Master and commander in fungal pathogens: the two-component system and the HOG signaling pathway.
about
Genome sequencing of four Aureobasidium pullulans varieties: biotechnological potential, stress tolerance, and description of new speciesIdentical phosphatase mechanisms achieved through distinct modes of binding phosphoprotein substrateHog1 mitogen-activated protein kinase (MAPK) interrupts signal transduction between the Kss1 MAPK and the Tec1 transcription factor to maintain pathway specificity.Phenylpyrroles: 30 Years, Two Molecules and (Nearly) No ResistanceHrk1 plays both Hog1-dependent and -independent roles in controlling stress response and antifungal drug resistance in Cryptococcus neoformansReconstruction of the High-Osmolarity Glycerol (HOG) Signaling Pathway from the Halophilic Fungus Wallemia ichthyophaga in Saccharomyces cerevisiaeSte50 adaptor protein governs sexual differentiation of Cryptococcus neoformans via the pheromone-response MAPK signaling pathwayA novel family of dehydrin-like proteins is involved in stress response in the human fungal pathogen Aspergillus fumigatus.Differential role of HAMP-like linkers in regulating the functionality of the group III histidine kinase DhNik1p.Comparative transcriptome analysis reveals novel roles of the Ras and cyclic AMP signaling pathways in environmental stress response and antifungal drug sensitivity in Cryptococcus neoformans.Distinct and redundant roles of protein tyrosine phosphatases Ptp1 and Ptp2 in governing the differentiation and pathogenicity of Cryptococcus neoformans.A Ferroxidase, Cfo1, Regulates Diverse Environmental Stress Responses of Cryptococcus neoformans through the HOG PathwayA split-ubiquitin two-hybrid screen for proteins physically interacting with the yeast amino acid transceptor Gap1 and ammonium transceptor Mep2.Cryptococcus neoformans histone acetyltransferase Gcn5 regulates fungal adaptation to the hostEvolution and phyletic distribution of two-component signal transduction systems.Regulatory circuitry governing fungal development, drug resistance, and disease.The two-component sensor kinase TcsC and its role in stress resistance of the human-pathogenic mold Aspergillus fumigatus.Pleiotropic effects of deubiquitinating enzyme Ubp5 on growth and pathogenesis of Cryptococcus neoformans.Histidine kinase two-component response regulator proteins regulate reproductive development, virulence, and stress responses of the fungal cereal pathogens Cochliobolus heterostrophus and Gibberella zeae.Analysis of mitogen-activated protein kinase phosphorylation in response to stimulation of histidine kinase signaling pathways in Neurospora.Strategies for Wheat Stripe Rust Pathogenicity Identified by Transcriptome SequencingNikA/TcsC histidine kinase is involved in conidiation, hyphal morphology, and responses to osmotic stress and antifungal chemicals in Aspergillus fumigatus.Multiple roles of Ypd1 phosphotransfer protein in viability, stress response, and virulence factor regulation in Cryptococcus neoformans.Candida albicans SRR1, a putative two-component response regulator gene, is required for stress adaptation, morphogenesis, and virulenceMitogen-activated protein kinase Hog1 is activated in response to curcumin exposure in the budding yeast Saccharomyces cerevisiae.The Aspergillus fumigatus sitA Phosphatase Homologue Is Important for Adhesion, Cell Wall Integrity, Biofilm Formation, and Virulence.A loss-of-function mutation in the PAS kinase Rim15p is related to defective quiescence entry and high fermentation rates of Saccharomyces cerevisiae sake yeast strains.The Genomes of Three Uneven Siblings: Footprints of the Lifestyles of Three Trichoderma Species.Identification of a major IP5 kinase in Cryptococcus neoformans confirms that PP-IP5/IP7, not IP6, is essential for virulenceRegulatory role of glycerol in Candida albicans biofilm formation.Oxidative stress-related transcription factors in the regulation of secondary metabolismGreen fluorescent protein (GFP)-based overexpression screening and characterization of AgrC, a Receptor protein of quorum sensing in Staphylococcus aureusRemodeling of global transcription patterns of Cryptococcus neoformans genes mediated by the stress-activated HOG signaling pathways.Deletion of the HAMP domains from the histidine kinase CaNik1p of Candida albicans or treatment with fungicides activates the MAP kinase Hog1p in S. cerevisiae transformants.Signalling pathways in the pathogenesis of Cryptococcus.Our paths might cross: the role of the fungal cell wall integrity pathway in stress response and cross talk with other stress response pathways.Stress signaling pathways for the pathogenicity of Cryptococcus.The Aspergillus fumigatus SchASCH9 kinase modulates SakAHOG1 MAP kinase activity and it is essential for virulence.Farnesol-induced cell death in the filamentous fungus Aspergillus nidulans.Hog1: 20 years of discovery and impact.
P2860
Q21266647-FD3A0F73-A99C-4C58-86C5-DE3AA25F521CQ27658990-DC2D14F2-C8F0-48A2-AC3B-4A2F9B6D482FQ27933210-154192C1-DB7B-4F48-9BD3-8BC81FFEFCEBQ28079158-7D1D2C04-3D64-4ABD-B952-9A9CB8AE5994Q28477751-FB5441F8-F364-45EF-B5E0-7FC12B793649Q30008896-4BAD0A7F-11D6-412D-8805-AA93AA5D7086Q30155982-35B0E5E1-47A7-44D9-9719-47E23529F578Q30500619-916784D0-E8DA-4677-A024-CE305A6AB123Q33578438-64412EBE-7B09-44EE-8A0F-60D2AA12AEF2Q33725233-026AB083-DE08-4B5F-BE22-AB31576453CAQ33743558-9C9E4957-4E29-49DC-B00A-D07BD410794EQ33955520-606863BE-FF53-4641-8D32-E63A35F347A3Q34017899-28EAE8B5-EC8B-4652-B9B7-A66D87D7F8D1Q34055174-3AEDAE32-A0A5-4F78-85F9-EDA87D20E571Q34096988-D2E73D70-85DB-4011-9F40-2E7A35E362BCQ34190284-56DC8309-61DC-4FB4-971C-AD7EFCAC2AEAQ34295783-176E53E5-4F89-4DD7-AA7A-B3B202A38E63Q34311864-DF29434C-D55F-474F-8C59-5D85C325CA2CQ34432283-5C8B9970-25C1-48E3-8B7D-0FFD6A285119Q34785015-E5BD0B33-8776-4100-B4FF-C62CC8FB2D50Q34806548-E4ED5160-2679-43D4-81A8-B9E2734BF58FQ35061130-75662F9C-866A-476D-B991-6EEFD69D456DQ35138958-4F988676-5734-4D9C-841B-EF533EA0842CQ35271366-24138ACC-F5DD-4546-A73C-28F495209A09Q35530251-59C87922-5BFD-4A40-950A-4FFC23F61014Q35902085-CF9D9D6A-82FD-4E92-AE8A-27D5252C77C7Q35940857-021DA81E-6600-415C-9FAE-A3AA732E0909Q36631422-B8CCF726-91C8-4944-8845-FE541E1A50E3Q36754718-C18DE43F-36BD-4413-86CA-92824585E7EBQ36756638-F71D58CE-DED5-427C-B137-5205CCEC33EBQ36993905-70489CAB-143A-40EA-8E48-48911B487681Q37225171-74F7F081-7D11-4023-9C10-2B9F603B62ACQ37301922-066E4B05-C569-462A-94EF-FBEC0F426F90Q37359653-2168C67A-0F8F-4B04-841B-73F363B5A22EQ37377961-D9483FE6-0369-4F1D-BF67-62F05546BB21Q37410110-5DC721F5-7F0D-4D46-912F-293A0C922C63Q37469570-79E06353-B0EC-4A55-AC8B-658590D17CF9Q37551507-1CC59C14-11D2-4E5B-A454-0DFE9E209B2CQ37936574-62683EF6-6EF0-410C-ABCE-35CF5B003279Q38250197-998D422D-24A6-48A6-A48C-5B7FD15EB471
P2860
Master and commander in fungal pathogens: the two-component system and the HOG signaling pathway.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
Master and commander in fungal ...... and the HOG signaling pathway.
@en
type
label
Master and commander in fungal ...... and the HOG signaling pathway.
@en
prefLabel
Master and commander in fungal ...... and the HOG signaling pathway.
@en
P2860
P356
P1433
P1476
Master and commander in fungal ...... and the HOG signaling pathway.
@en
P2860
P304
P356
10.1128/EC.00323-08
P577
2008-10-24T00:00:00Z