Elevated atmospheric concentrations of carbon dioxide reduce monarch tolerance and increase parasite virulence by altering the medicinal properties of milkweeds

Decker, Leslie E.; Roode, Jacobus C. de; Hunter, Mark D.

doi:10.1111/ele.13101

Cited by 28 publications

(20 citation statements)

References 88 publications

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“…Trade-offs between different defence strategies may be particularly relevant for hosts that face consistent parasite pressure, yet live in variable environments, such as Galápagos mockingbirds. The ability to mount a successful defence may become even more challenging in the face of a changing climate [25,62]. Recent models predict increased variability and magnitude of El Niñ o and La Niñ a events [63], which are the primary climatic cycles that drive rainfall patterns in the Galápagos [34].…”

Section: Discussionmentioning

confidence: 99%

Annual environmental variation influences host tolerance to parasites

et al. 2019

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When confronted with a parasite or pathogen, hosts can defend themselves by resisting or tolerating the attack. While resistance can be diminished when resources are limited, it is unclear how robust tolerance is to changes in environmental conditions. Here, we investigate the sensitivity of tolerance in a single host population living in a highly variable environment. We manipulated the abundance of an invasive parasitic fly, Philornis downsi, in nests of Galápagos mockingbirds (Mimus parvulus) over four field seasons and measured host fitness in response to parasitism. Mockingbird tolerance to P. downsi varied significantly among years and decreased when rainfall was limited. Video observations indicate that parental provisioning of nestlings appears key to tolerance: in drought years, mockingbirds likely do not have sufficient resources to compensate for the effects of P. downsi. These results indicate that host tolerance is a labile trait and suggest that environmental variation plays a major role in mediating the consequences of host -parasite interactions.

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Section: Discussionmentioning

confidence: 99%

Annual environmental variation influences host tolerance to parasites

et al. 2019

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“…We expected sequestration profiles to mirror changes in plant chemistry induced by eCO 2 because factors that alter phytochemistry and consumption rates should also influence the types and amounts of PSMs monarchs sequester. We also predicted that changes in cardenolides and reductions in the nutritional quality of larval host plants grown under eCO 2 (Decker, de Roode, & Hunter, ; Robinson et al, ) would cause declines in the quality of the insect flight phenotype: smaller, thinner and rounder wings with lower wing loading values. Feeding on lower quality food with different types and amounts of cardenolides may engender a metabolic cost inflicting stress upon the insect and inducing morphological changes.…”

Section: Introductionmentioning

confidence: 99%

Phytochemical changes in milkweed induced by elevated CO₂ alter wing morphology but not toxin sequestration in monarch butterflies

et al. 2019

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Environmental change has the potential to influence trophic interactions by altering the defensive phenotype of prey. Here, we examine the effects of a pervasive environmental change driver, elevated atmospheric concentrations of CO2 (eCO2), on toxin sequestration and flight morphology of a specialist herbivore. We fed monarch butterfly larvae, Danaus plexippus, foliage from four milkweed, Asclepias, species of varying chemical defence profiles grown under either ambient or eCO2. We also infected a subset of these herbivores with a protozoan parasite, Ophryocystis elektroscirrha, to understand how infection and environmental change combine to alter herbivore defences. We measured changes in phytochemistry induced by eCO2 and assessed cardenolide, toxic steroid, sequestration and wing morphology of butterflies. Monarchs compensated for lower plant cardenolide concentrations under eCO2 by increasing cardenolide sequestration rate, maintaining similar cardenolide composition and concentrations in their wings under both CO2 treatments. We suggest that these increases in sequestration rate are a by‐product of compensatory feeding aimed at maintaining a nutritional target in response to declining dietary quality under eCO2. Monarch wings were more suitable for sustained flight (more elongated) when reared on plants grown under eCO2 or when reared on Asclepias syriaca or Asclepias incarnata rather than on Asclepias curassavica or Asclepias speciosa. Parasite infection engendered wings less suitable for sustained flight (wings became rounder) on three of four milkweed species. Wing loading (associated with powered flight) was higher on A. syriaca than on other milkweeds, whereas wing density was lower on A. curassavica. Monarchs that fed on high cardenolide milkweed developed rounder, thinner wings, which are less efficient at gliding flight. Ingesting foliage from milkweed high in cardenolides may provide protection from enemies through sequestration yet come at a cost to monarchs manifested as lower quality flight phenotypes: rounder, thinner wings with lower wing loading values. Small changes in morphology may have important consequences for enemy evasion and migration success in many animals. Energetic costs associated with alterations in defence and morphology may, therefore, have important consequences for trophic interactions in a changing world. A http://onlinelibrary.wiley.com/doi/10.1111/1365-2435.13270/suppinfo is available for this article.

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“…This raises the possibility of trade-offs in defense strategies against multiple natural enemies, if the costs of sequestering PSMs outweigh the benefits of immune defenses or vice versa. Such trade-offs may become even more important in the presence of ecological perturbations, such as human-induced environmental change, which can lead to changes in host plant quality (Jamieson et al, 2015;Decker et al, 2018), range shifts of host plants or natural enemies (Jeffs and Lewis, 2013), the introduction of novel hosts (Jahner et al, 2011), and subsequently insect defense against natural enemies (Gherlenda et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Host Plant Effects on Immune Response Across Development of a Specialist Caterpillar

2019

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Some herbivorous insects sequester chemicals from their host plants, which can serve as a defense against predators. However, sequestration can also be costly, impacting immunological responses important for other types of natural enemies, such as parasites and pathogens. These costs could also vary across herbivorous insect development, as both immune function and sequestration abilities change, although few studies have assessed variation in the cost of sequestration across life stages. The buckeye, Junonia coenia (Nymphalidae), is a specialist butterfly that sequesters iridoid glycosides from its host plants, including the introduced weed, Plantago lanceolata (Plantaginaceae).To determine the immunological costs of sequestration and how the immune response varies with host plant and across development, we reared caterpillars on a native host plant, Mimulus guttatus (Phrymaceae), which does not contain iridoid glycosides, and on P. lanceolata, which does. We assayed immune function across 3rd, 4th, and 5th instar caterpillars, estimating both hemocyte density and the ability of hemocytes to encapsulate foreign bodies by challenging the immune system with nylon filaments. For caterpillars reared on P. lanceolata, we then explored the relationships between iridoid glycoside sequestration and immune function across instars. We found that while hemocyte density tended to increase with instar regardless of host plant, caterpillars reared on P. lanceolata had lower encapsulation ability, and encapsulation decreased with increasing sequestration of iridoid glycosides, though patterns varied between instars and experimental periods. Interestingly, immune challenged caterpillars sequestered more iridoid glycosides than unchallenged caterpillars, suggesting that caterpillars responded to immune challenge by sequestering or retaining more iridoids, even though that may decrease their ability to encapsulate. These results suggest that sequestration can have important consequences for immune function across caterpillar development, and that the incorporation of novel hosts may affect defense against natural enemies.

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Elevated atmospheric concentrations of carbon dioxide reduce monarch tolerance and increase parasite virulence by altering the medicinal properties of milkweeds

Cited by 28 publications

References 88 publications

Annual environmental variation influences host tolerance to parasites

Annual environmental variation influences host tolerance to parasites

Phytochemical changes in milkweed induced by elevated CO₂ alter wing morphology but not toxin sequestration in monarch butterflies

Host Plant Effects on Immune Response Across Development of a Specialist Caterpillar

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Elevated atmospheric concentrations of carbon dioxide reduce monarch tolerance and increase parasite virulence by altering the medicinal properties of milkweeds

Cited by 28 publications

References 88 publications

Annual environmental variation influences host tolerance to parasites

Annual environmental variation influences host tolerance to parasites

Phytochemical changes in milkweed induced by elevated CO2 alter wing morphology but not toxin sequestration in monarch butterflies

Host Plant Effects on Immune Response Across Development of a Specialist Caterpillar

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Phytochemical changes in milkweed induced by elevated CO₂ alter wing morphology but not toxin sequestration in monarch butterflies