about
Harbouring public good mutants within a pathogen population can increase both fitness and virulenceComparing artificial and natural selection in rate of adaptation to genetic stress in Aspergillus nidulansThe jack of all trades is master of none: a pathogen's ability to infect a greater number of host genotypes comes at a cost of delayed reproduction.Migrate or evolve: options for plant pathogens under climate change.Rust fungi and global change.Changing fitness of a necrotrophic plant pathogen under increasing temperature.The properties of adaptive walks in evolving populations of fungusNeurospora discreta as a model to assess adaptation of soil fungi to warmingMitotic recombination accelerates adaptation in the fungus Aspergillus nidulansInteractions of biotic and abiotic environmental factors in an ectomycorrhizal symbiosis, and the potential for selection mosaics.Regular bottlenecks and restrictions to somatic fusion prevent the accumulation of mitochondrial defects in NeurosporaExperimental evolution to increase the efficacy of the entomopathogenic fungus Beauveria bassiana against malaria mosquitoes: Effects on mycelial growth and virulence.Asexual reproduction induces a rapid and permanent loss of sexual reproduction capacity in the rice fungal pathogen Magnaporthe oryzae: results of in vitro experimental evolution assaysThe symbiont side of symbiosis: do microbes really benefit?Diversity effects on productivity are stronger within than between trophic groups in the arbuscular mycorrhizal symbiosis.Forests trapped in nitrogen limitation--an ecological market perspective on ectomycorrhizal symbiosis.Multivariate phenotypic divergence due to the fixation of beneficial mutations in experimentally evolved lineages of a filamentous fungus.Analyses of expressed sequence tags in Neurospora reveal rapid evolution of genes associated with the early stages of sexual reproduction in fungi.The aging biological clock in Neurospora crassa.Deleterious effects of recombination and possible nonrecombinatorial advantages of sex in a fungal model.Composite survival index to compare virulence changes in azole-resistant Aspergillus fumigatus clinical isolates.Clonal expansion of the Pseudogymnoascus destructans genotype in North America is accompanied by significant variation in phenotypic expressionHow Did Host Domestication Modify Life History Traits of Its Pathogens?High genetic variability and low local diversity in a population of arbuscular mycorrhizal fungi.Experimental evolution reveals that high relatedness protects multicellular cooperation from cheaters.Adaptation of a plant pathogen to partial host resistance: selection for greater aggressiveness in grapevine downy mildew.Natural selection and the evolutionary ecology of the arbuscular mycorrhizal fungi (Phylum Glomeromycota).Rapid genotypic change and plasticity in arbuscular mycorrhizal fungi is caused by a host shift and enhanced by segregation.Conserved components, but distinct mechanisms for the placement and assembly of the cell division machinery in unicellular and filamentous ascomycetes.Inbreeding depression in urban environments of the bird's nest fungus Cyathus stercoreus (Nidulariaceae: Basidiomycota).What was old is new again: thermal adaptation within clonal lineages during range expansion in a fungal pathogen.Endogenous lipogenic regulators of spore balance in Aspergillus nidulansAssessment of diversity and genetic relationships of Neonectria ditissima: the causal agent of fruit tree canker.Cooperation among germinating spores facilitates the growth of the fungus, Neurospora crassa.Sex slows down the accumulation of deleterious mutations in the homothallic fungus Aspergillus nidulans.Unisexual reproduction enhances fungal competitiveness by promoting habitat exploration via hyphal growth and sporulation.Genotype-environment interactions of spontaneous mutations for vegetative fitness in the human pathogenic fungus Cryptococcus neoformans.Model and test in a fungus of the probability that beneficial mutations survive drift.Deletion of the Delta12-oleic acid desaturase gene of a nonaflatoxigenic Aspergillus parasiticus field isolate affects conidiation and sclerotial development.Natural Variation of the Circadian Clock in Neurospora.
P2860
Q28354993-4300323E-760E-41FE-9F68-AC058860911EQ29027336-8CFB41DE-D350-4B22-8479-60396A6EAC94Q30458269-076A88C9-16BD-4DE4-8F89-54C607DB5E4DQ30611990-C580BC32-116A-4DDB-AAB6-D1904B59E475Q30761892-E2BAEED7-650F-497F-8EAA-612585AB15AEQ30909665-11041F8E-80CF-4982-B601-EA3E88D1B6B9Q30947119-115E4DFC-4C3E-4389-83FB-5EA7C5D67B04Q30993902-815717B7-93F5-4047-B6B4-D55057651A70Q33283066-487F2FDA-1449-4331-AC6A-A57616D6E234Q33338242-BA7D1B50-B11B-4888-B7ED-2C0D8AA0CE75Q33655988-E68082F3-D6EE-45C6-ACB9-157E6BAEDEFAQ33668307-431E3BF3-8134-4D61-95D5-C0E7C87E426DQ34212856-62F2B3F8-070F-444F-A5E9-7038D5336002Q34250034-025DE103-DB33-4220-B993-51DA154F7FCFQ34281739-F00A9DF7-6D03-4DCE-831A-BA73A23CC965Q34419861-9FC31783-9859-4C44-9EF3-0F9AD447600BQ34491304-7A4EDE6D-E75A-4B09-A62A-2B0CCE6433F1Q34491821-732166CE-4C5F-4323-BE70-8B05CE3E4A87Q34494860-E4265091-8EEE-474F-BB86-227A6CEC68AFQ34815194-24CFCCEF-B854-497D-A9CD-AD9D1ECC93F5Q34977071-9A8935D0-EF20-481D-B3FB-FEE7ED868AA5Q35224836-D459766A-B6FE-4FDE-9B38-904FF7E36002Q35668683-65DA691C-9087-4EDA-97BC-0BCAB5F6BB45Q36601925-6806148A-891F-471E-BC9B-362D34CFFF6EQ36871709-087DB764-6568-4733-B088-663125626784Q36907511-6707F20E-FFBC-4125-96D6-0B66E0516D7EQ37476436-4C283F9F-FE1D-492E-A211-1D18C9D37E4CQ37532021-94574E49-86B0-496B-9A01-318257831C10Q37811026-F4BAD895-FE7A-469D-8727-ED46D4C2CC79Q39256696-09071801-FCA6-49A1-8D95-8800A3DC04D7Q40357295-41B135AF-DD29-46E4-8565-0526F29C8C61Q40737343-5A1F113F-2CE9-4605-99CE-91315D43DD17Q41234947-4EC52060-C65D-47C9-8FCA-7691F9C2D127Q41761586-1204C106-5FE7-4FA9-AC39-FD6CD93A182FQ41839857-58BB3CFA-8340-4306-8977-E78C103B20A2Q42257847-01473BD2-B0A3-465E-A1B5-6E546FB9AF5EQ42910035-642C316A-F4D3-443A-B428-1967167641C6Q43184217-6139F4B7-E83A-4623-9462-AB56B4B5F750Q45152276-F96CD181-11B1-47FA-ABEA-4ED25DF1ABB2Q46280250-47DFEA17-1D80-477A-994B-3E45196042B6
P2860
description
2002 nî lūn-bûn
@nan
2002 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
The fitness of filamentous fungi.
@ast
The fitness of filamentous fungi.
@en
The fitness of filamentous fungi.
@nl
type
label
The fitness of filamentous fungi.
@ast
The fitness of filamentous fungi.
@en
The fitness of filamentous fungi.
@nl
prefLabel
The fitness of filamentous fungi.
@ast
The fitness of filamentous fungi.
@en
The fitness of filamentous fungi.
@nl
P1476
The fitness of filamentous fungi.
@en
P2093
Anne Pringle
John Taylor
P304
P356
10.1016/S0966-842X(02)02447-2
P577
2002-10-01T00:00:00Z