Almost forgotten or latest practice? AFLP applications, analyses and advances.
about
Dissecting comimetic radiations in Heliconius reveals divergent histories of convergent butterfliesReticulate evolution and taxonomic concepts in the Ranunculus auricomus complex (Ranunculaceae): insights from analysis of morphological, karyological and molecular data.A Complex System of Glacial Sub-Refugia Drives Endemic Freshwater Biodiversity on the Tibetan PlateauBoxer crabs induce asexual reproduction of their associated sea anemones by splitting and intraspecific theftEfficient Detection of Novel Nuclear Markers for Brassicaceae by Transcriptome SequencingGenetic structure and seed-mediated dispersal rates of an endangered shrub in a fragmented landscape: a case study for Juniperus communis in northwestern EuropeTesting mitochondrial sequences and anonymous nuclear markers for phylogeny reconstruction in a rapidly radiating group: molecular systematics of the Delphininae (Cetacea: Odontoceti: Delphinidae)Distinct migratory and non-migratory ecotypes of an endemic New Zealand eleotrid (Gobiomorphus cotidianus) - implications for incipient speciation in island freshwater fish speciesPlant speciation in continental island floras as exemplified by Nigella in the Aegean ArchipelagoSystematics of Simplicia Kirk (Poaceae, Agrostidinae) - an endemic, threatened New Zealand grass genusGeography shapes the phylogeny of frailejones (Espeletiinae Cuatrec., Asteraceae): a remarkable example of recent rapid radiation in sky islandsKey processes for Cheirolophus (Asteraceae) diversification on oceanic islands inferred from AFLP dataImproving AFLP analysis of large-scale patterns of genetic variation--a case study with the Central African lianas Haumania spp (Marantaceae) showing interspecific gene flow.A call for more transparent reporting of error rates: the quality of AFLP data in ecological and evolutionary research.Validation of outlier loci through replication in independent data sets: a test on Arabis alpina.Eukaryotic transcriptomics in silico: optimizing cDNA-AFLP efficiencyStatistical analysis of amplified fragment length polymorphism data: a toolbox for molecular ecologists and evolutionists.A novel method to infer the origin of polyploids from Amplified Fragment Length Polymorphism data reveals that the alpine polyploid complex of Senecio carniolicus (Asteraceae) evolved mainly via autopolyploidy.Accurate DNA fragment sizing by capillary electrophoresis with laser-induced fluorescence array for detection of sequence specificity of DNA damageAFLP analysis reveals a lack of phylogenetic structure within Solanum section Petota.Large-scale Gene Ontology analysis of plant transcriptome-derived sequences retrieved by AFLP technologyEvaluating the impact of scoring parameters on the structure of intra-specific genetic variation using RawGeno, an R package for automating AFLP scoring.Validation of phylogenetic signals in amplified fragment length data: testing the utility and reliability in closely related taxa.Genetic population structure of sympatric and allopatric populations of Baltic ciscoes (Coregonus albula complex, Teleostei, Coregonidae).Geographic barriers and Pleistocene climate change shaped patterns of genetic variation in the Eastern Afromontane biodiversity hotspot.Allopolyploid speciation and ongoing backcrossing between diploid progenitor and tetraploid progeny lineages in the Achillea millefolium species complex: analyses of single-copy nuclear genes and genomic AFLP.Amplified fragment length homoplasy: in silico analysis for model and non-model speciesGenetic species identification and population structure of Halophila (Hydrocharitaceae) from the Western Pacific to the Eastern Indian Ocean.Introgressive hybridization and the evolutionary history of the herring gull complex revealed by mitochondrial and nuclear DNADiscrimination of Picea chihuahuana Martinez populations on the basis of climatic, edaphic, dendrometric, genetic and population traitsCost-effective fluorescent amplified fragment length polymorphism (AFLP) analyses using a three primer system.Current trends in microsatellite genotyping.An objective, rapid and reproducible method for scoring AFLP peak-height data that minimizes genotyping error.The relative contribution of band number to phylogenetic accuracy in AFLP data sets.Nonspecific PCR amplification by high-fidelity polymerases: implications for next-generation sequencing of AFLP markers.Effectiveness of AFLPs and retrotransposon-based markers for the identification of Portuguese grapevine cultivars and clones.A hybrid BAC physical map of potato: a framework for sequencing a heterozygous genome.Population structure and linkage disequilibrium unravelled in tetraploid potato.AFLPMax: a user-friendly application for computing the optimal number of amplified fragment length polymorphism markers needed in phylogenetic reconstruction.Unexpected fine-scale population structure in a broadcast-spawning Antarctic marine mollusc
P2860
Q24622925-3281E634-E757-44E6-B455-5C04F09ED495Q24634700-E337B0EC-9D04-4EC7-A541-FE6E354B8260Q28598142-8E4A7212-FD34-4B51-9F50-7775ED62C01CQ28602049-FC877C8D-4EE9-48BB-A3F0-0BF1AF2955BEQ28629535-3F17E543-CC4D-4AA0-9B17-7036B5E7E869Q28740282-1FF1D799-3078-4F28-8897-65CBA2A07D36Q28750330-315A93FB-1E58-42D0-9006-B7A18B843F31Q28755327-CE23C1BB-C0D1-4950-ABA7-45B1B0DB5E6FQ28756065-8D22CDEB-E8D3-4930-AC5C-A7906E4F1351Q28817317-23835121-01E2-46C5-9754-803D00BF7C79Q28817478-5CE006EA-24DA-47CE-8AA7-8AC508BB51CDQ30000644-BF303D19-707F-4C14-B685-8C3146C9CC26Q30317886-2328F267-522E-4DB0-A088-259F8206F762Q30575822-4E74D602-6AE2-429F-A982-9D58E8A4CA7BQ30881886-8929F5B5-0EEF-4FD0-A7CF-C772813F7D4FQ30931427-701223D8-8FCB-4F3B-ABA6-671A8CB6B98FQ31127277-DF80A78C-6B00-4B3C-A958-914664B9B51EQ31149139-A2336AED-D204-4003-B82C-6FB431CE2167Q33319267-406BA28A-FEB3-4703-917C-E70FA10D121FQ33334633-2C7FF97B-B6A7-42FD-8835-B51E3BBB23E2Q33354750-3FC0AD21-3354-4B17-B9DA-1B16EF0943CCQ33403053-00A3EF41-3624-4D5B-BA84-2B09D66ADB33Q33417995-E1E39EDE-2A76-49F6-A983-4E777499E083Q33547167-F505367C-2860-442C-BFE7-127A238D162DQ33551704-BD0D69B8-4D33-4901-BF38-3AE684D6409CQ33553878-E1CAF7B7-BC4E-491D-9E25-6D2742F97BADQ33575200-25C344DC-2635-4BFB-B2D1-DA5EAC0DB351Q33631814-D8ADF880-8F02-40C9-ADF5-1E89758D0282Q33743699-A7618BD4-BEF6-4413-82CC-1E308632F505Q33797049-1AD369E2-6651-43D5-B9D0-345A206A2B44Q33868114-09AB4EDD-3F93-4452-8506-C4E2BD717A90Q33897404-A338A389-EA21-4082-9502-5AA5B3D0E43EQ33903009-A6436C9F-BD68-4505-836A-2EDF1792F94CQ33995045-26F04C48-C2D3-4B9D-A4D9-E2028D4B6B31Q34007704-80410255-795C-49B2-BF34-0AFBE6325FBEQ34073823-EA551120-1048-4D0C-8360-2F3C130CDABCQ34091817-A81B42CB-14A4-4F2D-AFE1-25A24DD17ADCQ34123730-60739D65-76FA-4196-B684-57F0B4AB9A3DQ34135931-88EB14D4-072B-45AE-B2CA-BEE0F179BEA2Q34189454-0B1E7412-483F-4387-94B9-91883C9FF1FD
P2860
Almost forgotten or latest practice? AFLP applications, analyses and advances.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Almost forgotten or latest practice? AFLP applications, analyses and advances.
@ast
Almost forgotten or latest practice? AFLP applications, analyses and advances.
@en
type
label
Almost forgotten or latest practice? AFLP applications, analyses and advances.
@ast
Almost forgotten or latest practice? AFLP applications, analyses and advances.
@en
prefLabel
Almost forgotten or latest practice? AFLP applications, analyses and advances.
@ast
Almost forgotten or latest practice? AFLP applications, analyses and advances.
@en
P1476
Almost forgotten or latest practice? AFLP applications, analyses and advances
@en
P2093
Andrew C Clarke
P304
P356
10.1016/J.TPLANTS.2007.02.001
P577
2007-02-14T00:00:00Z