Genes in new environments: genetics and evolution in biological control.
about
Microsatellite and mitochondrial data provide evidence for a single major introduction for the Neartic leafhopper Scaphoideus titanus in EuropeConciliation biology: the eco-evolutionary management of permanently invaded biotic systemsClassical Biological Control of Invasive Legacy Crop Pests: New Technologies Offer Opportunities to Revisit Old Pest Problems in Perennial Tree CropsHow humans drive speciation as well as extinctionGenetic divergence in the small Indian mongoose (Herpestes auropunctatus), a widely distributed invasive speciesThe biology of small, introduced populations, with special reference to biological controlHuman drivers of ecological and evolutionary dynamics in emerging and disappearing infectious disease systems.Unlocking the vault: next-generation museum population genomics.Can we forecast the effects of climate change on entomophagous biological control agents?Test of colonisation scenarios reveals complex invasion history of the red tomato spider mite Tetranychus evansiThe genetic polymorphisms and colonization process of olive fly populations in TurkeyGenetic evidence from mitochondrial, nuclear, and endosymbiont markers for the evolution of host plant associated species in the aphid genus Hyalopterus (Hemiptera: Aphididae).Isolation and Characterization of Microsatellite Loci for Cotesia plutellae (Hymenoptera: Braconidae)Review of the invasion of Tetranychus evansi: biology, colonization pathways, potential expansion and prospects for biological control.Recent cases of invasive alien mites and ticks in Japan: why is a regulatory framework needed?A population genetic signature of human releases in an invasive ladybeetle.Drosophila suzukii: the genetic footprint of a recent, worldwide invasion.Sequential loss of genetic variation in flea beetle Agasicles hygrophila (Coleoptera: Chrysomelidae) following introduction into China.The tomato borer, Tuta absoluta, invading the Mediterranean Basin, originates from a single introduction from Central Chile.Exploring origins, invasion history and genetic diversity of Imperata cylindrica (L.) P. Beauv. (Cogongrass) in the United States using genotyping by sequencing.Molecular tools and bumble bees: revealing hidden details of ecology and evolution in a model system.Mitochondrial DNA revealed the extent of genetic diversity and invasion origin of populations from two separate invaded areas of a newly invasive pest, Cydia pomonella (L.) (Lepidoptera: Tortricidae) in China.Marked Genetic Differentiation between Western Iberian and Italic Populations of the Olive Fly: Southern France as an Intermediate AreaInsight into the Migration Routes of Plutella xylostella in China Using mtCOI and ISSR MarkersMultiple and mass introductions from limited origins: genetic diversity and structure of Solidago altissima in the native and invaded range.Reconstructing the invasion history of Heracleum persicum (Apiaceae) into Europe.Climate-Driven Reshuffling of Species and Genes: Potential Conservation Roles for Species Translocations and Recombinant Hybrid Genotypes.Underutilized resources for studying the evolution of invasive species during their introduction, establishment, and lag phasesEvolution in agriculture: the application of evolutionary approaches to the management of biotic interactions in agro-ecosystems.Genetic Analysis of the Aspergillus flavus Vegetative Compatibility Group to Which a Biological Control Agent That Limits Aflatoxin Contamination in U.S. Crops BelongsPopulation genetic structure and demographic history of the black fly vector, Simulium nodosum in Thailand.Genetic variability of arrhenotokous and thelytokous Venturia canescens (Hymenoptera)Evolution and biological control.Host specificity in biological control: insights from opportunistic pathogensHybrid vigor in the biological control agent, Longitarsus jacobaeaeIntraspecific variability in the parasitoid wasp Trichogramma chilonis: can we predict the outcome of hybridization?Evolution of critical day length for diapause induction enables range expansion of Diorhabda carinulata, a biological control agent against tamarisk (Tamarix spp.).Evolving while invading: rapid adaptive evolution in juvenile development time for a biological control organism colonizing a high-elevation environment.Post-introduction evolution in the biological control agent Longitarsus jacobaeae (Coleoptera: Chrysomelidae)Stress for invasion success? Temperature stress of preceding generations modifies the response to insecticide stress in an invasive pest insect.
P2860
Q21089877-87504F71-84F9-4E58-96FE-A2249E7737FDQ24620880-CD667613-38C2-4043-BFE6-9C7FF206FBB1Q27022445-FE73E446-B51B-4302-8548-12498C2A4A69Q28068722-963E9E99-456C-462C-B0E1-02542465FB96Q28269679-68FA833B-64B0-43ED-9114-9A24F66F8B19Q28728687-AB5EA6F9-2EE5-4773-8519-C12B2EBFB0F7Q30240268-C764241B-4522-4BBC-BD18-B1D03462A442Q30676353-38BD3D54-7D8D-4A28-8F7F-7B4500AF6C6CQ30697935-FB512A49-2A2A-4385-9D0A-99FE30818B23Q31060076-75D5CBD0-0ADC-464A-98E1-CC5254716DE7Q31112040-08A2B317-3CC9-436D-BC26-E5AC1B66DC56Q33286420-9B885D65-660B-4EE1-BEF8-CB5AF9A4FB9FQ33856253-48DDCAFB-2E5C-4469-AAA2-2DE2AF75A622Q34348672-E703B7E8-DDD2-40BA-A9A6-51D8A3476A40Q34419178-9F6D56FF-24E8-42AD-94B7-F451AE316F59Q34435925-8F54DAD3-4AFA-4A4F-866D-84445503FB72Q34579236-DAF26C94-E383-416F-B1E8-96973EEF926CQ34954863-6A7FF2B1-12CC-45F2-8510-ACB2C106E336Q35558635-C7EC557C-1F7D-4ABE-9A67-63C4D0EAB4DEQ35599758-9DDEA6BD-6F84-4F78-944E-C470332E9DADQ35599882-BD5B55D2-75DC-448B-A7C2-83D4A0ADB421Q35610318-BFDA13B4-B453-41DF-90EC-B88D20F7CD91Q35624284-C1204DCA-8D67-4619-936A-E1FB9A34DA8CQ35670447-22B668E1-CD69-4E1D-9B19-1AB4049216C0Q35794381-04F83C6B-C9F4-42C4-99EC-5618665F356FQ35802487-A03B936B-3F2D-472A-A7F2-84833F43744BQ35805127-657A34E0-031F-407B-A13A-34D16C1C7931Q35961016-0607E723-2DE1-4C88-8EF8-6B2D219C9B85Q35961287-15876196-2BA0-43A6-8E09-4C8C0A0BCD60Q36000426-1AFF9C86-5737-4284-8186-3C66E416925EQ36035018-2F0C3FFA-D1EC-4B39-ABC0-8AC4B689F3DEQ36067267-BD08AFBA-72C6-4AFC-A6D7-131CA69A159CQ36125894-53E3DE5E-0E18-4629-B061-833D709276C4Q36125907-F68160C8-4E40-4762-B363-480382437361Q36125917-4AD75F9C-8844-47F1-B3A2-BF0C3799D6DDQ36125925-09C8E76D-DAA1-45E6-94B2-2C2BE8EC79B9Q36125931-D128BFD1-7967-4924-81CF-81A78AF1258AQ36125938-2B8EBC66-9F0E-4ADD-8AE4-A7FEDC4F3E54Q36554858-17C883C2-E2E3-4633-95EC-0FCAAB1B8582Q36651710-E4643638-B6E0-4C27-8F45-AB73C033317A
P2860
Genes in new environments: genetics and evolution in biological control.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
2003年论文
@zh
2003年论文
@zh-cn
name
Genes in new environments: genetics and evolution in biological control.
@ast
Genes in new environments: genetics and evolution in biological control.
@en
type
label
Genes in new environments: genetics and evolution in biological control.
@ast
Genes in new environments: genetics and evolution in biological control.
@en
prefLabel
Genes in new environments: genetics and evolution in biological control.
@ast
Genes in new environments: genetics and evolution in biological control.
@en
P356
P1476
Genes in new environments: genetics and evolution in biological control.
@en
P2093
Maria Navajas
P2888
P304
P356
10.1038/NRG1201
P577
2003-11-01T00:00:00Z