2860
P304
P356
10.1093/JNCI/DJQ093
P407
P577
2010-03-25T00:00:00Z