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1. Reactive anti-predator behavioral strategy shaped by predator characteristics

   https://doi.org/10.1371/journal.pone.0256147  

   Palmer, Meredith S.; Packer, Craig (August 2021, PLOS ONE)

   Yue, Bi-Song (Ed.)

   Large mammalian herbivores use a diverse array of strategies to survive predator encounters including flight, grouping, vigilance, warning signals, and fitness indicators. While anti-predator strategies appear to be driven by specific predator traits, no prior studies have rigorously evaluated whether predator hunting characteristics predict reactive anti-predator responses. We experimentally investigated behavioral decisions made by free-ranging impala, wildebeest, and zebra during encounters with model predators with different functional traits. We hypothesized that the choice of response would be driven by a predator’s hunting style (i.e., ambush vs. coursing) while the intensity at which the behavior was performed would correlate with predator traits that contribute to the prey’s relative risk (i.e., each predator’s prey preference, prey-specific capture success, and local predator density). We found that the choice and intensity of anti-predator behaviors were both shaped by hunting style and relative risk factors. All prey species directed longer periods of vigilance towards predators with higher capture success. The decision to flee was the only behavior choice driven by predator characteristics (capture success and hunting style) while intensity of vigilance, frequency of alarm-calling, and flight latency were modulated based on predator hunting strategy and relative risk level. Impala regulated only the intensity of their behaviors, while zebra and wildebeest changed both type and intensity of response based on predator traits. Zebra and impala reacted to multiple components of predation threat, while wildebeest responded solely to capture success. Overall, our findings suggest that certain behaviors potentially facilitate survival under specific contexts and that prey responses may reflect the perceived level of predation risk, suggesting that adaptive functions to reactive anti-predator behaviors may reflect potential trade-offs to their use. The strong influence of prey species identity and social and environmental context suggest that these factors may interact with predator traits to determine the optimal response to immediate predation threat. 

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2. Dynamics and pattern formation of a diffusive predator–prey model with predator-taxis

   https://doi.org/10.1142/S0218202518400158  

   Wu, Sainan; Wang, Jinfeng; Shi, Junping (October 2018, Mathematical Models and Methods in Applied Sciences)
3. Pattern formation in diffusive predator-prey systems with predator-taxis and prey-taxis

   https://doi.org/10.3934/dcdsb.2020162  

   Wang, Jinfeng; Wu, Sainan; Shi, Junping (January 2021, Discrete & Continuous Dynamical Systems - B)

   null (Ed.)
4. Killing the predator: impacts of highest-predator mortality on the global-ocean ecosystem structure

   https://doi.org/10.5194/bg-21-2493-2024  

   Talmy, David; Carr, Eric; Rajakaruna, Harshana; Våge, Selina; Willem_Omta, Anne (January 2024, Biogeosciences)

   Abstract. Recent meta-analyses suggest that microzooplankton biomass density scales linearly with phytoplankton biomass density, suggesting a simple, general rule may underpin trophic structure in the global ocean. Here, we use a set of highly simplified food web models, solved within a global general circulation model, to examine the core drivers of linear predator–prey scaling. We examine a parallel food chain model which assumes microzooplankton grazers feed on distinct size classes of phytoplankton and contrast this with a diamond food web model allowing shared microzooplankton predation on a range of phytoplankton size classes. Within these two contrasting model structures, we also evaluate the impact of fixed vs. density-dependent microzooplankton mortality. We find that the observed relationship between microzooplankton predators and prey can be reproduced with density-dependent mortality on the highest predator, regardless of choices made about plankton food web structure. Our findings point to the importance of parameterizing mortality of the highest predator for simple food web models to recapitulate trophic structure in the global ocean. 

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5. Predator dispersal influences predator distribution but not prey diversity in pitcher plant microbial metacommunities

   https://doi.org/10.1002/ecy.3912  

   Cuellar‐Gempeler, Catalina; terHorst, Casey P.; Mason, Olivia U.; Miller, Thomas (January 2023, Ecology)

   Abstract The spatial distribution of predators can affect both the distribution and diversity of their prey. Therefore, differences in predator dispersal ability that affect their spatial distribution, could also affect prey communities. Here, we use the microbial communities within pitcher plant leaves as a model system to test the relationship between predator (protozoa) dispersal ability and distribution, and its consequences for prey (bacteria) diversity and composition. We hypothesized that limited predator dispersal results in clustered distributions and heterogeneous patches for prey species, whereas wide predator dispersal and distribution could homogenize prey metacommunities. We analyzed the distribution of two prominent bacterivore protozoans from a 2‐year survey of an intact field ofSarracenia purpureapitcher plants, and found a clustered distribution ofTetrahymenaand homogeneous distribution ofPoterioochromonas. We manipulated the sources of protozoan colonists and recorded protozoan recruitment and bacterial diversity in target leaves in a field experiment. We found the large ciliate,Tetrahymena, was dispersal limited and occupied few leaves, whereas the small flagellatePoterioochromonaswas widely dispersed. However, the bacterial communities these protozoans feed on was unaffected by clustering ofTetrahymena, but likely influenced byPoterioochromonasand other bacterivores dispersing in the field. We propose that bacterial communities in this system are structured by a combination of well dispersed bacterivores, bacterial dispersal, and bottom‐up mechanisms. Clustered predators could become strong drivers of prey communities if they were specialists or keystone predators, or if they exerted a dominant influence on other predators in top‐down controlled systems. Linking dispersal ability within trophic levels and its consequences for trophic dynamics can lead to a more robust perspective on trophic metacommunities. 

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