Evolutionary potential of Chamaecrista fasciculata in relation to climate change. II. Genetic architecture of three populations reciprocally planted along an environmental gradient in the great plains.
about
Artificial selection shifts flowering phenology and other correlated traits in an autotetraploid herb.Evolution of a genetic polymorphism with climate change in a Mediterranean landscape.Evolutionary response of landraces to climate change in centers of crop diversity.Revealing hidden evolutionary capacity to cope with global change.The success of assisted colonization and assisted gene flow depends on phenology.Seasonal time constraints reduce genetic variation in life-history traits along a latitudinal gradient.Genetic differentiation across a latitudinal gradient in two co-occurring butterfly species: revealing population differences in a context of climate change.Germination behaviour of annual plants under changing climatic conditions: separating local and regional environmental effects.The response of two butterfly species to climatic variation at the edge of their range and the implications for poleward range shifts.Rapid evolution in response to introduced predators II: the contribution of adaptive plasticity.Evaluating the sources of potential migrant species: implications under climate change.Translocation experiments with butterflies reveal limits to enhancement of poleward populations under climate change.Why does phenology drive species distribution?Population divergence along lines of genetic variance and covariance in the invasive plant Lythrum salicaria in eastern North America.Rapid climate change and the rate of adaptation: insight from experimental quantitative genetics.Extensive variation in cadmium tolerance and accumulation among populations of Chamaecrista fasciculata.Limited Pollen Dispersal Contributes to Population Genetic Structure but Not Local Adaptation in Quercus oleoides Forests of Costa RicaEvolutionary rescue beyond the models.Evolutionary responses of natives to introduced species: what do introductions tell us about natural communities?Detecting genetic responses to environmental change.Non-random distribution of individual genetic diversity along an environmental gradient.Quantitative genetic study of the adaptive process.Genetics of dispersal.Genes and quantitative genetic variation involved with senescence in cells, organs, and the whole plantStudying plant-pollinator interactions in a changing climate: A review of approachesQuantifying effects of environmental and geographical factors on patterns of genetic differentiation.Geographic variation in genetic and demographic performance: new insights from an old biogeographical paradigm.Florally rich habitats reduce insect pollination and the reproductive success of isolated plants.Adaptation at range margins: common garden trials and the performance of Arabidopsis lyrata across its northwestern European range.Brave New World: the epistatic foundations of natives adapting to invaders.Tolerance of roadside and old field populations of common teasel (Dipsacus fullonum subsp. sylvestris) to salt and low osmotic potentials during germination.Patterns of genetic variation in desiccation tolerance in embryos of the terrestrial-breeding frog, Pseudophryne guentheri.Beyond the ecological: biological invasions alter natural selection on a native plant species.Indirect effects drive evolutionary responses to global change.High evolutionary constraints limited adaptive responses to past climate changes in toad skulls.Migration load in plants: role of pollen and seed dispersal in heterogeneous landscapes.Adaptation to marginal habitats by evolution of increased phenotypic plasticity.Between migration load and evolutionary rescue: dispersal, adaptation and the response of spatially structured populations to environmental change.Energy expenditure and body size are targets of natural selection across a wide geographic range, in a terrestrial invertebratePositive and negative biotic interactions and invasiveTriadica sebiferatolerance to salinity: a cross-continent comparative study
P2860
Q30444217-ABAFACCB-BA7C-4B39-B96A-D25CEC631A4BQ30587008-3C3DD2B4-DCB3-4DDA-A276-6B24DC5FA3E3Q30883232-60547334-20F2-4C8F-A5E0-FB4BC9F31086Q30911768-389610DA-52C7-40F3-A883-CB085B27434BQ30962848-30B90B1D-74DC-455D-BFCE-1BFBA12F724EQ30991197-64B8B9EF-5812-4E13-82DB-86A68FA54631Q31125473-BFA1D6DC-6AE8-41BD-BEC2-1A065771AA89Q31143134-0CD3ECA0-45DF-4D25-BDB7-802D0DC28402Q31164747-4EC6FF6D-A842-4B28-99C2-80E53B71E3DCQ33273796-158860E5-D523-482A-9B81-99FB2E0FBB6DQ33374369-813D8BCF-876D-440D-97E9-3618504B61B1Q33473088-F9890D60-80FC-4A49-A0DC-8D07945D5FD6Q33685177-52EBB237-0497-48D0-B92B-891186CA5FF9Q34007724-2EF6D62E-170B-4E14-99AC-0603B2750C4BQ34346061-C66DA27A-952E-4890-B23A-74C62AD473B2Q34718052-4BFCE8BE-92C4-4C32-863E-7796C5DB6900Q36094041-A7E79813-C5AC-439C-86ED-C4DD1374B03CQ36512974-932D0781-AFFD-4FFC-A6E4-6E8383DE0C45Q36588356-7C716400-1A31-4D63-9683-F587406832E1Q37157270-74F5933F-731F-4EB5-B2C9-CFDA81F456B4Q37212497-AB29CFD3-63C3-491F-BDE5-547956F93560Q37385805-48E22580-166C-4F8C-AB48-989DF87F6CF9Q38368491-FF0DB822-07A5-4B46-8114-ABE66AFBDFCAQ38371661-CDE20FB3-3E7F-48F9-B09F-214CC0B5E2C0Q38660526-90050D20-CBBD-459F-A0F7-2D0DB4953750Q38866706-9EA86DED-82F7-444E-BA71-250BCEF6706DQ39021875-C44EF232-CC2D-4706-8AF2-89419B04711CQ41546706-BDE3BDCA-BB27-4D08-85CB-07A8579284C2Q44812428-6D32963A-B341-4774-A4F3-69DE1F71F3D2Q46048088-BD891D76-B7DA-445A-848A-0427DF9DEF9BQ46077371-96875F76-82EE-45E8-8C19-D940F2C8EF7CQ46322602-F4F81D92-F77A-4846-9460-7C1BEEEDC2C9Q46645795-0C8E7F49-A6EF-4763-8DF9-07778B8DE2F3Q46985926-C83EA5AB-6B91-4B40-ADE0-6E036F349D51Q51252499-6B278787-22BE-4098-B884-718D43A278BCQ51699351-8ED4C2F6-B582-4AE9-855B-E453655AA475Q52719983-68FA6D5E-53B3-4176-8EDD-DC9BD6EA08BBQ52880031-73370941-2CB5-4F14-A173-AE9ED55978D8Q56425176-0CA5BB88-6A79-4341-BC7D-5C4461B66A5EQ56439477-3348BB95-8584-4D0A-8636-CF13EE4230FD
P2860
Evolutionary potential of Chamaecrista fasciculata in relation to climate change. II. Genetic architecture of three populations reciprocally planted along an environmental gradient in the great plains.
description
2004 nî lūn-bûn
@nan
2004 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2004 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
name
Evolutionary potential of Cham ...... gradient in the great plains.
@ast
Evolutionary potential of Cham ...... gradient in the great plains.
@en
type
label
Evolutionary potential of Cham ...... gradient in the great plains.
@ast
Evolutionary potential of Cham ...... gradient in the great plains.
@en
prefLabel
Evolutionary potential of Cham ...... gradient in the great plains.
@ast
Evolutionary potential of Cham ...... gradient in the great plains.
@en
P2860
P1433
P1476
Evolutionary potential of Cham ...... gradient in the great plains.
@en
P2093
Julie R Etterson
P2860
P304
P356
10.1111/J.0014-3820.2004.TB01727.X
P577
2004-07-01T00:00:00Z