about
Intensive aquaculture selects for increased virulence and interference competition in bacteriaGenetic compatibility and sexual selectionFluctuating temperature leads to evolution of thermal generalism and preadaptation to novel environments.Application of high resolution melting assay (HRM) to study temperature-dependent intraspecific competition in a pathogenic bacterium.Resource availability and competition shape the evolution of survival and growth ability in a bacterial community.Coincidental loss of bacterial virulence in multi-enemy microbial communitiesExperimental evolution in fluctuating environments: tolerance measurements at constant temperatures incorrectly predict the ability to tolerate fluctuating temperatures.Within-host evolution decreases virulence in an opportunistic bacterial pathogen.A multilocus sequence analysis scheme for characterization of Flavobacterium columnare isolatesPropagule pressure increase and phylogenetic diversity decrease community's susceptibility to invasion.Epigenetic Control of Phenotypic Plasticity in the Filamentous Fungus Neurospora crassa.The good-genes and compatible-genes benefits of mate choice.Different food sources elicit fast changes to bacterial virulenceConstant, cycling, hot and cold thermal environments: strong effects on mean viability but not on genetic estimates.Rapid evolutionary adaptation to elevated salt concentrations in pathogenic freshwater bacteria Serratia marcescens.Association of colony morphotypes with virulence, growth and resistance against protozoan predation in the fish pathogen Flavobacterium columnare.Does environmental robustness play a role in fluctuating environments?Evolution of bacterial life-history traits is sensitive to community structure.Can evolution of sexual dimorphism be triggered by developmental temperatures?Inbreeding, energy use and condition.Adaptation to fluctuations in temperature by nine species of bacteria.Energy use, diapause behaviour and northern range expansion potential in the invasive Colorado potato beetleAdaptation to environmental stress at different timescalesInbreeding depression in the effects of body mass on energy useInbreeding, energy use and sexual signalingBroad thermal tolerance is negatively correlated with virulence in an opportunistic bacterial pathogenThe Sex Specific Genetic Variation of Energetics in Bank Voles, Consequences of Introgression?Invasion triple trouble: environmental fluctuations, fluctuation-adapted invaders and fluctuation-mal-adapted communities all govern invasion successEcological conditions alter cooperative behaviour and its costs in a chemically defended sawflyEffects of acclimation time and epigenetic mechanisms on growth of Neurospora in fluctuating environments
P50
Q24277443-699C3980-3D55-4AAF-A812-683C1ACF6094Q28240271-BE935DA6-D776-4148-954C-7C37A6A8221BQ30671398-E7B46D29-3029-40D8-A01A-529BA908CCD7Q33681436-74AAF01C-5C60-4010-86F3-1373A343223FQ35010326-69A5B4DC-F3D0-46BD-820E-F4F25B43350DQ35388463-5886C056-0FFF-4622-B5A2-0003D67C724FQ35565310-1C464176-8CD0-4F7B-91D9-AF367781B8D6Q35748096-4E023DF4-F03D-432C-94B7-FBA6FBB5C43CQ35827820-65C81A5E-F163-43DE-A120-15768C674974Q36343772-71BE7D7B-F179-43DA-88B9-9B48BCE56644Q37485581-FD98D8C6-4F43-4F86-A7B8-AA57C7562E95Q37601493-5CE1CAC9-A329-4BDF-AE06-282EF4D45CEAQ38902109-C6B06329-D77F-4121-BBAF-25E7EBA70DCCQ39627392-07D523A7-FD89-42AE-992D-8413679197F7Q41912906-BCFAAABD-8447-464E-8FEC-555767439809Q42217407-12338CEE-9E69-437A-B2A5-ECABB3FB2136Q46085355-5D408774-5591-466E-A78D-3EBC35E88647Q46550250-C29D3C73-5B61-4E59-B2E5-1652225B942BQ51358334-54FD7C8D-EFAA-48C4-9714-CED050CE3722Q52696836-0EB949DF-9F11-4B9C-B5E6-2E8E059F5ADEQ55162169-85AC1E87-4C05-4533-A285-0006DA19832BQ56754680-457A0FCC-7610-4E56-B57E-70F86158AEF9Q57147899-430A2E2E-B6F9-4C9D-9432-F93A168EB725Q57266071-966AFE36-B303-402E-9CFF-24B70861C52FQ57266106-5D7C858F-12EB-462F-AAF4-B45BAF295FA4Q57824845-2BF70BC6-B13A-496B-98A7-AF3E060AA625Q58461270-7A455982-393D-4314-96A5-1A19EDA1BF61Q61802046-DD9F8DF4-9093-48FE-B5A6-B1D2864C061DQ90697372-F80269ED-6CAB-4FEB-A3D9-C5646B36C574Q91133863-15C66EDC-5FA7-4D14-8353-E3E494B339B5
P50
description
researcher ORCID ID = 0000-0001-5151-7980
@en
name
Tarmo Ketola
@ast
Tarmo Ketola
@en
Tarmo Ketola
@es
Tarmo Ketola
@nl
type
label
Tarmo Ketola
@ast
Tarmo Ketola
@en
Tarmo Ketola
@es
Tarmo Ketola
@nl
prefLabel
Tarmo Ketola
@ast
Tarmo Ketola
@en
Tarmo Ketola
@es
Tarmo Ketola
@nl
P1153
8202282300
P31
P496
0000-0001-5151-7980