Normal adaptation of Candida albicans to the murine gastrointestinal tract requires Efg1p-dependent regulation of metabolic and host defense genes.
about
Genetic and phenotypic intra-species variation in Candida albicansThe trans-kingdom identification of negative regulators of pathogen hypervirulenceMicroevolution of Candida albicans in macrophages restores filamentation in a nonfilamentous mutantPhenotypic Profiling Reveals that Candida albicans Opaque Cells Represent a Metabolically Specialized Cell State Compared to Default White CellsAge and Gender Affect the Composition of Fungal Population of the Human Gastrointestinal TractCandida albicans Niche Specialization: Features That Distinguish Biofilm Cells from Commensal Cells.Mitochondrial complex I bridges a connection between regulation of carbon flexibility and gastrointestinal commensalism in the human fungal pathogen Candida albicansIron-responsive chromatin remodelling and MAPK signalling enhance adhesion in Candida albicans.Candida albicans commensalism in the gastrointestinal tract.Candida albicans commensalism and pathogenicity are intertwined traits directed by a tightly knit transcriptional regulatory circuitMetabolism in fungal pathogenesis.Regulatory circuits that enable proliferation of the fungus Candida albicans in a mammalian hostA novel antifungal is active against Candida albicans biofilms and inhibits mutagenic acetaldehyde production in vitro.Hypoxia and Temperature Regulated Morphogenesis in Candida albicansDistinct stages during colonization of the mouse gastrointestinal tract by Candida albicansFunction and Regulation of Cph2 in Candida albicans.The game theory of Candida albicans colonization dynamics reveals host status-responsive gene expression.Budding off: bringing functional genomics to Candida albicans.Candida albicans: adapting to succeed.Candida albicans, plasticity and pathogenesis.Metabolism impacts upon Candida immunogenicity and pathogenicity at multiple levels.Adaptation of Candida albicans to commensalism in the gut.Ploidy dynamics and evolvability in fungiS. oralis activates the Efg1 filamentation pathway in C. albicans to promote cross-kingdom interactions and mucosal biofilms.Competitive Fitness of Fluconazole-Resistant Clinical Candida albicans Strains.Boric acid destabilizes the hyphal cytoskeleton and inhibits invasive growth of Candida albicans.Inactivation of genes TEC1 and EFG1 in Candida albicans influences extracellular matrix composition and biofilm morphologyCandida albicans FRE8 encodes a member of the NADPH oxidase family that produces a burst of ROS during fungal morphogenesis.The yeast form of the fungus Candida albicans promotes persistence in the gut of gnotobiotic mice.Eukaryotic Cu-only superoxide dismutases (SODs): A new class of SOD enzymes and SOD-like protein domains.The Genomic Landscape of the Fungus-Specific SWI/SNF Complex Subunit, Snf6, in Candida albicans.Hypoxia Promotes Immune Evasion by Triggering β-Glucan Masking on the Candida albicans Cell Surface via Mitochondrial and cAMP-Protein Kinase A SignalingTipping the Balance: Adaptation in Polymicrobial EnvironmentsCandida ImmunityCandida albicans: Clinical Relevance, Pathogenesis, and Host Immunity
P2860
Q21999063-085C5350-06E8-4594-B691-D8BBD8284A66Q26782915-7A66718F-96E5-4CDA-8D70-609BF8A012D5Q28542485-CC4B34CA-F4DD-46D5-AD6F-DD743F24EA74Q28820771-BF541D2C-D8F5-44EB-94A5-467C69B516F2Q28831500-BF1E5E56-A389-44C5-AD2A-6C0760F19484Q33603993-94C1A743-84EF-489B-A63D-0E3867B2D759Q33793655-4C6F1A2A-1B58-4B6D-86EE-83D56BE7A45BQ33934246-87E30C64-4F3C-4EB2-8DAC-CFC2405F2FCAQ34492985-AB189127-B2B6-4FA6-91FD-FE5CD6C33FAEQ34633866-92E6E223-99B8-41BC-9154-E8901FCAF698Q34930405-94F5D816-E7CB-4D03-AA55-884AD3E92296Q35079805-82AFFBBC-A0BF-4EBD-B0F1-FC95D79334C0Q35175064-350FC72E-3516-44DB-99CE-77C177CCD7A8Q35746147-525BB755-B7C7-472A-AFB2-576335297BA2Q35918461-43DEEF1B-24B4-4E74-BCA7-91E78FE5A50CQ36208858-E66E574C-A5C5-443C-A87E-E1169D5F3B3EQ36634086-9BF81394-1976-43B4-BCA2-BCDFCD6B1CDFQ37341557-EBC21192-1668-42C1-A5A5-F14FF9DA3514Q37494781-66996DBF-8737-454C-87CF-B3A7294989D1Q38130314-FB82A148-4FAF-46D0-93CF-2A683432785AQ38236582-4808BF47-A052-476F-A053-541AB39D34A8Q38806236-F320EDF0-29E0-4829-A0F3-331A3C370025Q39084067-9FAA2128-659B-4250-B596-BDC0CF0EF093Q40222061-C43BDE31-7400-4581-B808-4A3B6EAE57B7Q40230670-4E80FBAE-BFE6-4D00-B4F2-5423A0592B14Q41542881-37469271-0838-4780-9BF7-4A61EA105D02Q42681379-51DA8F91-2D52-4253-A2E1-5D0CE70C380EQ46250263-DC2717EC-27DB-4A00-A4EA-2CE0FF3B7102Q47138923-998DCC9D-5EC8-4439-AE03-DA2A296C1724Q47273228-83810845-FD68-4A3F-8EEE-AE217C2248C4Q47388204-DBA194BA-D1DC-49B2-9C05-D69F289772F7Q58607987-FDE810C2-A706-47F8-AE99-9DFDE0B7D183Q58723255-9D165561-90D7-4EBF-BE67-85B0A8D07E1DQ59072636-B0185D44-AEBF-49A9-9854-4F182826F42FQ59282466-A6BBD9B6-3407-4EB5-A213-8E5B16780444
P2860
Normal adaptation of Candida albicans to the murine gastrointestinal tract requires Efg1p-dependent regulation of metabolic and host defense genes.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Normal adaptation of Candida a ...... abolic and host defense genes.
@ast
Normal adaptation of Candida a ...... abolic and host defense genes.
@en
type
label
Normal adaptation of Candida a ...... abolic and host defense genes.
@ast
Normal adaptation of Candida a ...... abolic and host defense genes.
@en
prefLabel
Normal adaptation of Candida a ...... abolic and host defense genes.
@ast
Normal adaptation of Candida a ...... abolic and host defense genes.
@en
P2093
P2860
P356
P1433
P1476
Normal adaptation of Candida a ...... abolic and host defense genes.
@en
P2093
Carol A Kumamoto
Daniel Dignard
Jessica V Pierce
Malcolm Whiteway
P2860
P356
10.1128/EC.00236-12
P577
2012-11-02T00:00:00Z