Molecular evidence that the range of the Vancouver Island outbreak of Cryptococcus gattii infection has expanded into the Pacific Northwest in the United States
about
Cryptococcus gattii VGIII isolates causing infections in HIV/AIDS patients in Southern California: identification of the local environmental source as arborealThe Cryptococcus neoformans capsule: a sword and a shield.The cryptic sexual strategies of human fungal pathogensCryptococcus gattii infectionsCryptococcus neoformans: historical curiosity to modern pathogenNext generation multilocus sequence typing (NGMLST) and the analytical software program MLSTEZ enable efficient, cost-effective, high-throughput, multilocus sequencing typing.Current trends in the prevalence of Cryptococcus gattii in the United States and CanadaThe fatal fungal outbreak on Vancouver Island is characterized by enhanced intracellular parasitism driven by mitochondrial regulationVaccine-mediated immune responses to experimental pulmonary Cryptococcus gattii infection in miceCapsule independent uptake of the fungal pathogen Cryptococcus neoformans into brain microvascular endothelial cellsMicrobial Pathogens in the Fungal KingdomPopulation Genetic Analysis Reveals a High Genetic Diversity in the Brazilian Cryptococcus gattii VGII Population and Shifts the Global Origin from the Amazon Rainforest to the Semi-arid Desert in the Northeast of BrazilSpread ofCryptococcus gattiiinto Pacific Northwest Region of the United StatesCryptococcus gattii: an emerging fungal pathogen infecting humans and animals.A diverse population of Cryptococcus gattii molecular type VGIII in southern Californian HIV/AIDS patients.Surfactant protein D facilitates Cryptococcus neoformans infection.'Division of labour' in response to host oxidative burst drives a fatal Cryptococcus gattii outbreak.Cryptococcus gattii in the United States: genotypic diversity of human and veterinary isolatesFirst reported case of Cryptococcus gattii in the Southeastern USA: implications for travel-associated acquisition of an emerging pathogen.Emergence and pathogenicity of highly virulent Cryptococcus gattii genotypes in the northwest United StatesCryptococcus gattii outbreak expands into the Northwestern United States with fatal consequences.Real-time PCR assays for genotyping of Cryptococcus gattii in North AmericaIn vitro antifungal susceptibilities and amplified fragment length polymorphism genotyping of a worldwide collection of 350 clinical, veterinary, and environmental Cryptococcus gattii isolates.Emerging sporotrichosis is driven by clonal and recombinant Sporothrix species.Ecological niche modeling of Cryptococcus gattii in British Columbia, Canada.Clonality and α-a recombination in the Australian Cryptococcus gattii VGII population--an emerging outbreak in Australia.Cryptococcus neoformans hyperfilamentous strain is hypervirulent in a murine model of cryptococcal meningoencephalitis.Highly recombinant VGII Cryptococcus gattii population develops clonal outbreak clusters through both sexual macroevolution and asexual microevolution.Whole genome sequence analysis of Cryptococcus gattii from the Pacific Northwest reveals unexpected diversityFatal disseminated Cryptococcus gattii infection in New MexicoCryptococcus gattii in North American Pacific Northwest: whole-population genome analysis provides insights into species evolution and dispersal.Regulatory circuitry governing fungal development, drug resistance, and disease.Epidemiology of Cryptococcus gattii, British Columbia, Canada, 1999-2007.Matrix-assisted laser desorption ionization-time of flight mass spectrometry-based method for discrimination between molecular types of Cryptococcus neoformans and Cryptococcus gattiiUnisexual reproduction of Cryptococcus gattii.In vitro susceptibility of the yeast pathogen cryptococcus to fluconazole and other azoles varies with molecular genotype.Geoclimatic influences on invasive aspergillosis after hematopoietic stem cell transplantation.Genome variation in Cryptococcus gattii, an emerging pathogen of immunocompetent hosts.Microbiological, epidemiological, and clinical characteristics and outcomes of patients with cryptococcosis in Taiwan, 1997-2010Ancient dispersal of the human fungal pathogen Cryptococcus gattii from the Amazon rainforest.
P2860
Q21131358-FD6F909B-B5D2-45C6-9D3D-C0EEE0126333Q24619875-D4CEB2BE-84A0-4167-986F-1B6A01FC65CEQ26999966-6EDAE222-87BD-4DF8-84F1-F9A8985D4D0EQ27002687-89AAA8A3-2E0E-4327-8A7F-DDFB27FEC254Q27025924-484A6A78-EEEF-4E49-A275-5C0C0B8FEA66Q27311311-5BB42A59-3C20-4777-8D6C-935881F99FFCQ28080670-C0B0D6E5-8CFC-429F-825E-4DB06160A5AEQ28253787-E2DDBF79-7806-4A8D-88FC-D5FE128D6480Q28541882-99F88452-4D97-4AB8-BDFD-ECD183111BA1Q28730545-D47B3FF2-8582-44C6-B6DC-FFA61437AFC3Q28740823-A922C60D-AACC-48BE-85DC-7AD4915C65F0Q28830168-8B9E6482-9F9D-49B9-9C41-B5F8A8EBA06FQ30048584-066BDD49-DBC2-4762-A246-0C54AF703003Q30403990-E9400760-57A1-4665-AFB5-3021A25E8746Q30406964-B00D879D-69B0-42AA-A061-50EA8644C78EQ30416197-0DE8E1F5-E3E6-42EB-8399-33C574B48CECQ30596156-8A04D790-58D5-4825-B6A0-B364A93D35C4Q31138137-8C58E768-540F-4BCC-B80D-B8ABDEAE59D8Q33466017-0F762BC7-ABF2-46E3-8B21-E52F9519AD07Q33565424-DE0DB65F-0BCE-414A-9770-8CC24BE81912Q33636108-E91E207C-4DCA-40CC-8C60-64BF7AB48834Q33655285-812374EA-9B1A-4731-B151-1AF5A804DE85Q33696932-AC15B1B7-D2CF-47A9-938A-E517DFC25737Q33733015-1272E527-2850-4088-89B6-45FADB0D9F41Q33837837-C221C018-9C6B-44F6-95BC-74DF60CE9DC3Q33839536-B5BA3E01-3316-4973-BCB0-1FCC0A5D40CEQ34005219-71F9B31E-165D-4763-A3F9-4180C95538E9Q34026290-99622064-7088-4747-BC0A-3CAE02F4B481Q34098250-EA867D0D-4727-49E0-B3DF-50153AACB65CQ34110199-CB808A19-392E-4824-A91E-30CF3D2182A6Q34165445-09EE69A5-9BA1-4658-814A-7B7563F0CD70Q34190284-F03D87CD-A6A4-4114-8E67-11A782A5D34CQ34216198-273CD6FD-4523-44EE-A6ED-F7C4BD405D8CQ34264267-64866EF4-2B8C-42F5-BE80-FE18384A5719Q34388703-00FC9CC8-58C6-4C6C-A098-5545BED68C01Q34489508-4845DF7B-5AA3-4CD8-9CAE-F7F4C7A8D78EQ34505388-3385FB30-C537-428F-8892-346A73158B43Q34565901-56E275FC-C9C2-4117-8F2A-B7BC2D115B84Q34685419-866219DE-C5BB-426E-9341-FFABE1D5E7C1Q34936939-9046C46E-4FA2-4998-84AB-86961E5EE79A
P2860
Molecular evidence that the range of the Vancouver Island outbreak of Cryptococcus gattii infection has expanded into the Pacific Northwest in the United States
description
2009 nî lūn-bûn
@nan
2009 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
Molecular evidence that the ra ...... Northwest in the United States
@ast
Molecular evidence that the ra ...... Northwest in the United States
@en
type
label
Molecular evidence that the ra ...... Northwest in the United States
@ast
Molecular evidence that the ra ...... Northwest in the United States
@en
prefLabel
Molecular evidence that the ra ...... Northwest in the United States
@ast
Molecular evidence that the ra ...... Northwest in the United States
@en
P2093
P2860
P356
P1476
Molecular evidence that the ra ...... Northwest in the United States
@en
P2093
Edmond J Byrnes
Kieren A Marr
Robert J Bildfell
Sheryl A Frank
Thomas G Mitchell
P2860
P304
P356
10.1086/597306
P407
P577
2009-04-01T00:00:00Z