Influence of delayed density and ultraviolet radiation on caterpillar baculovirus infection and mortality

Pepi, Adam; Pan, Vincent; Karban, Richard

doi:10.1101/2021.03.22.436482

Cited by 5 publications

(9 citation statements)

References 49 publications

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“…However, laboratory rearing of A . virginalis from multiple monitored populations suggested a delayed‐density‐dependent rate of viral infection (Pepi et al 2021) as is the case in many Lepidoptera (Anderson & May, 1980; Myers & Cory, 2013, 2016).…”

Section: Discussionmentioning

confidence: 93%

“…Caterpillar populations at the Bodega Marine Reserve and other sites often exhibit high mortality rates after high population density years due to a granulovirus. Monitoring at Bodega and other sites has shown delayed density‐dependent infection and mortality rates due to granulovirus (Pepi et al 2021).…”

Section: Methodsmentioning

confidence: 99%

“…We included precipitation as a covariate based on previous knowledge that precipitation was important to dynamics. We included direct density‐dependence based on previous detection in time series analyses (Karban & de Valpine, 2010), and delayed density‐dependence based on wavelet periodogram results and the observation of delayed density‐dependent mortality from granulovirus in field studies (Pepi et al, 2021). Models with and without a threshold ( C ) were compared using AIC.…”

Section: Methodsmentioning

confidence: 99%

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Altered precipitation dynamics lead to a shift in herbivore dynamical regime

2021

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The interaction between endogenous dynamics and exogenous environmental variation is central to population dynamics. Although investigations into the effects of changing mean climate are widespread, changing patterns of variation in environmental forcing also affect dynamics in complex ways. Using wavelet and time series analyses, we identify a regime shift in the dynamics of a moth species in California from shorter to longer period oscillations over a 34‐year census, and contemporaneous changes in regional precipitation dynamics. Simulations support the hypothesis that shifting precipitation dynamics drove changes in moth dynamics, possibly due to stochastic resonance with delayed density‐dependence. The observed shift in climate dynamics and the interaction with endogenous dynamics mean that predicting future population dynamics will require information on both climatic shifts and their interaction with endogenous density‐dependence, a combination that is rarely available. Consequently, models based on historical data may be unable to predict future population dynamics.

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Section: Discussionmentioning

confidence: 93%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Altered precipitation dynamics lead to a shift in herbivore dynamical regime

2021

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“…This local bi-directional movement produced a positive relationship between larval patches and nearby hilltop moth counts (Figure 2), and a similar positive relationship between hilltop moth counts and nearby larval counts in patches in the following year (Figure 3). Both estimates of larval and adult density are imperfect predictors of the next stage, since there is mortality (e.g., due to disease [30], predation [33]) during the intervening periods that is likely density-dependent. Such density-dependent processes have high potential to remove any correlation between these stages, and therefore the effects of movement were likely substantially stronger before density-dependent mortality.…”

Section: Discussionmentioning

confidence: 99%

“…We also included direct and delayed density dependence terms, intended to represent direct and delayed effects of baculovirus infection on dynamics that we have previously documented [26,30]. The model comparison started from the following full model structure:…”

Section: Caterpillar Time Series Modelsmentioning

confidence: 99%

Hilltopping influences spatial dynamics in a patchy population of tiger moths

Pepi

Grof‐Tisza

Holyoak

et al. 2021

Preprint

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Dispersal is a key driver of spatial population dynamics. Dispersal behavior may be shaped by many factors, such as mate-finding, the spatial distribution of resources, or wind and currents, yet most models of spatial dynamics assume random dispersal. We examined the spatial dynamics of a day-flying moth species (Arctia virginalis) that forms mating aggregations on hilltops (hilltopping) based on long-term adult and larval population censuses. Using time-series models, we compared spatial population dynamics resulting from empirically-founded hilltop-based connectivity indices, and modeled the interactive effects of temperature, precipitation, and density dependence. Model comparisons supported hilltop-based connectivity metrics over random connectivity, suggesting an effect of hilltopping behavior on dynamics. We also found strong interactive effects of temperature and precipitation on dynamics. Simulations based on fitted time series models showed lower patch occupancy and regional synchrony, and higher colonization and extinction rates when hilltopping was included, with potential implications for the probability of persistence of the patch network. Overall, our results show the potential for dispersal behavior to have important effects on spatial population dynamics and persistence, and we advocate inclusion of such non-random dispersal in metapopulation models.

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Hilltopping influences spatial dynamics in a patchy population of tiger moths

et al. 2022

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Dispersal is a key driver of spatial population dynamics. Dispersal behaviour may be shaped by many factors, such as mate-finding, the spatial distribution of resources, or wind and currents, yet most models of spatial dynamics assume random dispersal. We examined the spatial dynamics of a day-flying moth species ( Arctia virginalis ) that forms mating aggregations on hilltops (hilltopping) based on long-term adult and larval population censuses. Using time-series models, we compared spatial population dynamics resulting from empirically founded hilltop-based connectivity indices and modelled the interactive effects of temperature, precipitation and density dependence. Model comparisons supported hilltop-based connectivity metrics including hilltop elevation over random connectivity, suggesting an effect of hilltopping behaviour on dynamics. We also found strong interactive effects of temperature and precipitation on dynamics. Simulations based on fitted time-series models showed lower patch occupancy and regional synchrony, and higher colonization and extinction rates when hilltopping was included, with potential implications for the probability of persistence of the patch network. Overall, our results show the potential for dispersal behaviour to have important effects on spatial population dynamics and persistence, and we advocate the inclusion of such non-random dispersal in metapopulation models.

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Influence of delayed density and ultraviolet radiation on caterpillar baculovirus infection and mortality

Cited by 5 publications

References 49 publications

Altered precipitation dynamics lead to a shift in herbivore dynamical regime

Altered precipitation dynamics lead to a shift in herbivore dynamical regime

Hilltopping influences spatial dynamics in a patchy population of tiger moths

Hilltopping influences spatial dynamics in a patchy population of tiger moths

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