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Ready or Not, Garlic Mustard Is Moving In: Alliaria petiolata as a Member of Eastern North American ForestsThe release of genetically modified crops into the environment. Part II. Overview of ecological risk assessmentPlants capable of selfing are more likely to become naturalizedA chemosynthetic weed: the tubeworm Sclerolinum contortum is a bipolar, cosmopolitan speciesOrganic farming and landscape structure: effects on insect-pollinated plant diversity in intensively managed grasslandsChecklist for the crop weeds of ParaguayFactors affecting germination of jointed goatgrass (Aegilops cylindrica) seedA biogeographical approach to plant invasions: the importance of studying exotics in their introduced and native rangeEvolutionary ecology along invasion fronts of the annual grass Aegilops triuncialisNonindigenous Plant Advantage in Native and Exotic Australian Grasses under Experimental Drought, Warming, and Atmospheric CO2 Enrichment.Biological invasions, climate change and genomics.Fast economic development accelerates biological invasions in China.Revealing historic invasion patterns and potential invasion sites for two non-native plant species.Do invasive species show higher phenotypic plasticity than native species and, if so, is it adaptive? A meta-analysis.A phylogenetically controlled analysis of the roles of reproductive traits in plant invasions.The population genomic basis of geographic differentiation in North American common ragweed (Ambrosia artemisiifolia L.).Competitive performance of transgenic wheat resistant to powdery mildew.Can arbuscular mycorrhizal fungi reduce the growth of agricultural weeds?Invasive Microstegium populations consistently outperform native range populations across diverse environments.A review of the environmental safety of the Cry1Ab protein.Geographic range size is predicted by plant mating system.Plant community associations of two invasive thistlesGeneralised pollination systems for three invasive milkweeds in Australia.Assembly of nonnative floras along elevational gradients explained by directional ecological filteringPhenotypic plasticity of early and late successional forbs in response to shifts in resources.Evidence for rapid evolution of phenology in an invasive grass.Hybridisation is associated with increased fecundity and size in invasive taxa: meta-analytic support for the hybridisation-invasion hypothesis.Transgenics and vertebrate cloning as tools for species conservation.Integrative invasion science: model systems, multi-site studies, focused meta-analysis and invasion syndromes.Biocontrol attack increases pollen limitation under some circumstances in the invasive plant Centaurea solstitialis.Phenotypic plasticity in plants: a case study in ecological development.Population structure and genetic diversity of native and invasive populations of Solanum rostratum (Solanaceae).Are weeds hitchhiking a ride on your car? A systematic review of seed dispersal on cars.Salicornia as a crop plant in temperate regions: selection of genetically characterized ecotypes and optimization of their cultivation conditions.Metapopulation structure and fine-scaled genetic structuring in crop-wild hybrid weed beets.Morning glory as a powerful model in ecological genomics: tracing adaptation through both natural and artificial selection.Comparative genomics in the Asteraceae reveals little evidence for parallel evolutionary change in invasive taxa.Transgene introgression from genetically modified crops to their wild relatives.The devil is in the details: genetic variation in introduced populations and its contributions to invasion.Exploring origins, invasion history and genetic diversity of Imperata cylindrica (L.) P. Beauv. (Cogongrass) in the United States using genotyping by sequencing.
P2860
Q28109691-0B0F80C0-1C31-448C-BAAD-E9B9D7DDDA9AQ28203960-931FAA6F-1F34-4D22-A2B7-8FA226B3FDAFQ28314933-646A9696-BB07-4DAF-90F2-14E4F2D6BCAFQ28604264-A9717CF2-9B81-472E-9C0D-C9A2B008AFA3Q28729096-48C2C824-F80A-4FD3-A7C5-3EC1C06848D0Q28937350-28248D6A-7C3B-44EF-9180-A3E6F846EF4DQ29036652-8E501844-FF4D-464A-878F-99362B79088BQ29041580-7CA762B8-A5C4-4436-820D-B65498FB4F12Q29542277-36415471-DBD5-496C-AF42-46B71C32A335Q30821776-355E853B-9E76-4CDC-9B1E-F32F8620DFDBQ30890746-765E6778-595D-4CB3-A718-719C220FFAACQ33306694-A636829B-C8B6-4E38-B44F-90258BA3D88BQ33320535-8933F9AD-FD8A-4FF9-85DF-92F13718033EQ33818626-012BCAEC-EA61-4038-965F-3AEA10BBF36DQ33822618-2AEBFA73-5FAC-4FD2-B0CE-C61D9A0460CCQ33910388-3B448538-7759-4CDE-8463-7D836D1D0545Q34088136-9C9874EE-652D-4C57-B353-7AD28CF2CA62Q34098920-98911050-15BC-44DA-BEBA-BD50D82A7027Q34165177-D27D9203-2DF7-4B11-805E-C8CDBA221817Q34271532-71FFD129-2687-4B6C-803F-13A46279160DQ34476627-855C354C-B684-4108-A520-F51C475EDE9AQ34479024-FA227145-554D-4EB0-8955-D856F8FF5636Q34485516-F4066AC3-C062-484F-A10C-3B7C50EBEDEDQ34490846-E0647E43-74C2-4F3E-AF91-6E3A02600717Q34491294-9002A5A1-B371-4D9F-BFAD-200E86BB08B6Q34495420-068308CA-2A24-4EDA-989A-896A85E17DC9Q34511104-6CD82ECC-C880-48BC-8988-803BF2A41FCEQ34557446-B221BAFE-5535-4A9B-A20E-BD06708ED2A1Q34859785-E5F3D027-F85A-432B-B3ED-90139C68BE74Q34987434-D43F8125-F632-4D6A-AE89-DBFDD69941C5Q35030619-2F308311-8DEC-473D-ADB4-9DA18E45053EQ35041499-FE019849-D86A-499F-A6ED-D2FACE3395E6Q35050590-55F31F92-3F20-4D00-B22F-AF94FEF90228Q35411116-A8651D61-717D-489C-A566-C6AFA763FFCEQ35428803-4DD03301-AEE0-4C10-A3B2-D3DAC68314BEQ35428823-C5031D8F-E9E5-4FE2-B970-871221BA564CQ35465170-3E583C51-C4A2-4A93-A419-6F37D3D0AB1BQ35550191-03B2822C-0A84-408E-BB6E-420699C2E5C8Q35595754-845B4F10-96F9-4ADF-98B1-9FD282F87DB2Q35599758-5E300D00-1609-459A-AE13-5400B0EB53B7
P2860
description
article
@en
im November 1974 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в листопаді 1974
@uk
ലേഖനം
@ml
name
The Evolution of Weeds
@en
The Evolution of Weeds
@nl
type
label
The Evolution of Weeds
@en
The Evolution of Weeds
@nl
prefLabel
The Evolution of Weeds
@en
The Evolution of Weeds
@nl
P1476
The Evolution of Weeds
@en
P2093
P356
10.1146/ANNUREV.ES.05.110174.000245
P407
P577
1974-11-01T00:00:00Z