Random movement of predators can eliminate trophic cascades in marine protected areas

Jiao, Jing; Pilyugin, Sergei S.; Osenberg, Craig W.

doi:10.1002/ecs2.1421

Cited by 12 publications

(9 citation statements)

References 54 publications

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“…This is because under small mosquito breeding capacity, mosquito larvae would have stronger density-dependent mortality (see Eq. 5); thus, killing more adults (i.e., less air-based concern) can release more space for mosquito larvae, which boosts mosquito growth (i.e., the compensation from density-dependent mortality; see (41-45). With this compensated mosquito growth, average infections also increase (see the higher values at lower adult concern in Fig.…”

Section: Discussionmentioning

confidence: 99%

How public reaction to disease information across scales and the impacts of vector control methods influence disease prevalence and control efficacy

Jiao

Suárez

Fefferman

2021

Preprint

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With the development of social media, the information about vector-borne disease incidence over broad spatial scales can cause demand for local vector control before local risk exists. Anticipatory intervention may still benefit local disease control efforts; however, infection risks are not the only focal concerns governing public demand for vector control. Concern for environmental contamination from pesticides and economic limitations on the frequency and magnitude of control measures also play key roles. Further, public concern may be focused more on ecological factors (i.e., controlling mosquito populations) or on epidemiological factors (i.e., controlling infection-carrying mosquitoes), which may lead to very different control outcomes. Here we introduced a generic Ross-MacDonald model, incorporating these factors under three spatial scales of disease information: local, regional, and global. We tailored and parameterized the model for Zika virus transmitted by Aedes aegypti mosquito. We found that overreaction caused by larger-scale incidence information could decrease average human infections per patch breeding capacity, however, the associated increase in total control effort plays a larger role, which leads to an overall decrease in control efficacy. The shift of focal concerns from epidemiological to ecological risk could relax the negative effect of overreaction on control efficacy when mosquito breeding capacity populations are expected to be large. This work demonstrates that, depending on expected total mosquito breeding capacity population size, and weights of different focal concerns, large-scale disease information can reduce disease infections without lowering control efficacy. Our findings provide guidance for vector-control strategies by considering public reaction through social media.

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Section: Discussionmentioning

confidence: 99%

How public reaction to disease information across scales and the impacts of vector control methods influence disease prevalence and control efficacy

Jiao

Suárez

Fefferman

2021

Preprint

Self Cite

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“…That is, under high epibiont cover of adult mussels, would a crab prefer to cannibalise its own conspecifics [46,47], rather than switching to juvenile mussels? Another interesting future direction is to look at the foraging of crabs as they move in and out of patches containing mussels, some of which might be protected by mussel farmers, akin to marine protected areas [9,10]. A spatially explicit approach to this end, modeling a changing habitat based on mussel density, would also be interesting [14].…”

Section: Discussionmentioning

confidence: 99%

The Effects of Invasive Epibionts on Crab–mussel Communities: A Theoretical Approach to Understand Mussel Population Decline

et al. 2020

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Blue mussels (Mytilus edulis) are an important keystone species that have been declining in the Gulf of Maine. This could be attributed to a variety of complex factors such as indirect effects due to invasion by epibionts, which remains unexplored mathematically. Based on classical optimal foraging theory and anti-fouling defense mechanisms of mussels, we derive an ODE model for crab-mussel interactions in the presence of an invasive epibiont, Didemnum vexillum. The dynamical analysis leads to results on stability, global boundedness and bifurcations of the model. Next, via optimal control methods we predict various ecological outcomes. Our results have key implications for preserving mussel populations in the advent of invasion by non-native epibionts. In particular they help us understand the changing dynamics of local predator-prey communities, due to indirect effects that epibionts confer.1991 Mathematics Subject Classification. Primary: 34C11, 34C23, 49J15; Secondary: 92D25, 92D40.

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“…Movement can influence species interactions and distributions across heterogeneous landscapes [37][38][39][40][41][42][43][44]. Previous studies of fitness-directed movement used a modelling framework similar to ours (i.e.…”

Section: Discussionmentioning

confidence: 99%

Mobility and its sensitivity to fitness differences determine consumer–resource distributions

et al. 2020

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An animal's movement rate (mobility) and its ability to perceive fitness gradients (fitness sensitivity) determine how well it can exploit resources. Previous models have examined mobility and fitness sensitivity separately and found that mobility, modelled as random movement, prevents animals from staying in high-quality patches, leading to a departure from an ideal free distribution (IFD). However, empirical work shows that animals with higher mobility can more effectively collect environmental information and better sense patch quality, especially when the environment is frequently changed by human activities. Here, we model, for the first time, this positive correlation between mobility and fitness sensitivity and measure its consequences for the populations of a consumer and its resource. In the absence of consumer demography, mobility alone had no effect on system equilibria, but a positive correlation between mobility and fitness sensitivity could produce an IFD. In the presence of consumer demography, lower levels of mobility prevented the system from approaching an IFD due to the mixing of consumers between patches. However, when positively correlated with fitness sensitivity, high mobility led to an IFD. Our study demonstrates that the expected covariation of animal movement attributes can drive broadly theorized consumer–resource patterns across space and time and could underlie the role of consumers in driving spatial heterogeneity in resource abundance.

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Random movement of predators can eliminate trophic cascades in marine protected areas

Cited by 12 publications

References 54 publications

How public reaction to disease information across scales and the impacts of vector control methods influence disease prevalence and control efficacy

How public reaction to disease information across scales and the impacts of vector control methods influence disease prevalence and control efficacy

The Effects of Invasive Epibionts on Crab–mussel Communities: A Theoretical Approach to Understand Mussel Population Decline

Mobility and its sensitivity to fitness differences determine consumer–resource distributions

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