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1. Identifying individual and spatial drivers of heterogeneous transmission and virulence of malaria in Caribbean anoles

   https://doi.org/10.1002/ecs2.4297  

   Toohey, John M.; Otero, Luisa; Flores Siaca, Ian G.; Acevedo, Miguel A. (December 2022, Ecosphere)

   Abstract Heterogeneous distributions are a fundamental principle of ecology, manifesting as natural variability within ecological levels of organization from individuals to ecosystems. In disease ecology, variability in biotic and abiotic factors can result in heterogeneous patterns of transmission and virulence—broadly defined here as the negative consequences of infection. Still, our classic theoretical understanding of disease dynamics comes from models that assume homogeneous transmission and virulence. Here, we test this assumption by assessing the contribution of various sources of individual and spatial heterogeneity to patterns of transmission and sublethal measurements of virulence in two lizard–malaria systems: a three‐parasite assemblage (Plasmodium floridense,Plasmodium leukocytica, andPlasmodium azurophilum) infecting the lizardAnolis gundlachiin the rainforest of Puerto Rico and a single‐parasite system (P. floridense–Anolis sagrei) in Florida. Using a Bayesian model selection framework, we evaluated whether individual host differences (i.e., body size and sex) or spatial variability (i.e., habitat type and local‐scale host spatial structure) drive heterogeneity in the probability of infection or its associated health costs (i.e., body condition, blood chemistry). We found that the probability of infection increases with increasing lizard body size in both systems. However, in Florida, we found the relationship to be subdued in deforested habitats compared to the adjacent urban hydric forests. Furthermore, infection was spatially clustered within sampling sites, with “hot” and “cold” spots across the landscape. Nevertheless, we found no clear evidence of costs of infection on lizard health in any of the measures assessed and hence no grounds for inference regarding heterogeneous virulence. Ultimately, the consistency of our results across systems suggests prominent roles of individual and spatial heterogeneities as driving factors of transmission of vector‐borne diseases. 

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2. Another tool in the toolbox: Aphid‐specific Wolbachia protect against fungal pathogens

   https://doi.org/10.1111/1462-2920.70005  

   Higashi, Clesson_H_V; Patel, Vilas; Kamalaker, Bryan; Inaganti, Rahul; Bressan, Alberto; Russell, Jacob_A; Oliver, Kerry_M (November 2024, Environmental Microbiology)

   Abstract Aphids harbor nine common facultative symbionts, most mediating one or more ecological interactions.Wolbachia pipientis, well‐studied in other arthropods, remains poorly characterized in aphids. InPentalonia nigronervosaandP. caladii, global pests of banana,Wolbachiawas initially hypothesized to function as a co‐obligate nutritional symbiont alongside the traditional obligateBuchnera. However, genomic analyses failed to support this role. Our sampling across numerous populations revealed that more than 80% ofPentaloniaaphids carried an M‐supergroup strain ofWolbachia(wPni). The lack of fixation further supports a facultative status forWolbachia, while high infection frequencies in these entirely asexual aphids strongly suggestWolbachiaconfers net fitness benefits. Finding no correlation betweenWolbachiapresence and food plant use, we challengedWolbachia‐infected aphids with common natural enemies. Bioassays revealed thatWolbachiaconferred significant protection against a specialized fungal pathogen (Pandora neoaphidis) but not against generalist pathogens or parasitoids.Wolbachiaalso improved aphid fitness in the absence of enemy challenge. Thus, we identified the first clear benefits for aphid‐associatedWolbachiaand M‐supergroup strains specifically. Aphid‐Wolbachiasystems provide unique opportunities to merge key models of symbiosis to better understand infection dynamics and mechanisms underpinning symbiont‐mediated phenotypes. 

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3. Host blood meal identity modifies vector gene expression and competency

   https://doi.org/10.1111/mec.16413  

   Ring, Kacie; Couper, Lisa I.; Sapiro, Anne L.; Yarza, Fauna; Yang, X. Frank; Clay, Keith; Mateusiak, Chase; Chou, Seemay; Swei, Andrea (January 2022, Molecular Ecology)

   A vector's susceptibility and ability to transmit a pathogen—termed vector competency—determines disease outcomes, yet the ecological factors influencing tick vector competency remain largely unknown. Ixodes pacificus, the tick vector of Borrelia burgdorferi (Bb) in the western U.S., feeds on rodents, birds, and lizards. Rodents and birds are reservoirs for Bb and infect juvenile ticks, while lizards are refractory to Bb and cannot infect feeding ticks. Additionally, the lizard bloodmeal contains borreliacidal properties, clearing previously infected feeding ticks of their Bb infection. Despite I. pacificus feeding on a range of hosts, it is undetermined how the host identity of the larval bloodmeal affects future nymphal vector competency. We experimentally evaluate the influence of larval host bloodmeal on Bb acquisition by nymphal I. pacificus. Larval I. pacificus were fed on either lizards or mice and after molting, nymphs were fed on Bb-infected mice. We found that lizard-fed larvae were significantly more likely to become infected with Bb during their next bloodmeal than mouse-fed larvae. We also conducted the first RNA-seq analysis on whole-bodied I. pacificus and found significant upregulation of tick antioxidants and antimicrobial peptides in the lizard-fed group. Our results indicate that the lizard bloodmeal significantly alters vector competency and gene regulation in ticks, highlighting the importance of host bloodmeal identity in vector-borne disease transmission and upends prior notions about the role of lizards in Lyme disease community ecology. 

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4. Use of an exotic host plant shifts immunity, chemical defense, and viral burden in wild populations of a specialist insect herbivore

   https://doi.org/10.1002/ece3.8723  

   Muchoney, Nadya D.; Bowers, M. Deane; Carper, Adrian L.; Mason, Peri A.; Teglas, Mike B.; Smilanich, Angela M. (March 2022, Ecology and Evolution)

   Abstract Defense against natural enemies constitutes an important driver of herbivore host range evolution in the wild. Populations of the Baltimore checkerspot butterfly,Euphydryas phaeton(Nymphalidae), have recently incorporated an exotic plant,Plantago lanceolata(Plantaginaceae), into their dietary range. To understand the tritrophic consequences of utilizing this exotic host plant, we examined immune performance, chemical defense, and interactions with a natural entomopathogen (Junonia coenia densovirus,Parvoviridae) across wild populations of this specialist herbivore. We measured three immune parameters, sequestration of defensive iridoid glycosides (IGs), and viral infection load in field‐collected caterpillars using eitherP.lanceolataor a native plant,Chelone glabra(Plantaginaceae). We found that larvae using the exotic plant exhibited reduced immunocompetence, compositional differences in IG sequestration, and higher in situ viral burdens compared to those using the native plant. On both host plants, high IG sequestration was associated with reduced hemocyte concentration in the larval hemolymph, providing the first evidence of incompatibility between sequestered chemical defenses and the immune response (i.e., the “vulnerable host” hypothesis) from a field‐based study. However, despite this negative relationship between IG sequestration and cellular immunity, caterpillars with greater sequestration harbored lower viral loads. While survival of virus‐infected individuals decreased with increasing viral burden, it ultimately did not differ between the exotic and native plants. These results provide evidence that: (1) phytochemical sequestration may contribute to defense against pathogens even when immunity is compromised and (2) herbivore persistence on exotic plant species may be facilitated by sequestration and its role in defense against natural enemies. 

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5. Inter- and intrapopulation resource use variation of marine subsidized western fence lizards

   https://doi.org/10.1007/s00442-023-05496-6  

   Ebersole, Alexi; Bunker, Marie E.; Weiss, Stacey L.; Fox-Dobbs, Kena (January 2024, Oecologia)

   Abstract Marine resource subsidies alter consumer dynamics of recipient populations in coastal systems. The response to these subsidies by generalist consumers is often not uniform, creating inter- and intrapopulation diet variation and niche diversification that may be intensified across heterogeneous landscapes. We sampled western fence lizards,Sceloporus occidentalis, from Puget Sound beaches and coastal and inland forest habitats, in addition to the lizards’ marine and terrestrial prey items to quantify marine and terrestrial resource use with stable isotope analysis and mixing models. Beach lizards had higher average δ¹³C and δ¹⁵N values compared to coastal and inland forest lizards, exhibiting a strong mixing line between marine and terrestrial prey items. Across five beach sites, lizard populations received 20–51% of their diet from marine resources, on average, with individual lizards ranging between 7 and 86% marine diet. The hillslope of the transition zone between marine and terrestrial environments at beach sites was positively associated with marine-based diets, as the steepest sloped beach sites had the highest percent marine diets. Within-beach variation in transition zone slope was positively correlated with the isotopic niche space of beach lizard populations. These results demonstrate that physiography of transitional landscapes can mediate resource flow between environments, and variable habitat topography promotes niche diversification within lizard populations. Marine resource subsidization of Puget Sound beachS. occidentalispopulations may facilitate occupation of the northwesternmost edge of the species range. Shoreline restoration and driftwood beach habitat conservation are important to support the unique ecology of Puget SoundS. occidentalis. 

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