Genomic and proteomic profiling of responses to toxic metals in human lung cells.
about
sameAs
Arsenic exposure is associated with decreased DNA repair in vitro and in individuals exposed to drinking water arsenicDiscrimination of vanadium from zinc using gene profiling in human bronchial epithelial cells.Discriminating different classes of toxicants by transcript profilingRenal toxicogenomic response to chronic uranyl nitrate insult in mice.Recent applications of DNA microarray technology to toxicology and ecotoxicologyHuman AP endonuclease 1: a potential marker for the prediction of environmental carcinogenesis riskCytogenomics of hexavalent chromium (Cr 6+) exposed cells: a comprehensive reviewChromium genotoxicity: A double-edged swordArsenic as an endocrine disruptor: arsenic disrupts retinoic acid receptor-and thyroid hormone receptor-mediated gene regulation and thyroid hormone-mediated amphibian tail metamorphosisPerturbation of defense pathways by low-dose arsenic exposure in zebrafish embryosExit from arsenite-induced mitotic arrest is p53 dependentA Comparative Study of Selected Trace Element Content in Malay and Chinese Traditional Herbal Medicine (THM) Using an Inductively Coupled Plasma-Mass Spectrometer (ICP-MS)Gene 33/Mig6 inhibits hexavalent chromium-induced DNA damage and cell transformation in human lung epithelial cellsPharmacokinetic and Genomic Effects of Arsenite in Drinking Water on Mouse Lung in a 30-Day ExposureInduction of heme oxygenase 1 by arsenite inhibits cytokine-induced monocyte adhesion to human endothelial cellsCulture conditions profoundly impact phenotype in BEAS-2B, a human pulmonary epithelial modelRelation of dietary inorganic arsenic to serum matrix metalloproteinase-9 (MMP-9) at different threshold concentrations of tap water arsenicGlobal transcriptome and deletome profiles of yeast exposed to transition metalsCadmium triggers an integrated reprogramming of the metabolism of Synechocystis PCC6803, under the control of the Slr1738 regulatorGenomic and genotoxic responses to controlled weathered-oil exposures confirm and extend field studies on impacts of the Deepwater Horizon oil spill on native killifish.Identification of arsenic-binding proteins in human breast cancer cellsGlobal gene expression profiling in human lung cells exposed to cobalt.Gene response profiles for Daphnia pulex exposed to the environmental stressor cadmium reveals novel crustacean metallothioneinsTungsten carbide cobalt nanoparticles exert hypoxia-like effects on the gene expression level in human keratinocytes.Comparison of gene expression profiles in chromate transformed BEAS-2B cellsComparative genomic analyses identify common molecular pathways modulated upon exposure to low doses of arsenic and cadmiumImprinted genes and the environment: links to the toxic metals arsenic, cadmium, lead and mercury.Cadmium induces transcription independently of intracellular calcium mobilization.Dose-responsive gene expression changes in juvenile and adult mummichogs (Fundulus heteroclitus) after arsenic exposureBehavioural and physiological responses of Gammarus pulex exposed to cadmium and arsenate at three temperatures: individual and combined effects.Acquisition of temozolomide chemoresistance in gliomas leads to remodeling of mitochondrial electron transport chainThe NRF2-KEAP1 pathway is an early responsive gene network in arsenic exposed lymphoblastoid cells.Low-dose arsenic induces chemotherapy protection via p53/NF-κB-mediated metabolic regulation.p53-Based Strategy for Protection of Bone Marrow From Y-90 Ibritumomab Tiuxetan.Differential response of Mono Mac 6, BEAS-2B, and Jurkat cells to indoor dust.Arsenic promotes ubiquitinylation and lysosomal degradation of cystic fibrosis transmembrane conductance regulator (CFTR) chloride channels in human airway epithelial cellsReduction of hexavalent chromium by human cytochrome b5: generation of hydroxyl radical and superoxidep53-based strategy to reduce hematological toxicity of chemotherapy: A proof of principle study.Resistance to apoptosis, increased growth potential, and altered gene expression in cells that survived genotoxic hexavalent chromium [Cr(VI)] exposure.Interleukin 5 is protective during sepsis in an eosinophil-independent manner.
P2860
Q23909922-AB057A8A-3E79-47C6-901F-A7A12086AC42Q24811778-95ECF893-A0F2-429F-A715-6B46EFAD31A6Q24813403-0A325F65-1448-49C0-840F-38E610F96262Q24816541-8C292134-F5A4-4075-A35D-5F73F5A7E29AQ25256581-E5EEFC23-C712-492F-878E-0ECA70B932C9Q26863138-ADC511EE-9BA6-4571-A978-471771976548Q26991939-1AC094D4-DEFE-4F7C-AFD4-2BB2070510E6Q28383439-30FE3FF8-B273-4465-BE58-F515B88C464BQ28383459-755F3582-5B6D-4BA1-A797-1D8819BD2CFDQ28389519-ABCAEDFC-497E-4199-BBE5-26938B8DC5D0Q28391168-CDC4503D-7EF0-4CD8-B438-8C568A1E1A92Q28395177-E05AF852-AAB2-4B70-9D07-8D6046F5B157Q28395858-C8400846-DC9A-4A93-8899-0E6D639C5B1EQ28395923-4942C711-9713-4D73-9892-45C54D43F0BFQ28396592-78C784B6-71B9-4862-89FE-65E129CC055BQ28396792-58E59454-E6E4-4AF8-92E8-FEC837746D34Q28397998-2469BA37-6F17-4526-B1E7-F1C785065205Q28472521-C61F6124-A2CE-4FB3-9817-8522C4F5082CQ28755989-A3A419FA-0D7E-4B33-BFBC-DCBB59B9E331Q30430977-880A80E6-B331-4978-AC32-522602E67308Q30831628-D519C925-D415-451A-A380-AD2332E6AE8BQ33286948-BE534E4B-7851-49C6-860E-5C20A2978641Q33312105-5AC4E4BB-2CC3-4CEC-AF39-79663266B9A1Q33526842-DA93B744-17E3-4895-A2EE-30631B02B16BQ33855548-366CCC91-30E8-4D9B-ACD5-B8936EE62817Q33860486-5470439E-A40A-4EE7-9F3F-7617A8CE0640Q33891724-D2CD9801-9B67-4D5F-A317-CD3895D95346Q33939105-DDD81FFF-3399-48C1-BA37-98C510449CEAQ33976810-CDF3F21F-643E-48DF-B829-51839EE0802AQ34325889-D39964F4-E41A-4AEA-8AD7-008B4B9E00A9Q34400848-072F8A16-4D04-48F3-A647-3442BE464AFAQ35091522-62DA5858-A1BE-4085-8EFE-B6C1196B4591Q35743688-A8EC6F97-9291-4D54-A393-450275941A18Q35875618-B5A18E22-CF81-4521-831F-C29827BCA81EQ35971799-F6D3C38A-5357-40FC-A75A-283F51E2A6B5Q36006901-FCD000A1-90FB-4E25-A49D-867CC6A43E9FQ36012143-7728D074-EF4E-4D7D-9865-BC0F7A53EB8CQ36134524-5097D20E-A3C6-45DA-B4D1-46E0A54D50D9Q36147392-F98B5201-C33C-44DA-A01B-A652A7EADD97Q36176895-414E01F7-E1DB-4C5C-A858-EA97E17FA05A
P2860
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
description
2003 nî lūn-bûn
@nan
2003 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Genomic and proteomic profiling of responses to toxic metals in human lung cells
@nl
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@ast
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@en
type
label
Genomic and proteomic profiling of responses to toxic metals in human lung cells
@nl
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@ast
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@en
prefLabel
Genomic and proteomic profiling of responses to toxic metals in human lung cells
@nl
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@ast
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@en
P2093
P2860
P356
P1476
Genomic and proteomic profiling of responses to toxic metals in human lung cells.
@en
P2093
Amy J Warren
Angeline S Andrew
Joshua W Hamilton
Kaili A Temple
Kimberley A O'Hara
Linda Klei
Nicole V Soucy
P2860
P304
P356
10.1289/EHP.111-1241504
P407
P577
2003-05-01T00:00:00Z