Your search keyword '"Robert J. Whelan"' showing total 6 results

1. Patterns of hybridization and asymmetrical gene flow in hybrid zones of the rare Eucalyptus aggregata and common E. rubida

Author

Robert J. Whelan, David L. Field, David J. Ayre, and Andrew G. Young

Subjects

Gene Flow, Eucalyptus, Seed dispersal, Population Dynamics, Plant genetics, Genetic Variation, Eucalyptus aggregata, Flowers, Biology, biology.organism_classification, Gene flow, Genetics, Population, Species Specificity, Seed Dispersal, Botany, Genetic variation, Genetics, Hybridization, Genetic, Original Article, New South Wales, Genetics (clinical), Microsatellite Repeats

Abstract

The patterns of hybridization and asymmetrical gene flow among species are important for understanding the processes that maintain distinct species. We examined the potential for asymmetrical gene flow in sympatric populations of Eucalyptus aggregata and Eucalyptus rubida, both long-lived trees of southern Australia. A total of 421 adults from three hybrid zones were genotyped with six microsatellite markers. We used genealogical assignments, admixture analysis and analyses of spatial genetic structure and spatial distribution of individuals, to assess patterns of interspecific gene flow within populations. A high number of admixed individuals were detected (13.9-40% of individuals), with hybrid populations consisting of F(1) and F(2) hybrids and backcrosses in both parental directions. Across the three sites, admixture proportions were skewed towards the E. aggregata genetic cluster (x=0.56-0.65), indicating that backcrossing towards E. aggregata is more frequent. Estimates of long-term migration rates also indicate asymmetric gene flow, with higher migration rates from E. aggregata to hybrids compared with E. rubida. Taken together, these results indicate a greater genetic input from E. aggregata into the hybrid populations. This asymmetry probably reflects differences in style lengths (E. rubida: ~7 mm, E. aggregata: ~4 mm), which can prevent pollen tubes of smaller-flowered species from fertilizing larger-flowered species. However, analyses of fine-scale genetic structure suggest that localized seed dispersal (40 m) and greater clustering between hybrid and E. aggregata individuals may also contribute to directional gene flow. Our study highlights that floral traits and the spatial distributions of individuals can be useful predictors of the directionality of interspecific gene flow in plant populations.

Published

2010

2. Evidence for ancient genetic subdivision among recently fragmented populations of the endangered shrub Grevillea caleyi (Proteaceae)

Author

David J. Ayre, Tanya M. Llorens, and Robert J. Whelan

Subjects

education.field_of_study, Population fragmentation, Genetic diversity, DNA, Plant, biology, Ecology, Genetic Drift, Population, Genetic Variation, Small population size, biology.organism_classification, Grevillea caleyi, Proteaceae, Genetic divergence, Genetics, Population, Seeds, Genetic structure, Genetic variation, Genetics, Pollen, education, Genetics (clinical), Microsatellite Repeats

Abstract

The genetic effects of population fragmentation cannot be interpreted without understanding the underlying pattern of genetic variation resulting from historic population processes. We used AFLP markers to determine genetic structure and distribution of genetic diversity among populations of an endangered Australian shrub Grevillea caleyi (Proteaceae). Populations that occurred historically on four ridges have new been fragmented to varying degrees, producing some large, relatively pristine populations and very small populations consisting of fewer than 10 adult plants. We found marked population genetic structure (65.9% of genetic variation was among populations) and a significant relationship between genetic and geographic distance (rm=0.564, P=0.004). However, only 14% of overall genetic differentiation was attributable to variation among ridges, compared with 52% among populations within ridges. Moreover, genetic diversity within samples of plants did not vary with either population size or degree of isolation. Thus, the present genetic structure of populations is probably almost entirely the product of historical events. Fine-scale structuring within populations prior to fragmentation may have been caused by limited seed and pollen dispersal, despite a complex suite of (mostly avian) pollinators, and a mixed mating system that allows a large amount of selfing. The combined effects of adult longevity and a soil-stored seed bank may have buffered the recently fragmented populations against the effects of dramatic reductions in numbers of adult plants.

Published

2004

3. Genetic variation and reproductive success of road verge populations of the rare shrub Grevillea barklyana (Proteaceae)

Author

Robert J. Whelan, Patricia M. Hogbin, and David J. Ayre

Subjects

education.field_of_study, Reproductive success, biology, Ecology, Population, Population genetics, Outcrossing, biology.organism_classification, Genetic variation, Genetics, Genetic variability, Road verge, education, Grevillea barklyana, Genetics (clinical)

Abstract

Road verge remnant native vegetation often provides a last refuge for many endangered plant species. However, the value of road verge populations is often questioned because their relatively small size and isolation is expected to reduce both their reproductive potential and their genotypic diversity. We assessed the fitness, genetic variability and links with other populations of small, disjunct and highly disturbed road verge populations of the rare Australian shrub Grevillea barklyana. We found that a set of three road verge populations produced significantly more inflorescences and seed than three nearby nonverge populations. Using three random amplified polymorphic DNA (RAPD) primers, we detected similar levels of genetic variability within and among road verge and nonverge populations. We detected a total of 23 polymorphic marker bands, which allowed us to assign a unique phenotype to each of 60 surveyed plants. AMOVA revealed that only 3.3 per cent of the total variability detected was attributable to variation between the two groups of populations. The majority (80 per cent) of variation occurred among individuals within populations, and 16.7 per cent occurred among populations within each population type. Surprisingly, this pattern of variation is similar to results reported for obligatorily outcrossing species. We conclude that our three road verge populations of G. barklyana have relatively great conservation value, as all were apparently as fecund and as genetically diverse as conspecific nonverge populations.

Published

1998

4. Genetic variation and reproductive success of road verge populations of the rare shrub Grevillea barklyana (Proteaceae)

Author

PATRICIA M HOGBIN, DAVID J AYRE, and ROBERT J WHELAN

Subjects

Genetics, Genetics (clinical)

Published

1998

5. Is the post-disturbance composition of a plant population determined by selection for outcrossed seedlings or by the composition of the seedbank?

Author

Robert J. Whelan, David G. Roberts, David J. Ayre, and Kym Ottewell

Subjects

Perennial plant, biology, Genotype, Ecology, Heterosis, Genetic Variation, Context (language use), biology.organism_classification, Disasters, Genetics, Population, Agronomy, Seedling, Germination, Seedlings, Genetic variation, Seeds, Genetics, Original Article, Selection, Genetic, Grevillea, Genetics (clinical), Selection (genetic algorithm)

Abstract

Seedbanks are expected to buffer populations against disturbances, such as fire, that could alter the genetic composition of smaller, ephemeral adult populations. However, seedling genotypes may be influenced by the spatially heterogeneous nature of both the seedbank and the disturbance (for example, germination may vary with local disturbance) and also by selection acting on germination and post-germination performance. We used microsatellite-DNA surveys of seedlings emerging from the soil-stored seedbanks of Grevillea macleayana after wildfire to compare diversity and spatial structure in seedlings and adults, and through resampling of the seedling data set, to determine whether the resultant adult population reflected the effects of selection or random seedling mortality. The large post-fire seedling cohorts captured the full allelic diversity of the pre-fire adult population. However, we found a mismatch in the genotypic structure of adults and seedlings. Seedlings displayed larger heterozygous deficits than adults; however, over the ensuing 11 years, seedling heterozygosity eventually matched values for the pre-fire adults. Increasing heterozygosity among adults has generally been attributed to heterosis and/or reduction in Wahlund effects via self-thinning. Resampling of early post-fire seedlings to generate samples of equivalent size to survivors at 11 years showed that increases in heterozygosity must be driven by selection favouring outcrossed seed. This finding is important in an evolutionary context but also has implications for the restoration of natural or managed populations where a seedbank is a viable source of recruits.

Published

2013

6. Effects of seed bank disturbance on the fine-scale genetic structure of populations of the rare shrub Grevillea macleayana

Author

David J. Ayre, Robert J. Whelan, and Phillip R. England

Subjects

education.field_of_study, Pollination, Genotype, Ecology, Seed dispersal, Reproduction, Foraging, Population, Australia, Selfing, Genetic Variation, Biology, Environment, Proteaceae, Seed dispersal syndrome, Genetics, Population, Genetic structure, Seeds, Genetics, Biological dispersal, Pollen, education, Genetics (clinical), Ecosystem, Demography

Abstract

Dispersal in most plants is mediated by the movement of seeds and pollen, which move genes across the landscape differently. Grevillea macleayana is a rare, fire-dependent Australian shrub with large seeds lacking adaptations for dispersal; yet it produces inflorescences adapted to pollination by highly mobile vertebrates (eg birds). Interpreting fine-scale genetic structure in the light of these two processes is confounded by the recent imposition of anthropogenic disturbances with potentially contrasting genetic consequences: (1) the unusual foraging behaviour of exotic honeybees and 2. widespread disturbance of the soil-stored seedbank by road building and quarrying. To test for evidence of fine-scale genetic structure within G. macleayana populations and to test the prediction that such structure might be masked by disturbance of the seed bank, we sampled two sites in undisturbed habitat and compared their genetic structure with two sites that had been strongly affected by road building using a test for spatial autocorrelation of genotypes. High selfing levels inferred from genotypes at all four sites implies that pollen dispersal is limited. Consistent with this, we observed substantial spatial clustering of genes at 10 m or less in the two undisturbed populations and argue that this reflects the predicted effects of both high selfing levels and limited seed dispersal. In contrast, at the two sites disturbed by road building, spatial autocorrelation was weak. This suggests there has been mixing of the seed bank, counteracting the naturally low dispersal and elevated selfing due to honeybees. Pollination between near neighbours with reduced relatedness potentially has fitness consequences for G. macleayana in disturbed sites.

Published

2003