Immune and environment‐driven gene expression during invasion: An eco‐immunological application of RNA‐Seq

Selechnik, D.; Richardson, Mark F.; Shine, Richard; Brown, Gregory P.; Rollins, Lee A.

doi:10.1002/ece3.5249

Cited by 16 publications

(19 citation statements)

References 66 publications

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“…While studies of cane toads have shown that traits may have curvilinear responses with distance along an invasion gradient [36][37][38], here, I provide a clear demonstration across two transects that the trait of dispersal capacity itself can have a nonlinear relationship with distance from the core and, thus, its characterization requires more than two observations (e.g. core versus frontline).…”

Section: Discussionmentioning

confidence: 68%

Flight capacity increases then declines from the core to the margins of an invasive species' range

Merwin

2019

Biol. Lett.

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Individuals that disperse farther than other individuals are more likely to be on the frontlines of spreading populations and may be more likely to mate with one another as a consequence of their spatial proximity. Over generations, this process—known as spatial sorting—can produce patterns of increasing dispersal ability from a population's core towards the spreading front. By contrast, when the spread of a population is limited by the availability of suitable habitat, theory predicts that range boundaries can select against more dispersive phenotypes and produce patterns of decreasing dispersal capacity towards population margins. In a common garden study of invasive kudzu bugs ( Megacopta cribraria )—which are limited by the availability of hostplants in their southern and western margins—I show that midrange individuals fly 49% farther than individuals in the core and 37% farther than individuals at margins. This result highlights that other processes, such as maternal effects or selection at range boundaries, may create more complicated patterns of dispersal ability across landscapes than predicted by models of spatial sorting alone.

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Section: Discussionmentioning

confidence: 68%

Flight capacity increases then declines from the core to the margins of an invasive species' range

Merwin

2019

Biol. Lett.

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“…Morphological and physiological traits underlie this accelerated expansion, yet it is also clear that behavioural traits have evolved across this invasion; western cane toads exhibit bolder behaviour than eastern toads (Gruber et al, ). Notably, these changes have occurred despite low genetic diversity in Australian toads (Lillie, Shine, & Belov, ; Selechnik, Richardson, Shine, Brown, & Rollins, ; Slade & Moritz, ). Environmental and intrinsic factors (e.g., genetic components) that may affect behavioural traits have been previously studied (Rollins, Richardson, & Shine, ; Selechnik, Richardson, Shine, DeVore, et al, ; Urban et al, ).…”

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

A comparison of nonlethal sampling methods for amphibian gut microbiome analyses

Zhou

Nelson

López

et al. 2020

Molecular Ecology Resources

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“…Conversely, at the invasion‐front, where there is a strong evolutionary pressure for dispersal ability via both natural selection and spatial sorting (Brown et al, 2014; Phillips & Perkins, 2019), increased host resistance might be favoured if parasite infection reduces dispersal ability. Moreover, some sets of immune genes are upregulated at the invasion‐front (Selechnik et al, 2019a), suggesting that heightened, possibly non‐specific, immune responses arising from exposure to other pathogens or conditions at the invasion‐front may increase resistance of toads (Brown et al, 2018; Mayer et al, 2021). This hypothesis is supported by the reduced longevity of larvae when exposed to skin secretions of toads from the invasion‐front.…”

Section: Discussionmentioning

confidence: 99%

Host defense or parasite cue: Skin secretions mediate interactions between amphibians and their parasites

et al. 2021

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Amphibian skin secretions (substances produced by the amphibian plus microbiota) plausibly act as a first line of defense against parasite/pathogen attack, but may also provide chemical cues for pathogens. To clarify the role of skin secretions in host–parasite interactions, we conducted experiments using cane toads (Rhinella marina) and their lungworms (Rhabdias pseudosphaerocephala) from the range‐core and invasion‐front of the introduced anurans’ range in Australia. Depending on the geographical area, toad skin secretions can reduce the longevity and infection success of parasite larvae, or attract lungworm larvae and enhance their infection success. These striking differences between the two regions were due both to differential responses of the larvae, and differential effects of the skin secretions. Our data suggest that skin secretions play an important role in host–parasite interactions in anurans, and that the arms race between a host and parasite can rapidly generate spatial variation in critical features of that interaction.

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Immune and environment‐driven gene expression during invasion: An eco‐immunological application of RNA‐Seq

Cited by 16 publications

References 66 publications

Flight capacity increases then declines from the core to the margins of an invasive species' range

Flight capacity increases then declines from the core to the margins of an invasive species' range

A comparison of nonlethal sampling methods for amphibian gut microbiome analyses

Host defense or parasite cue: Skin secretions mediate interactions between amphibians and their parasites

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