Home About us Contact
|
Home About us Contact | ||
|
|
||
Epiphytic Orchid (epiphytic + orchid)
Selected AbstractsPartitioning nuclear and chloroplast variation at multiple spatial scales in the neotropical epiphytic orchid, Laelia rubescensMOLECULAR ECOLOGY, Issue 9 2004DORSET W. TRAPNELL Abstract Insights into processes that lead to the distribution of genetic variation within plant species require recognition of the importance of both pollen and seed movement. Here we investigate the contributions of pollen and seed movement to overall gene flow in the Central American epiphytic orchid, Laelia rubescens. Genetic diversity and structure were examined at multiple spatial scales in the tropical dry forest of Costa Rica using nuclear (allozymes) and chloroplast restriction fragment length polymorphism (RFLP) markers, which were found to be diverse (allozymes, P = 73.3%; HE = 0.174; cpDNA, HE = 0.741). Nuclear genetic structure (FSTn) was low at every spatial scale (0.005,0.091). Chloroplast markers displayed more structure (0.073,0.254) but relatively similar patterns. Neither genome displayed significant isolation-by-distance. Pollen and seed dispersal rates did not differ significantly from one another (mp/ms = 1.40) at the broadest geographical scale, among sites throughout Costa Rica. However, relative contributions of pollen and seeds to gene flow were scale-dependent, with different mechanisms determining the dominant mode of gene flow at different spatial scales. Much seed dispersal is highly localized within the maternal population, while some seeds enter the air column and are dispersed over considerable distances. At the intermediate scale (10s to 100s of metres) pollinators are responsible for substantial pollen flow. This species appears capable of distributing its genes across the anthropogenically altered landscape that now characterizes its Costa Rican dry forest habitat. [source] Three-dimensional fine-scale genetic structure of the neotropical epiphytic orchid, Laelia rubescensMOLECULAR ECOLOGY, Issue 5 2004Dorset W. Trapnell Abstract Epiphytic plants occupy three-dimensional space, which allows more individuals to be closely clustered spatially than is possible for populations occupying two dimensions. The unique characteristics of epiphytes can act in concert to influence the fine-scale genetic structure of their populations which can, in turn, influence mating patterns and other population phenomena. Three large populations of Laelia rubescens (Orchidaceae) in the Costa Rican seasonal dry forest were sampled at two levels of intensity to determine: (i) whether individual clusters contain more than one genotype, and (ii) the spatial distribution and fine-scale genetic structure of genotypes within populations. Samples were assayed for their multilocus allozyme genotypes and spatial autocorrelation analyses were performed. High levels of genetic diversity, high genotypic diversity and low among-population variation were found. In the larger clusters, multiple genets per cluster were common with discrete clusters containing up to nine genotypes. Spatial autocorrelation analyses indicated significant positive genetic structure at distances of , 45 cm. This result is likely due to the formation of discrete clusters by vegetative reproduction, as well as the establishment of sexually derived progeny within and near maternal clusters. [source] Morphological flexibility across an environmental gradient in the epiphytic orchid, Tolumnia variegata: complicating patterns of fitnessBOTANICAL JOURNAL OF THE LINNEAN SOCIETY, Issue 4 2010MARIELY MORALES Deceit-pollinated orchid species show substantial variation in floral traits, which may be maintained by genetic drift or various forms of selection, or may reflect phenotypic plasticity. We explored how much plasticity occurs in both vegetative and floral traits of Tolumnia variegata (Oncidiinae, Orchidaceae) across two different light environments in Puerto Rico using data from a reciprocal transplant experiment. We also examined how fruit set, a measure of reproductive success and a surrogate for fitness, is associated with this morphological variation, and whether it changes over time. Tolumnia variegata responded to environmental variables in multiple ways. Vegetative characters were more plastic than those associated with sexual reproduction. Transplant effects accounted for significant variation in flower length, lip length, number of inflorescences, peduncle length, leaf length and the total number of ramets, but responses were not always consistent among years. Phenotypic selection on morphological characters was dependent on plant location. The trends detected were complex, and often inconsistent across years, probably as a result of wetter and drier years than average. Overall fruit set was quite variable among plants, averaging 15%, with no significant differences among sun and shade plants. Although reproductive success was similar among sites, habitat heterogeneity and annual variation had an effect on morphological expression, which sometimes modified the trajectories of phenotypic selection. © 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 163, 431,446. [source] | ||||||||||