about
Intensive aquaculture selects for increased virulence and interference competition in bacteriaWithin-host competitive interactions as a mechanism for the maintenance of parasite diversityHarbouring public good mutants within a pathogen population can increase both fitness and virulenceQuorum sensing inhibition selects for virulence and cooperation in Pseudomonas aeruginosaThe expression and evolution of virulence in multiple infections: the role of specificity, relative virulence and relative doseBacterial interactions in biofilms.Predation on multiple trophic levels shapes the evolution of pathogen virulence.Influence of multiple infection and relatedness on virulence: disease dynamics in an experimental plant population and its castrating parasiteCooperation and conflict in host manipulation: interactions among macro-parasites and micro-organisms.Competition, cooperation among kin, and virulence in multiple infections.Genetic structure of Schstosoma mansoni in western Kenya: the effects of geography and host sharing.Within-host competition drives selection for the capsule virulence determinant of Streptococcus pneumoniaeTo be or not to be solitary: Phytophthora infestans' dilemma for optimizing its reproductive fitness in multiple infections.Within-host dynamics of multi-species infections: facilitation, competition and virulence.Life history trade-offs and relaxed selection can decrease bacterial virulence in environmental reservoirs.Do black truffles avoid sexual harassment by linking mating type and vegetative incompatibility?Cheating, trade-offs and the evolution of aggressiveness in a natural pathogen populationWithin-host evolution decreases virulence in an opportunistic bacterial pathogen.Context-dependent effects of induced resistance under co-infection in a plant-pathogen interaction.The sociobiology of sex: inclusive fitness consequences of inter-sexual interactionsCoinfection outcome in an opportunistic pathogen depends on the inter-strain interactions.Competitive outcome of multiple infections in a behavior-manipulating virus/wasp interactionSpite and virulence in the bacterium Pseudomonas aeruginosa.Cooperation and virulence of clinical Pseudomonas aeruginosa populationsA Chrysodeixis chalcites single-nucleocapsid nucleopolyhedrovirus population from the Canary Islands is genotypically structured to maximize survival.War and peace: social interactions in infectionsFirst principles of Hamiltonian medicine.Multiple infections and the evolution of virulence.Evolution of resistance to quorum-sensing inhibitors.Cooperation, quorum sensing, and evolution of virulence in Staphylococcus aureus.Growth rate, transmission mode and virulence in human pathogens.Microbe-mediated host defence drives the evolution of reduced pathogen virulence.The evolution of siderophore production as a competitive trait.Killing them softly: managing pathogen polymorphism and virulence in spatially variable environments.Testing GxG interactions between coinfecting microbial parasite genotypes within hostsVirulence evolution and the trade-off hypothesis: history, current state of affairs and the future.Within-host interference competition can prevent invasion of rare parasites.Fitness costs restrict niche expansion by generalist niche-constructing pathogens.Ecological and genetic determinants of plasmid distribution in Escherichia coli.Host infection history modifies co-infection success of multiple parasite genotypes.
P2860
Q24277443-915F311E-13CA-4089-ABF2-96DDC2E05E7AQ26700138-B6CB65B6-F25C-4793-88F5-85970F4D9B81Q28354993-93A4DBF3-7F03-43E6-9C01-8AB73924BC91Q28473858-AC7ADB2A-0621-4578-B6C8-4141ABD4EE8BQ31116567-C1BE3483-924C-44F8-AB3F-42BA5C1A96A1Q33485456-B6EB9325-0A36-4215-975A-2C954881D646Q33496768-E09F73D3-20FE-4607-925C-FB9E918651B8Q33706531-1E787A8E-1533-482B-9708-A4D26BFED17EQ33737288-FE4B673E-934B-4813-AB90-2959F04C418DQ33759831-42499832-3D49-483E-A4F5-D25479DF76BCQ33941750-0935ED9F-3416-4CB3-82E6-6D018539E62AQ34032902-222254DE-45D5-4BF8-90FF-B131F7061BC0Q34295626-46249E45-CF16-4DFC-95BB-CA43D8844CEFQ34318373-FE7FC131-E68C-4013-B596-B73DB3537CE1Q34399416-0525920B-8172-4786-98C7-1F2301151AEBQ34742886-2B6E61CE-74D6-4ADC-883D-A7F3E8592BE5Q35309107-36091C29-2FC7-4B77-8DD6-90FA48D803E9Q35748096-D14FC20A-76D5-4200-8ADD-AED86421CEBBQ35961222-25191A66-1224-41F7-BEF1-D6D3A624CD2EQ36081180-092557F6-05BB-41B3-A0C9-1530E349F4F3Q36306510-C79B34C4-86AE-4D0D-AC6F-3B2F9229B1B7Q36475439-21365B86-B49F-4249-B58B-FB2D5E45A0CAQ37153678-B12EA00E-83D3-491B-9BC9-8AD0D0900096Q37158959-DD976185-430F-489B-A813-EC2924B67811Q37335597-2A853939-2624-4A84-9466-E515EBE4E88FQ37696303-5ADC83FB-D8F8-442F-A49D-6510F6C61251Q37696306-4BABFD99-C123-402A-B11A-9578C40BE6BBQ38076466-30C9F0BA-8865-4ABC-A420-B763B83AB93BQ38160197-7B8C08EB-9F38-4CDF-9CED-25A3A2F47F3DQ38327559-1F5E416D-8A05-4990-BDA6-CDF713688866Q38910362-3ECABFFA-BE01-4B00-8325-C7B807A21762Q39187216-8219DA05-91C0-491D-B431-662FB7A0AB27Q39304117-D2AC192F-F131-4185-83BC-5D16B4481276Q39370171-CBB5DD0D-3DB8-451D-AF9E-B8A0E870B58AQ39851517-2C165562-46E4-4C89-9F9E-0EECA91779D4Q40004898-320C726F-8830-4411-BECB-73E44B2A6132Q40213822-90F373E4-B185-4B1A-9387-67EB30A6EDC2Q40471961-FA2A3FA6-CFD3-47F4-BD94-B1F4A8804ED1Q40479788-77B2921E-425D-4DF8-B867-9C52AAC75142Q40901668-B5807949-8BBB-4D82-9CEC-E4BE2978CAB7
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 23 January 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Kin selection and the evolution of virulence.
@en
Kin selection and the evolution of virulence.
@nl
type
label
Kin selection and the evolution of virulence.
@en
Kin selection and the evolution of virulence.
@nl
prefLabel
Kin selection and the evolution of virulence.
@en
Kin selection and the evolution of virulence.
@nl
P2860
P356
P1433
P1476
Kin selection and the evolution of virulence.
@en
P2093
A Buckling
M A Brockhurst
P2860
P2888
P304
P356
10.1038/SJ.HDY.6801093
P407
P577
2008-01-23T00:00:00Z
P5875
P6179
1006886646