p38(MAPK): stress responses from molecular mechanisms to therapeutics.
about
The Role of p38 MAPK in the Development of Diabetic CardiomyopathyDietary phytochemicals and neuro-inflammaging: from mechanistic insights to translational challengesThe Innate Immune System in Acute and Chronic WoundsThe role of p38 MAPK in the aetiopathogenesis of psoriasis and psoriatic arthritisReduced parasite motility and micronemal protein secretion by a p38 MAPK inhibitor leads to a severe impairment of cell invasion by the apicomplexan parasite Eimeria tenellaA-kinase anchoring protein (AKAP)-Lbc anchors a PKN-based signaling complex involved in α1-adrenergic receptor-induced p38 activationp38α MAPK is required for arsenic-induced cell transformationRedox homeostasis: the linchpin in stem cell self-renewal and differentiationSynergistic cooperation between methamphetamine and HIV-1 gsp120 through the P13K/Akt pathway induces IL-6 but not IL-8 expression in astrocytesT-LAK cell-originated protein kinase (TOPK) phosphorylation of MKP1 protein prevents solar ultraviolet light-induced inflammation through inhibition of the p38 protein signaling pathwayComprehensive logic based analyses of Toll-like receptor 4 signal transduction pathwayReduction of tendon adhesions following administration of Adaprev, a hypertonic solution of mannose-6-phosphate: mechanism of action studiesThe Genetic Architecture of Murine Glutathione TransferasesO-linked β-N-acetylglucosamine supports p38 MAPK activation by high glucose in glomerular mesangial cellsExaggerated effects of particulate matter air pollution in genetic type II diabetes mellitus.Dual roles of extracellular signal-regulated kinase (ERK) in quinoline compound BPIQ-induced apoptosis and anti-migration of human non-small cell lung cancer cellsNoise induced changes in the expression of p38/MAPK signaling proteins in the sensory epithelium of the inner ear.P38 mitogen-activated protein kinase activity is required during mitosis for timely satisfaction of the mitotic checkpoint but not for the fidelity of chromosome segregation.Hepatic nonparenchymal cells drive metastatic breast cancer outgrowth and partial epithelial to mesenchymal transitionDownregulation of P38 phosphorylation correlates with low-grade differentiation and proliferation of lung squamous cell carcinoma.Interplay between Mdm2 and HIPK2 in the DNA damage response.Increased miR-424-5p expression in peripheral blood mononuclear cells from patients with pemphigusKnowledge-driven binning approach for rare variant association analysis: application to neuroimaging biomarkers in Alzheimer's diseasep38 MAPK regulates steroidogenesis through transcriptional repression of STAR geneParkinson's disease: insights from pathways.Fish Scale Collagen Peptides Protect against CoCl2/TNF-α-Induced Cytotoxicity and Inflammation via Inhibition of ROS, MAPK, and NF-κB Pathways in HaCaT CellsModeling the TNFα-induced apoptosis pathway in hepatocytes.p38 mediates mechanical allodynia in a mouse model of type 2 diabetes.Deficiency of CC chemokine ligand 2 and decay-accelerating factor causes retinal degeneration in miceA Comprehensive Review of Dysregulated miRNAs Involved in Cervical Cancer.Fenretinide-dependent upregulation of death receptors through ASK1 and p38α enhances death receptor ligand-induced cell death in Ewing's sarcoma family of tumours.Drosophila heat shock response requires the JNK pathway and phosphorylation of mixed lineage kinase at a conserved serine-proline motif.NFκB in the development of endothelial activation and damage in uremia: an in vitro approach13-acetoxysarcocrassolide induces apoptosis on human gastric carcinoma cells through mitochondria-related apoptotic pathways: p38/JNK activation and PI3K/AKT suppressionSelective JAK inhibitors in development for rheumatoid arthritis.TLR and TNF-R1 activation of the MKK3/MKK6-p38α axis in macrophages is mediated by TPL-2 kinase.7-ketocholesterol-induced inflammation: involvement of multiple kinase signaling pathways via NFκB but independently of reactive oxygen species formationTranscriptional analysis reveals gender-specific changes in the aging of the human immune system.Apigenin induces the apoptosis and regulates MAPK signaling pathways in mouse macrophage ANA-1 cells.Profiling hepatic microRNAs in zebrafish: fluoxetine exposure mimics a fasting response that targets AMP-activated protein kinase (AMPK)
P2860
Q26744743-0C39173F-93D2-42E4-8719-C2C3A4A63DE3Q26747783-C14C67B0-E637-4CBD-B1B6-7508CE9F8543Q26767062-947B8E40-23C0-492C-8A42-F4485CB59BF8Q26821943-FCEF507F-B445-4A28-92C7-D87E3BDAC785Q27317304-2E125428-3203-44A0-8B50-5AC6C3EBCCE8Q28115053-A8ECFD66-EDE7-4ED3-8CE4-79165AB56977Q28393791-B282244A-2B32-41E3-9DDC-590BFC5469E3Q28396335-07A09B92-FFF7-4D5F-B80E-31E9488DDDE8Q28484371-99C91149-3DA6-420F-9928-328F7C26FE24Q28513822-9F9CDC78-BB6D-44D0-A244-C1B400D5C5AEQ28541905-91DF37E5-B20B-4520-83E2-8983992BFC8BQ28544839-44CE1CC7-0C3D-4873-BEAA-93F069D46B38Q28553004-F935C43B-D123-4886-85E6-229C296AE91FQ28569862-8F3C4F66-B501-469B-9756-CA7F3E52A581Q28658604-52D2A9F4-971C-4DE5-8C70-77D60AA1097CQ29248583-6CD908FE-C295-4B40-986E-E5AF3ECD6563Q30459756-90D7C7B1-BD02-41BE-B00D-A040D6C53F30Q30495197-AEF99BDD-EE28-4758-AF3F-94D50C12573BQ33565909-AD779B87-A42D-48AF-972B-F6BC64A198B5Q33623190-908A1509-7276-4C45-A329-601C0D3F7BBBQ33656086-8ED54F08-AE1E-4CAB-A331-BA223F0C9FF1Q33702474-17880A82-AF31-4C08-833E-E513EDAA4177Q33726449-C1900E5B-88CF-4743-83EF-1D4F07E0C58AQ33831721-889BA2B3-F256-47DF-9C5F-F572843C2EC9Q33871291-22049E26-7D11-4939-8682-A8795E76BE40Q33876621-4EDF7EC0-DA59-4EF7-9BC4-80BB93747F3DQ33886203-00D8C323-5D97-459C-9999-9F6B06A89DF7Q33895067-03B901C7-F9AF-4D1F-936C-08D4BE949E08Q33902247-2E360AF6-302E-4889-9B28-9BDF906A00E9Q34049716-7D76D277-4BE0-435B-8D55-C2473E8081A9Q34344093-A782A783-BD81-45F0-95CC-010812D57929Q34359747-302AA6EE-E119-4083-913F-CEFB758C1570Q34399116-056A8495-E54C-4F94-BA34-1B1EBA8A82A7Q34411580-CBF20620-326B-4F3E-8C53-751938C2922BQ34419615-B4605B9D-E7EC-43A8-BC18-B347A5E05E68Q34533855-52B49E3E-5E9D-4E97-993C-A9AA485772E5Q34735445-14F2FA05-B3DA-4160-A1FF-69B0BFCE384CQ34776449-15573E29-7D79-485F-87DC-1D15A7241A6BQ35124996-19B88665-27B4-478F-83D9-5734B2D1B07CQ35154001-E848B47F-0D03-422B-A01B-14D177D80AFD
P2860
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 06 August 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en-gb
type
label
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en-gb
prefLabel
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en-gb
P2093
P2860
P1476
p38(MAPK): stress responses from molecular mechanisms to therapeutics.
@en
P2093
Danielle E White
Dominic L Jones
Lydia R Coulthard
Susan A Burchill
P2860
P304
P356
10.1016/J.MOLMED.2009.06.005
P577
2009-08-06T00:00:00Z