Cryptococcus: from environmental saprophyte to global pathogen.
about
Networks of fibers and factors: regulation of capsule formation in Cryptococcus neoformansSpecies in the Cryptococcus gattii Complex Differ in Capsule and Cell Size following Growth under Capsule-Inducing ConditionsHigh-dose fluconazole in combination with amphotericin B is more efficient than monotherapy in murine model of cryptococcosis.MLST-Based Population Genetic Analysis in a Global Context Reveals Clonality amongst Cryptococcus neoformans var. grubii VNI Isolates from HIV Patients in Southeastern Brazil.Discovery of a Novel Antifungal Agent in the Pathogen Box.Molecular typing of environmental Cryptococcus neoformans/C. gattii species complex isolates from Manaus, Amazonas, Brazil.Different Lymphocyte Populations Direct Dichotomous Eosinophil or Neutrophil Responses to Pulmonary Cryptococcus Infection.Ploidy dynamics and evolvability in fungiIt's not all about us: evolution and maintenance of Cryptococcus virulence requires selection outside the human host.Modulation of Zinc Homeostasis in Acanthamoeba castellanii as a Possible Antifungal Strategy against Cryptococcus gattii.Role of microglia in fungal infections of the central nervous system.Influenza A Virus as a Predisposing Factor for Cryptococcosis.Disarming Fungal Pathogens: Bacillus safensis Inhibits Virulence Factor Production and Biofilm Formation by Cryptococcus neoformans and Candida albicans.Nutritional Requirements and Their Importance for Virulence of Pathogenic Cryptococcus Species.Exploration of Antifungal and Immunomodulatory Potentials of a Furanone Derivative to Rescue Disseminated Cryptococosis in Mice.The F-Box Protein Fbp1 Shapes the Immunogenic Potential of Cryptococcus neoformans.Regulated release of cryptococcal polysaccharide drives virulence and suppresses immune infiltration into the central nervous system.Novel recombinant multiepitope proteins for the detection of anti-Cryptococcus antibodies.The putative flippase Apt1 is required for intracellular membrane architecture and biosynthesis of polysaccharide and lipids in Cryptococcus neoformans.Investigation of Cryptococcus neoformans magnesium transporters reveals important role of vacuolar magnesium transporter in regulating fungal virulence factors.Atypical cutaneous cryptococcosis in four cats in the USA.Ecoepidemiology of Cryptococcus gattii in Developing Countries.Contribution of IL-1RI Signaling to Protection against Cryptococcus neoformans 52D in a Mouse Model of Infection.Virulence Factors as Targets for Anticryptococcal Therapy.False Negative Serum Cryptococcal Lateral Flow Assay Due to Prozone.Mechanisms of Pulmonary Escape and Dissemination by Cryptococcus neoformans.Functional genomics of lipid metabolism in the oleaginous yeast Rhodosporidium toruloides.Discovery of an Octahedral Silicon Complex as a Potent Antifungal Agent.A G-protein-coupled chemoattractant receptor recognizes lipopolysaccharide for bacterial phagocytosis.The Cryptococcus neoformans Titan cell is an inducible and regulated morphotype underlying pathogenesis.The Interaction of Human Pathogenic Fungi With C-Type Lectin Receptors.Introns in Cryptococcus.
P2860
Q26741771-36DE7C86-175F-46B4-8A6B-2A3B960BDADDQ28818460-76906228-996B-4F33-9D16-09BBE1FC9EB4Q33875911-A633E235-5ABB-48B7-A76D-845A00D09F99Q36252529-A42FB3C5-9C4C-40C5-80F3-C7446F9B3812Q36354735-B5A1A16A-DFAB-4A57-9D51-E25E1B8E602FQ38871468-4C86F91A-E34E-46F0-99BF-D4C9A5FD01B9Q39030590-4ACEA85C-BC2B-4FB0-B0EE-F453A9678B4AQ39084067-C22FC53E-47B2-4B48-9012-3FAEACF34CA1Q39175165-A0313978-0442-4777-AA93-07BF0CE3A368Q40061452-B0D56807-B9FC-4E5B-8DC5-255F7E7F6496Q40446872-9D6DC20D-F997-4D12-9968-5D05C552F754Q41919510-FC89C915-46EA-471A-8D82-7C72EBD94E3DQ42074435-50731A44-CF05-40DC-B51C-9DB524694694Q46295778-BD99F6A8-1CE8-42BC-B4DE-29D4C587773CQ47135507-5EB2DEA9-07E4-45FE-AECE-B93281970BB3Q47215796-0177EAF1-4D24-41FB-A5CD-36099B6B938CQ47370987-416D2DF2-C6B9-4979-97F9-A3517B863348Q47416748-E3899BFF-AAC7-49AC-8623-C31AB8DD91DEQ47665831-E6362551-099A-4143-92B7-81E4BB19767AQ48112146-59A6500A-9AD8-4860-88CC-0CDFBBEFCAB5Q48299778-FE296FC5-EBE5-49A5-B53F-5D8B4B3706B4Q48501948-DD1439CE-E30D-477A-8C06-ECFA2BF3EC0FQ49447299-4B2958AE-526B-43B9-BCED-BFC44A600BFEQ49612928-74C39FB9-840D-499A-B05A-C90B1A8597BEQ49789498-AC844B2F-98B8-4555-BCF1-7C289AE9BAB1Q49804343-A6B1B894-BB05-4EC9-8D0E-AFC8AA58F73EQ51764586-9F9C8A1C-B4BF-456B-BE60-0749DDAFE0F0Q52677950-BB21A96A-60CB-430A-B580-BE0AD5CE4D99Q55251215-D5D52618-7972-474D-B586-D467E77E6053Q55339940-05562930-7948-46AD-9216-06E74BCBDDA5Q55407575-370D1C49-39A5-4FB6-95B9-62A9A29B33E7Q55422161-1ECB3EC2-3823-4E60-8058-C803BD26C3CF
P2860
Cryptococcus: from environmental saprophyte to global pathogen.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 21 December 2015
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Cryptococcus: from environmental saprophyte to global pathogen.
@en
Cryptococcus: from environmental saprophyte to global pathogen.
@nl
type
label
Cryptococcus: from environmental saprophyte to global pathogen.
@en
Cryptococcus: from environmental saprophyte to global pathogen.
@nl
prefLabel
Cryptococcus: from environmental saprophyte to global pathogen.
@en
Cryptococcus: from environmental saprophyte to global pathogen.
@nl
P2860
P50
P356
P1476
Cryptococcus: from environmental saprophyte to global pathogen
@en
P2093
Darin L Wiesner
Kirsten Nielsen
P2860
P2888
P304
P356
10.1038/NRMICRO.2015.6
P407
P577
2015-12-21T00:00:00Z