Browsing by Author "McQuaid, Christopher D."

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    Contrasting environments shape thermal physiology across the spatial range of the sandhopper Talorchestia capensis
    (2015) Baldanzi, Simone; Weidberg, Nicolas F.; Fusi, Marco; Cannicci, Stefano; McQuaid, Christopher D.; Porri, Francesca
    Integrating thermal physiology and species range extent can contribute to a better understanding of the likely effects of climate change on natural populations. Generally, broadly distributed species show variation in thermal physiology between populations. Within their distributional ranges, populations at the edges are assumed to experience more challenging environments than central populations (fundamental niche breadth hypothesis). We have investigated differences in thermal tolerance and thermal sensitivity under increasing/decreasing temperatures among geographically separated populations of the sandhopper Talorchestia capensis along the South African coasts. We tested whether the thermal tolerance and thermal sensitivity of T. capensis differ between central and marginal populations using a non-parametric constraint space analysis. We linked thermal sensitivity to environmental history by using historical climatic data to evaluate whether individual responses to temperature could be related to natural long-term fluctuations in air temperatures. Our results demonstrate that there were significant differences in the thermal response of T. capensis populations to both increasing/decreasing temperatures. Thermal sensitivity (for increasing temperatures only) was negatively related to temperature variability and positively related to temperature predictability. Two different models fitted the geographical distribution of thermal sensitivity and thermal tolerance. Our results confirm that widespread species show differences in physiology among populations by providing evidence of contrasting thermal responses in individuals subject to different environmental conditions at the limits of the species' spatial range. When considering the complex interactions between individual physiology and species ranges, it is not sufficient to consider mean environmental temperatures, or even temperature variability; the predictability of that variability may be critical.
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    Epigenetic variation among natural populations of the South African sandhopper Talorchestia capensis
    (2017) Baldanzi, Simone; Watson, Ralph; McQuaid, Christopher D.; Gouws, Gavin; Porri, Francesca
    Ecological epigenetics is gaining importance within the field of Molecular Ecology, because of its novel evolutionary implications. Linking population ecology to the variation in epigenetic profiles can help explain the effect of environmental conditions on phenotypic differences among populations. While epigenetic changes have largely been investigated through the examination of DNA methylation under laboratory conditions, there is a limited understanding of the extent of DNA methylation variation in wild populations. Assuming that epigenetic variation is important in nature, the conditions experienced by different conspecific populations should result in levels of DNA methylation that are independent of their genetic differentiation. To test this, we investigated levels of DNA methylation among populations of the sandhopper Talorchestia capensis that show phenotypic (physiological) differences in their response to environmental conditions, at the same time evaluating their genetic relationships. Given the high levels of inter-individual physiological variation observed within populations, we further hypothesised that inter-individual differences in methylation would be high. Levels of genetic and epigenetic variation were assessed within and among populations from five localities using the methylation sensitive amplified polymorphism technique. Population differentiation was higher for epigenetics than genetics, with no clear geographical pattern or any relation to biogeography. Likewise, individuals showed greater variability in their epigenetic than their genetic profiles. Four out of five populations showed significant negative relationships between epigenetic and genetic diversity. These results show uncoupling between epigenetic and genetic variation and suggest that: (1) epigenetics are more responsive to local, site-specific environmental conditions than genetics and (2) individual differences in epigenetic profiles drive phenotypic variation within (and most likely among) natural populations. Within populations, epigenetics could offer a level of phenotypic flexibility beyond genetic constraint that allows rapid responses to variable or unpredictable environments, potentially compensating for low genetic variability.
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    Genomics-informed models reveal extensive stretches of coastline under threat by an ecologically dominant invasive species
    (2021) Hudson, Jamie; Castilla, Juan Carlos; Teske, Peter R.; Beheregaray, Luciano B.; Haigh, Ivan D.; McQuaid, Christopher D.; Rius, Marc
    Explaining why some species are widespread, while others are not, is fundamental to biogeography, ecology, and evolutionary biology. A unique way to study evolutionary and ecological mechanisms that either limit species' spread or facilitate range expansions is to conduct research on species that have restricted distributions. Nonindigenous species, particularly those that are highly invasive but have not yet spread beyond the introduced site, represent ideal systems to study range size changes. Here, we used species distribution modeling and genomic data to study the restricted range of a highly invasive Australian marine species, the ascidian Pyura praeputialis. This species is an aggressive space occupier in its introduced range (Chile), where it has fundamentally altered the coastal community. We found high genomic diversity in Chile, indicating high adaptive potential. In addition, genomic data clearly showed that a single region from Australia was the only donor of genotypes to the introduced range. We identified over 3,500 km of suitable habitat adjacent to its current introduced range that has so far not been occupied, and importantly species distribution models were only accurate when genomic data were considered. Our results suggest that a slight change in currents, or a change in shipping routes, may lead to an expansion of the species' introduced range that will encompass a vast portion of the South American coast. Our study shows how the use of population genomics and species distribution modeling in combination can unravel mechanisms shaping range sizes and forecast future range shifts of invasive species.