Your search keyword '"STARLINGS"' showing total 4 results

1. Genetics and Plasticity Are Responsible for Ecogeographical Patterns in a Recent Invasion.

Author

Stuart, Katarina C., Sherwin, William B., Cardilini, Adam P.A., and Rollins, Lee A.

Subjects

GENETICS, STURNUS vulgaris, GENETIC variation, GROUND cover plants, PHENOTYPIC plasticity, STARLINGS, PHENOTYPES

Abstract

Patterns of covariation between phenotype and environment are presumed to be reflective of local adaptation, and therefore translate to a meaningful influence on an individual's overall fitness within that specific environment. However, these environmentally driven patterns may be the result of numerous and interacting processes, such as genetic variation, epigenetic variation, or plastic non-heritable variation. Understanding the relative importance of different environmental variables on underlying genetic patterns and resulting phenotypes is fundamental to understanding adaptation. Invasive systems are excellent models for such investigations, given their propensity for rapid evolution. This study uses reduced representation sequencing data paired with phenotypic data to examine whether important phenotypic traits in invasive starlings (Sturnus vulgaris) within Australia appear to be highly heritable (presumably genetic) or appear to vary with environmental gradients despite underlying genetics (presumably non-heritable plasticity). We also sought to determine which environmental variables, if any, play the strongest role shaping genetic and phenotypic patterns. We determined that environmental variables—particularly elevation—play an important role in shaping allelic trends in Australian starlings and may also reinforce neutral genetic patterns resulting from historic introduction regime. We examined a range of phenotypic traits that appear to be heritable (body mass and spleen mass) or negligibly heritable (e.g. beak surface area and wing length) across the starlings' Australian range. Using SNP variants associated with each of these phenotypes, we identify key environmental variables that correlate with genetic patterns, specifically that temperature and precipitation putatively play important roles shaping phenotype in this species. Finally, we determine that overall phenotypic variation is correlated with underlying genetic variation, and that these interact positively with the level of vegetation variation within a region, suggesting that ground cover plays an important role in shaping selection and plasticity of phenotypic traits within the starlings of Australia. [ABSTRACT FROM AUTHOR]

Published

2022

2. Signatures of selection in a recent invasion reveal adaptive divergence in a highly vagile invasive species.

Author

Stuart, Katarina C., Cardilini, Adam P. A., Cassey, Phillip, Richardson, Mark F., Sherwin, William B., Rollins, Lee A., and Sherman, Craig D. H.

Subjects

*INTRODUCED species, *STURNUS vulgaris, *SINGLE nucleotide polymorphisms, *STARLINGS

Abstract

A detailed understanding of population genetics in invasive populations helps us to identify drivers of successful alien introductions. Here, we investigate putative signals of selection in Australian populations of invasive common starlings, Sturnus vulgaris, and seek to understand how these have been influenced by introduction history. We used reduced representation sequencing to determine population structure, and identify Single Nucleotide Polymorphisms (SNPs) that are putatively under selection. We found that since their introduction into Australia, starling populations have become genetically differentiated despite the potential for high levels of dispersal, and that starlings have responded to selective pressures imposed by a wide range of environmental conditions across their geographic range. Isolation by distance appears to have played a strong role in determining genetic substructure across the starling's Australian range. Analyses of candidate SNPs that are putatively under selection indicated that aridity, precipitation and temperature may be important factors driving adaptive variation across the starling's invasive range in Australia. However, we also noted that the historic introduction regime may leave footprints on sites flagged as being under adaptive selection, and encourage critical interpretation of selection analyses in non‐native populations. see also the Perspective by Soraia Barbosa. [ABSTRACT FROM AUTHOR]

Published

2021

3. Distribution and abundance of common starling 'Sturnus vulgarus' and common myna 'Acridotheres tristis' in south-east Queensland

Author

Woodall, Peter F

Published

2006

4. Is a handful of genes responsible for the common starling invasion success?

Author

Barbosa S

Subjects

Animals, Australia, Genetics, Population, North America, Introduced Species, Starlings

Abstract

Invasive species have the ability to colonize new habitats across distinct areas of the globe, rapidly adjusting to new biotic and abiotic conditions, and often experiencing little impact from the decrease in effective population size and genetic diversity. Still, as each invading population represents a subsample of the original native distribution, it is common to see variability in terms of the genetic makeup of invading populations and consequently differences in invasion success rates across their non-native range (Blackburn et al., 2017). In a From the Cover article in this issue of Molecular Ecology, Stuart et al. (2020) used genotyping-by-sequencing to explore how landscape and environmental heterogeneity shaped the genetic population structure and adaptation of multiple invasions of the common starling in Australia, and compared it to the patterns observed in North America, examined in Hofmeister et al. (2019). Their results suggest that the common starling worldwide invasion has been driven by a handful of genes that allowed adaptation to extreme environmental conditions and might be the key for differences in invasion success., (© 2021 John Wiley & Sons Ltd.)

Published

2021