Host density drives macroparasite abundance across populations of a critically endangered megaherbivore

Stringer, Andrew Paul; Linklater, Wayne L.

doi:10.1007/s00442-015-3319-1

Cited by 16 publications

(19 citation statements)

References 29 publications

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“…There are two reasons for this expectation. First, parasite co-extinctions are predicted to precede host extinctions when parasites require a minimum host density threshold for successful transmission (Anderson & May, 1978), and second, host density strongly predicts parasite abundance at the population level (Stringer & Linklater, 2015).…”

Section: (A) Endoparasitesmentioning

confidence: 99%

Ecological and evolutionary legacy of megafauna extinctions

et al. 2017

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For hundreds of millions of years, large vertebrates (megafauna) have inhabited most of the ecosystems on our planet. During the late Quaternary, notably during the Late Pleistocene and the early Holocene, Earth experienced a rapid extinction of large, terrestrial vertebrates. While much attention has been paid to understanding the causes of this massive megafauna extinction, less attention has been given to understanding the impacts of loss of megafauna on other organisms with whom they interacted. In this review, we discuss how the loss of megafauna disrupted and reshaped ecological interactions, and explore the ecological consequences of the ongoing decline of large vertebrates. Numerous late Quaternary extinct species of predators, parasites, commensals and mutualistic partners were associated with megafauna and were probably lost due to their strict dependence upon them (co-extinctions). Moreover, many extant species have megafauna-adapted traits that provided evolutionary benefits under past megafauna-rich conditions, but are now of no or limited use (anachronisms). Morphological evolution and behavioural changes allowed some of these species partially to overcome the absence of megafauna. Although the extinction of megafauna led to a number of co-extinction events, several species that likely co-evolved with megafauna established new interactions with humans and their domestic animals. Species that were highly specialized in interactions with megafauna, such as large predators, specialized parasites, and large commensalists (e.g. scavengers, dung beetles), and could not adapt to new hosts or prey were more likely to die out. Partners that were less megafauna dependent persisted because of behavioural plasticity or by shifting their dependency to humans via domestication, facilitation or pathogen spill-over, or through interactions with domestic megafauna. We argue that the ongoing extinction of the extant megafauna in the Anthropocene will catalyse another wave of co-extinctions due to the enormous diversity of key ecological interactions and functional roles provided by the megafauna.

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Section: (A) Endoparasitesmentioning

confidence: 99%

Ecological and evolutionary legacy of megafauna extinctions

et al. 2017

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“…If too few parasites migrate with their hosts, parasite density in the new habitat may be too low to maintain occupancy [ 81 ]; indeed, an increasing body of literature suggests that parasite range shifts may lag behind host range shifts [ 82 ], though this phenomenon is not limited to host–parasite interactions [ 83 ]. For example, Hopper et al.…”

Section: Predictors Of Parasite Vulnerabilitymentioning

confidence: 99%

Parasite vulnerability to climate change: an evidence-based functional trait approach

et al. 2017

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Despite the number of virulent pathogens that are projected to benefit from global change and to spread in the next century, we suggest that a combination of coextinction risk and climate sensitivity could make parasites at least as extinction prone as any other trophic group. However, the existing interdisciplinary toolbox for identifying species threatened by climate change is inadequate or inappropriate when considering parasites as conservation targets. A functional trait approach can be used to connect parasites' ecological role to their risk of disappearance, but this is complicated by the taxonomic and functional diversity of many parasite clades. Here, we propose biological traits that may render parasite species particularly vulnerable to extinction (including high host specificity, complex life cycles and narrow climatic tolerance), and identify critical gaps in our knowledge of parasite biology and ecology. By doing so, we provide criteria to identify vulnerable parasite species and triage parasite conservation efforts.

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“…While such effects have been studied experimentally (e.g., Kopp and Jokela 2007;Thieltges et al 2009, Goedknegt et al 2015, surprisingly few studies have attempted to study the effects of invasive species on infection patterns in native hosts in the field (but see Paterson et al 2011Paterson et al , 2013 who used a combined approach). Parasite infection levels in native hosts are not only potentially affected by invasive species but also influenced by many other factors which have been shown to underlie the generally high spatial heterogeneities in infection levels observed in the field (Thieltges and Reise 2007;Byers et al 2008;Wilson et al 2011;Galaktionov et al 2015;Stringer and Linklater 2015). For example, the population density of native hosts often affects infection patterns across many parasite and host taxa (Arneberg 1998;Galaktionov et al 2015;Stringer and Linklater 2015;Searle et al 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Parasite infection levels in native hosts are not only potentially affected by invasive species but also influenced by many other factors which have been shown to underlie the generally high spatial heterogeneities in infection levels observed in the field (Thieltges and Reise 2007;Byers et al 2008;Wilson et al 2011;Galaktionov et al 2015;Stringer and Linklater 2015). For example, the population density of native hosts often affects infection patterns across many parasite and host taxa (Arneberg 1998;Galaktionov et al 2015;Stringer and Linklater 2015;Searle et al 2016). Other factors known to affect infection patterns include host size (Mouritsen et al 2003;Thieltges and Reise 2007), the supply of free-living infective stages (often approximated via preceding intermediate host densities for parasites with complex life cycles; Byers et al 2008;Wilson et al 2011;Galaktionov et al 2015) and environmental variables such as temperature, pH and salinity (Pietrock and Marcogliese 2003;Poulin 2006).…”

Section: Introductionmentioning

confidence: 99%

How invasive oysters can affect parasite infection patterns in native mussels on a large spatial scale

et al. 2019

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Declaration of authorship: MAG, DWT and JVDM conceived and designed the study. MAG, RN, MM, CB and KMW conducted fieldwork. MAG, RN and MM performed parasite dissections. PCL conducted the molecular identification. EOF and AMW compiled data on biotic and environmental variables. MAG conducted the statistical analyses with input from JVDM. MAG and DWT wrote the manuscript with significant contributions of all other authors.

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Host density drives macroparasite abundance across populations of a critically endangered megaherbivore

Cited by 16 publications

References 29 publications

Ecological and evolutionary legacy of megafauna extinctions

Ecological and evolutionary legacy of megafauna extinctions

Parasite vulnerability to climate change: an evidence-based functional trait approach

How invasive oysters can affect parasite infection patterns in native mussels on a large spatial scale

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