All Stories

  1. Climatic changes shaped evolutionary patters in a Hippophae species from Tibet.
  2. Local diversity of angiosperms in continental Europe is associated with small genomes
  3. Genetic Diversity, Evolution, and Biogeography of Seabuckthorn
  4. Climatic Changes and Orogeneses in the Late Miocene of Eurasia: The Main Triggers of an Expansion at a Continental Scale?
  5. Shared evolutionary history may help plants to persist in similar habitats
  6. The Evolutionary Legacy of Diversification Predicts Ecosystem Function
  7. Transcriptome Characterization of Gnetum parvifolium Reveals Candidate Genes Involved in Important Secondary Metabolic Pathways of Flavonoids and Stilbenoids
  8. An Ancient Medicinal Plant at the Crossroads of Modern Horticulture and Genetics: Genetic Resources and Biotechnology of Sea Buckthorn (Hippophae L., Elaeagnaceae)
  9. Environment of habitat types controls evolutionary heritage of plants these habitat types contain
  10. Ecologically diverse and distinct neighbourhoods trigger persistent phenotypic consequences, and amine metabolic profiling detects them
  11. ‘High-co-occurrence genera’: weak but consistent relationships with global richness, niche partitioning, hybridization and decline
  12. Larger phylogenetic distances in litter mixtures: lower microbial biomass and higher C/N ratios but equal mass loss
  13. Phylogenetic patterns are not proxies of community assembly mechanisms (they are far better)
  14. Enemy damage of exotic plant species is similar to that of natives and increases with productivity
  15. Phylogeny and colonization history of Pringlea antiscorbutica (Brassicaceae), an emblematic endemic from the South Indian Ocean Province
  16. Specialists leave fewer descendants within a region than generalists
  17. Disparate relatives: Life histories vary more in genera occupying intermediate environments
  18. Out of the Qinghai–Tibet Plateau: evidence for the origin and dispersal of Eurasian temperate plants from a phylogeographic study of Hippophaë rhamnoides (Elaeagnaceae)
  19. Phylogenetically Poor Plant Communities Receive More Alien Species, Which More Easily Coexist with Natives
  20. Vicariance or long-distance dispersal: historical biogeography of the pantropical subfamily Chrysophylloideae (Sapotaceae)
  21. Species pools along contemporary environmental gradients represent different levels of diversification
  22. Phylogeny and generic limits in the Niemeyera complex of New Caledonian Sapotaceae: evidence of multiple origins of the anisomerous flower
  23. Multi‐gene phylogeny of the pantropical subfamily Chrysophylloideae (Sapotaceae): evidence of generic polyphyly and extensive morphological homoplasy
  24. Effects of population size on genetic diversity, fitness and pollinator community composition in fragmented populations of Anthericum liliago L.
  25. Phylogeny, diagnostic characters and generic limitation of Australasian Chrysophylloideae (Sapotaceae, Ericales): evidence from ITS sequence data and morphology
  26. Analysis of genetic diversity in the endangered tropical tree species Hagenia abyssinica using ISSR markers
  27. Late Quaternary history of Hippophaë rhamnoides L. (Elaeagnaceae) inferred from chalcone synthase intron (Chsi) sequences and chloroplast DNA variation
  28. RAPD-based Analysis of Genetic Diversity and Selection of Lingonberry (Vaccinium vitis-idaea L.) Material for ex situ Conservation
  29. Phylogenetic relationships among New Caledonian Sapotaceae (Ericales): molecular evidence for generic polyphyly and repeated dispersal
  30. RAPD analysis of diploid and tetraploid populations of Aronia points to different reproductive strategies within the genus
  31. Contrasting patterns of spatial genetic structure of diploid and triploid populations of the clonal aquatic species,Butomus umbellatus (Butomaceae), in Central Europe
  32. Elaeagnaceae
  33. Genetic structure detected in a small population of the endangered plant Anthericum liliago (Anthericaceae) by RAPD analysis
  34. Taxonomic synopsis of Hippophae (Elaeagnaceae)
  35. Comparison of Differentiation Estimates Based on Morphometric and Molecular Data, Exemplified by Various Leaf Shape Descriptors and RAPDs in the Genus Chaenomeles (Rosaceae)
  36. Phylogenetic relationships and differentiation among and within populations of Chaenomeles Lindl. (Rosaceae) estimated with RAPDs and isozymes
  37. Genetic relationships in Chaenomeles (Rosaceae) revealed by isozyme analysis
  38. Inter- and intraspecific genetic variation inHippophae (Elaeagnaceae) investigated by RAPD markers
  39. Combined analyses of RAPDs, cpDNA and morphology demonstrate spontaneous hybridization in the plant genus Chaenomeles
  40. Effects of life history traits and sampling strategies on genetic diversity estimates obtained with RAPD markers in plants
  41. Population genetic structure in the dioecious pioneer plant species Hippophae rhamnoides investigated by random amplified polymorphic DNA (RAPD) markers
  42. Genetic diversity inChaenomeles (Rosaceae) revealed by RAPD analysis
  43. THE USE OF INTERSPECIFIC CROSSES IN MALUS TO MAP THE GENES OF CHARACTERS IMPORTANT FOR APPLE ROOTSTOCK BREEDING
  44. A NEW APPROACH TO OBTAIN POLYPLOID FORMS OF APPLE
  45. GTPase activity of bacteriophage T4 sheath protein