Model-driven mapping of transcriptional networks reveals the circuitry and dynamics of virulence regulation.
about
cyclin Ctranscriptional repressor NF-X1hepatocyte nuclear factortranscription factorFork head protein homolog 1, putativeFork head protein homolog 1, putativeCMGC/MAPK/P38 protein kinaseRNA polymerase II transcription factorCentromere DNA-binding protein complex CBF3 subunit B, putativeRNA polymerase II transcription factorPre-rRNA-processing protein FHL1, putative
P1343
Networks of fibers and factors: regulation of capsule formation in Cryptococcus neoformansExploiting Fungal Virulence-Regulating Transcription Factors As Novel Antifungal Drug TargetsInvestigating Conservation of the Cell-Cycle-Regulated Transcriptional Program in the Fungal Pathogen, Cryptococcus neoformansIntegrating Transcriptomic and Proteomic Data Using Predictive Regulatory Network Models of Host Response to Pathogens.A novel bZIP protein, Gsb1, is required for oxidative stress response, mating, and virulence in the human pathogen Cryptococcus neoformans.Connecting virulence pathways to cell-cycle progression in the fungal pathogen Cryptococcus neoformansThe cAMP/protein kinase A signaling pathway in pathogenic basidiomycete fungi: Connections with iron homeostasisComputational Analysis Reveals a Key Regulator of Cryptococcal Virulence and Determinant of Host ResponseSystematic functional analysis of kinases in the fungal pathogen Cryptococcus neoformans.Past Roadblocks and New Opportunities in Transcription Factor Network Mapping.Novel Agents and Drug Targets to Meet the Challenges of Resistant Fungi.Cryptococcus neoformans UGT1 encodes a UDP-Galactose/UDP-GalNAc transporter.Regulated release of cryptococcal polysaccharide drives virulence and suppresses immune infiltration into the central nervous system.Transcriptomic Crosstalk between Fungal Invasive Pathogens and Their Host Cells: Opportunities and Challenges for Next-Generation Sequencing Methods.UDP-Glucuronic Acid Transport Is Required for Virulence of Cryptococcus neoformans.Xylose donor transport is critical for fungal virulence.The novel microtubule-associated CAP-glycine protein Cgp1 governs growth, differentiation, and virulence of Cryptococcus neoformans.Unintended Side Effects of Transformation Are Very Rare in Cryptococcus neoformans.HDAC genes play distinct and redundant roles in Cryptococcus neoformans virulence.A unique cytoskeleton-associated protein in Cryptococcus neoformans.Peeling the onion: the outer layers of Cryptococcus neoformans.The Cryptococcus neoformans Titan cell is an inducible and regulated morphotype underlying pathogenesis.Mon1 Is Essential for Fungal Virulence and Stress Survival in Cryptococcus neoformans.
P2860
Q62838391-FC960E35-B8BD-4F48-9BC3-A182D24CB09DQ62852902-D1E2F816-B9EA-4BBD-B9C7-342791C78886Q62858418-3DF39755-878D-4F36-91BD-7A6D05965AFBQ62866264-7A6F7826-1636-446F-971F-912362D4C27DQ62885387-C8E9FF7D-F492-4BFA-9DF0-9B4B954C7FCFQ62885394-DF341D98-7495-4B74-8EA3-781A41A3D49DQ62905794-C49787B5-B00A-45E4-82C8-E4036ABA5BE9Q62915031-F7A595FD-ADA5-439C-8711-C27F0E8A0E3DQ62915109-C8CF0E94-5EA9-4F45-963C-9743E81EF82DQ62919279-6E2ED206-721E-4599-B253-E4A5512839D4Q62920596-80C036E7-EECE-4E60-BD12-4F1C19127FA1
P1343
Q26741771-BC758182-668B-4BB4-85E4-B6A143CBFBA2Q26800255-BB482FD0-3B4D-4017-BF8F-15FA0690A24EQ28589754-0816E037-6257-4DBC-BC7A-354CDD9C6031Q31114011-6AAB3649-941E-4929-936A-07E5622857DDQ33826387-6348DEB5-01AE-4378-9EA3-DE33EFA2FF95Q36299029-59CE09F6-C2D5-4410-9751-9539B18DB501Q36419997-EBCDAE22-67CD-4834-8D6B-EE82221DE884Q36849909-1EFE7935-8701-4375-9C74-70978444CE11Q37315258-9DF38E46-540A-4514-A6E6-339D42A97C3AQ38976283-7961B8C4-AC34-4F0B-A91C-593E1BEFAEC4Q40045666-8C73A554-768F-4669-9AEF-863682865497Q40586172-75CEB139-4C1F-4619-8414-BFE3014FB818Q47370987-8815C975-B60E-4D2D-BB2B-AB30D9F7C4AAQ47706882-2CC3C309-795E-4A46-80CB-2D0BB589F222Q47830888-F79C552E-1873-49F6-9CFB-BB5B13FE5FC1Q48218058-115E8CF4-5594-4FC6-95E3-16F537CA6A56Q48507287-51651025-0C1C-4698-B109-268C67CD2583Q50158602-1A7459CA-3124-4512-8BBB-511C9630E5E9Q51144534-8DC0E871-6069-4A78-B6C0-AE9A007B8C99Q55004020-353D6C78-255F-4B57-BF6A-BFD60974175CQ55056045-5C6D570A-8B85-4B11-91E5-E07CDE293208Q55339940-DF4A1FE6-1798-4793-8161-89BB79ECF26AQ55359867-4522D4F1-1EEC-40BD-9D2F-DE50012CEBFA
P2860
Model-driven mapping of transcriptional networks reveals the circuitry and dynamics of virulence regulation.
description
2015 nî lūn-bûn
@nan
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
2015年论文
@zh
2015年论文
@zh-cn
name
Model-driven mapping of transc ...... amics of virulence regulation.
@ast
Model-driven mapping of transc ...... amics of virulence regulation.
@en
type
label
Model-driven mapping of transc ...... amics of virulence regulation.
@ast
Model-driven mapping of transc ...... amics of virulence regulation.
@en
prefLabel
Model-driven mapping of transc ...... amics of virulence regulation.
@ast
Model-driven mapping of transc ...... amics of virulence regulation.
@en
P2093
P2860
P921
P356
P1433
P1476
Model-driven mapping of transc ...... amics of virulence regulation.
@en
P2093
Alyssa L Marulli
Brian C Haynes
Ezekiel J Maier
Michael R Brent
Stacey R Gish
Tamara L Doering
Zhuo A Wang
P2860
P304
P356
10.1101/GR.184101.114
P577
2015-02-02T00:00:00Z