Global Climate Change as a Driver of Bottom-Up and Top-Down Factors in Agricultural Landscapes and the Fate of Host-Parasitoid Interactions

Chidawanyika, Frank; Mudavanhu, Pride; Nyamukondiwa, Casper

doi:10.3389/fevo.2019.00080

Cited by 62 publications

(52 citation statements)

References 165 publications

(223 reference statements)

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“…This will allow for a more effective assessment of constraints of biological control associated with thermal stress prior to organismal loss of physiological function, e.g. through thermal performance curves (see discussions in [ 37 ]). While CTLs are only a measure of the fate of an organism at extreme temperatures [ 92 , 93 ], they can still be useful in predictive models associated with population dynamics [ 27 , 37 , 94 ].…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, thermal performance is highly enigmatic and varies among species, ontogeny, age [ 36 ] and size [ 29 ]. Moreover, natural enemy efficacy also depends on the fate of bottom-up and top-down effects, which have been reported to favour pest and vector species [ 37 ]. As such, even slight alterations to temperature can compromise or heighten species fitness, community interactions and structure [ 38 , 39 ].…”

Section: Introductionmentioning

confidence: 99%

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Implications of increasing temperature stress for predatory biocontrol of vector mosquitoes

et al. 2020

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Background Predators play a critical role in regulating larval mosquito prey populations in aquatic habitats. Understanding predator-prey responses to climate change-induced environmental perturbations may foster optimal efficacy in vector reduction. However, organisms may differentially respond to heterogeneous thermal environments, potentially destabilizing predator-prey trophic systems. Methods Here, we explored the critical thermal limits of activity (CTLs; critical thermal-maxima [CTmax] and minima [CTmin]) of key predator-prey species. We concurrently examined CTL asynchrony of two notonectid predators (Anisops sardea and Enithares chinai) and one copepod predator (Lovenula falcifera) as well as larvae of three vector mosquito species, Aedes aegypti, Anopheles quadriannulatus and Culex pipiens, across instar stages (early, 1st; intermediate, 2nd/3rd; late, 4th). Results Overall, predators and prey differed significantly in CTmax and CTmin. Predators generally had lower CTLs than mosquito prey, dependent on prey instar stage and species, with first instars having the lowest CTmax (lowest warm tolerance), but also the lowest CTmin (highest cold tolerance). For predators, L. falcifera exhibited the narrowest CTLs overall, with E. chinai having the widest and A. sardea intermediate CTLs, respectively. Among prey species, the global invader Ae. aegypti consistently exhibited the highest CTmax, whilst differences among CTmin were inconsistent among prey species according to instar stage. Conclusion These results point to significant predator-prey mismatches under environmental change, potentially adversely affecting natural mosquito biocontrol given projected shifts in temperature fluctuations in the study region. The overall narrower thermal breadth of native predators relative to larval mosquito prey may reduce natural biotic resistance to pests and harmful mosquito species, with implications for population success and potentially vector capacity under global change.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Implications of increasing temperature stress for predatory biocontrol of vector mosquitoes

et al. 2020

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“…Ultimately, these effects will hinder IPM tactics ( Oerke 2006 , Maino et al 2017 , Taylor et al 2018 , Matzrafi 2019 ). GCC will have a negative impact on biological control, causing asynchrony between hosts and parasitoids, while lowering the efficacy of pesticide-free management techniques ( Chidawanyika et al 2019 ). Phenology changes and environmental cues altered by GCC will create plant–pollinator mismatch, ultimately reducing the production of seed and fruit commodities ( Forrest 2015 ).…”

Section: Debates Introductionmentioning

confidence: 99%

Synergisms in Science: Climate Change and Integrated Pest Management Through the Lens of Communication—2019 Student Debates

Holt

Bernaola

Britt

et al. 2020

Journal of Insect Science

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Every year, the Student Debates Subcommittee (SDS) of the Student Affairs Committee (SAC) for the annual Entomological Society of America (ESA) meeting organizes the Student Debates. This year, the SAC selected topics based on their synergistic effect or ability to ignite exponential positive change when addressed as a whole. For the 2019 Student Debates, the SAC SDS identified these topic areas for teams to debate and unbiased introduction speakers to address: 1) how to better communicate science to engage the public, particularly in the area of integrated pest management (IPM), 2) the influential impacts of climate change on agriculturally and medically relevant insect pests, and 3) sustainable agriculture techniques that promote the use of IPM to promote food security. Three unbiased introduction speakers gave a foundation for our audience to understand each debate topic, while each of six debate teams provided a strong case to support their stance or perspective on a topic. Debate teams submitted for a competitive spot for the annual ESA Student Debates and trained for the better part of a year to showcase their talents in presenting logical arguments for a particular topic. Both the debate teams and unbiased introduction speakers provided their insight toward a better understanding of the complexities of each topic and established a foundation to delve further into the topics of science advocacy and communication, climate change, and the many facets of integrated pest management.

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“…Intrinsic mechanisms refer to direct effects of climate-associated abiotic parameters on an organism (Cornelissen 2011;Robinet & Roques 2010). Extrinsic mechanisms refer to indirect effects, mediated for instance through shifted distributions, altered phenology or physiology of lower trophic levels (Han et al 2019;Kaplan et al 2016;Kharouba et al 2018;Jeffs & Lewis 2013;Pincebourde et al 2017;Chidawanyika et al 2019;Damien & Tougeron 2019;Renner & Zohner 2018). While investigating indirect effects of climate change across trophic levels is crucial to predict community shifts (van der Putten et al 2010), understanding the direct impact of climate change onto each trophic level is essential to characterize the underlying mechanisms (Thomson et al 2010).…”

Section: Introductionmentioning

confidence: 99%

“…For example, temperature was identified as a key determinant of parasitoid developmental rates, survival, fecundity, parasitism and dispersal (Hance et al 2007;Walther et al 2002;Selvaraj et al 2013). Thermal performance curves revealed that increasing temperatures enhance parasitism success until a maximum at optimum temperature, beyond which any increase in temperature leads to a decline of parasitism success (Furlong & Zalucki 2017;Chidawanyika et al 2019). Optimum temperature was repeatedly reported to be lower for parasitoids than for their hosts, indicating that parasitoids may be more susceptible to elevated temperature than herbivores, resulting in lowered biocontrol efficacy over time (Furlong & Zalucki 2017).…”

Section: Introductionmentioning

confidence: 99%

NATURAL ENEMIES OF HERBIVORES MAINTAIN THEIR BIOLOGICAL CONTROL POTENTIAL UNDER FUTURE CO₂, TEMPERATURE AND PRECIPITATION PATTERNS

Doan

Pfander

Guyer

et al. 2020

Preprint

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Climate change will profoundly alter the physiology and ecology of plants, insect herbivores and their natural enemies, resulting in strong effects on multitrophic interactions. Yet, manipulative studies that investigate the direct combined impacts of changes in CO2, temperature, and precipitation on this group of organisms remain rare. Here, we assessed how three day exposure to elevated CO2, increased temperature, and decreased precipitation affect the performance and predation success on species from four major groups of natural enemies of insect herbivores: an entomopathogenic nematode, a wolf spider, a ladybug and a parasitoid wasp. Future climatic conditions (RCP 8.5), entailing a 28% decrease in precipitation, a 3.4°C raise in temperature and a 400 ppm increase in CO2 levels, slightly reduced the survival of entomopathogenic nematodes, but had no effect on the survival of other species. Predation success was not negatively affected in any of the tested species, but was even increased for wolf spiders and entomopathogenic nematodes. Factorial manipulation of climate variables revealed a positive effect of reduced soil moisture on nematode infectivity, but not of increased temperature or elevated CO2. These results suggest that natural enemies of herbivores are well adapted to short term changes in climatic conditions and may not suffer from direct negative effects of future climates. These findings provide mechanistic insights that will inform future efforts to disentangle the complex interplay of biotic and abiotic factors that drive climate-dependent changes in multitrophic interaction networks.

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Global Climate Change as a Driver of Bottom-Up and Top-Down Factors in Agricultural Landscapes and the Fate of Host-Parasitoid Interactions

Cited by 62 publications

References 165 publications

Implications of increasing temperature stress for predatory biocontrol of vector mosquitoes

Implications of increasing temperature stress for predatory biocontrol of vector mosquitoes

Synergisms in Science: Climate Change and Integrated Pest Management Through the Lens of Communication—2019 Student Debates

NATURAL ENEMIES OF HERBIVORES MAINTAIN THEIR BIOLOGICAL CONTROL POTENTIAL UNDER FUTURE CO₂, TEMPERATURE AND PRECIPITATION PATTERNS

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Global Climate Change as a Driver of Bottom-Up and Top-Down Factors in Agricultural Landscapes and the Fate of Host-Parasitoid Interactions

Cited by 62 publications

References 165 publications

Implications of increasing temperature stress for predatory biocontrol of vector mosquitoes

Implications of increasing temperature stress for predatory biocontrol of vector mosquitoes

Synergisms in Science: Climate Change and Integrated Pest Management Through the Lens of Communication—2019 Student Debates

NATURAL ENEMIES OF HERBIVORES MAINTAIN THEIR BIOLOGICAL CONTROL POTENTIAL UNDER FUTURE CO2, TEMPERATURE AND PRECIPITATION PATTERNS

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NATURAL ENEMIES OF HERBIVORES MAINTAIN THEIR BIOLOGICAL CONTROL POTENTIAL UNDER FUTURE CO₂, TEMPERATURE AND PRECIPITATION PATTERNS