Curtis P. Ewing scite author profile

Ticks were sampled by flagging, collecting from the investigator's clothing (walking samples), trapping with dry-ice bait, and collecting from mammal hosts on Fire Island, NY, U.S.A. The habitat distribution of adult deer ticks, Ixodes dammini, was the same in simultaneous collections from the investigator's clothing and from muslin flags. Walking and flagging samples can both be biased by differences between investigators, so the same person should do comparative samples whenever possible. Walking samples probably give a more accurate estimate than flagging samples of the human risk of encountering ticks. However, ticks (such as immature I. dammini) that seek hosts in leaf litter and ground-level vegetation are poorly sampled by walking collections. These ticks can be sampled by flagging at ground level. Dry-ice-baited tick-traps caught far more lone-star ticks, Amblyomma americanum, than deer ticks, even in areas where deer ticks predominated in flagging samples. In comparisons of tick mobility in the lab, nymphal A. americanum were more mobile than nymphal I. dammini in 84% of the trials. Therefore, the trapping bias may result from increased trap encounter due to more rapid movement by A. americanum, although greater attraction to carbon dioxide may also play a role. Tick traps are useful for intraspecific between-habitat comparisons. Early in their seasonal activity period, larval I. dammini were better represented in collections from mouse hosts than in flagging samples. Apparently, sampling from favored hosts can detect ticks at low population levels, but often cannot be used to get accurate estimates of pathogen prevalence in questing ticks.

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Community assembly on isolated islands: macroecology meets evolution

Rominger

Goodman

Lim

et al. 2015

Global Ecology and Biogeography

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Aim Understanding how ecological and evolutionary processes together determine patterns of biodiversity remains a central aim in biology. Guided by ecological theory, we use data from multiple arthropod lineages across the Hawaiian archipelago to explore the interplay between ecological (population dynamics, dispersal, trophic interactions) and evolutionary (genetic structuring, adaptation, speciation, extinction) processes. Our goal is to show how communities develop from the dynamic feedbacks that operate at different temporal and spatial scales. Location The Hawaiian islands (19-22°N, 155-160°W).Methods We synthesize genetic data from selected arthropods across the Hawaiian archipelago to determine the relative role of dispersal and in situ differentiation across the island chronosequence. From four sites on three high islands with geological ages ranging from < 1 Ma to 5 Ma, we also generate ecological metrics on plant-herbivore bipartite networks drawn from the literature. We compare the structure of these networks with predictions derived from the principle of maximum information entropy.Results From the perspective of the island chronosequence we show that species at lower trophic levels develop population genetic structure at smaller temporal and spatial scales than species at higher trophic levels. Network nestedness decreases while modularity increases with habitat age. Single-island endemics exhibit more specialization than broadly distributed species, but both show the least specialization in communities on middle-aged substrates. Plant-herbivore networks also show the least deviation from theoretical predictions in middle-aged communities. Main conclusionsThe application of ecological theory to island chronosequences can illuminate feedbacks between ecological and evolutionary processes in community assembly. We show how patterns of population genetic structure, decreasing network nestedness, increasing network modularity and increased specialization shift from early assembly driven by immigration, to in situ diversification after > 1 Myr. Herbivore-plant communities only transiently achieve statistical steady state during assembly, presumably due to incomplete assembly from dispersal in the early stages, and the increasing influence of island ontogeny on older islands.

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Habitat Distribution of Ixodes dammini (Acari: Ixodidae) and Lyme Disease Spirochetes on Fire Island, New York

Ginsberg¹,

Ewing²

1989

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The distributions of Ixodes dammini Spielman, Clifford, Piesman, and Corwin and Lyme disease spirochetes were studied on Fire Island, N.Y. Adult ticks were more common in high-shrub habitats (shrubby vegetation greater than or equal to 1 m high) than in grassy and lowshrub habitats (vegetation less than 1 m) in spring and fall. In the fall, adults were also common in the woods. Adults were more abundant on narrow trails than in nearby vegetation. During the summer, questing nymphs and larvae were far more common in the woods (primarily in leaf litter) than in open grass-shrub habitats. In contrast, the number of nymphs and larvae per white-footed mouse did not differ among habitats, suggesting that mice play a role in tick dispersal. CO2 trap captures of nymphs on trails were not significantly greater than off trails. Most collections of larvae and nymphs had more than one tick, whereas most samples of adults had only one individual. Borrelia burgdorferi infection rates in free-living ticks were 38% (n = 12) to 50% (n = 32) in adults, 32% in nymphs (n = 184), and 0% in larvae (n = 15). The proportion of ticks infected did not differ significantly among habitats. Therefore, during the spring and fall, activities that take place in high-shrub areas or in the woods (e.g., landscaping, trail or brush clearing) involve a high risk of exposure to adult ticks infected with Lyme disease. In late spring to early summer, any activity involving close contact with leaf litter (e.g., playing in the leaves, gathering leaves for camp bedding) results in a high risk of exposure to infected nymphs.

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Metschnikowia hamakuensis sp. nov., Metschnikowia kamakouana sp. nov. and Metschnikowia mauinuiana sp. nov., three endemic yeasts from Hawaiian nitidulid beetles

Lachance

Ewing

Bowles

et al. 2005

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Three heterothallic, haplontic yeast species,Metschnikowia hamakuensis,Metschnikowia kamakouanaandMetschnikowia mauinuiana, are described from isolates associated with endemic nitidulid beetles living on various endemic plants on three Hawaiian islands. As morphospecies, they are similar toMetschnikowia hawaiiensis, but based on mating compatibility and ascospore formation, they can be assigned clearly to distinct biological species. Analysis of ITS/5·8S and D1/D2 large subunit rDNA sequences shows that, withM. hawaiiensisand two other isolates, these species form a distinct subclade within the large-sporedMetschnikowiaspecies, indicating that they are Hawaiian endemics. Type cultures are:M. hamakuensis, UWOPS 04-207.1T=CBS 10056T=NRRL Y-27834T(type, h+) and UWOPS 04-204.1=CBS 10055=NRRL Y-27833 (allotype, h−);M. kamakouana, UWOPS 04-112.5T=CBS 10058T=NRRL Y-27836T(type, h+) and UWOPS 04-109.1=CBS 10057=NRRL Y-27835 (allotype, h−); andM. mauinuiana, UWOPS 04-190.1T=CBS 10060T=NRRL Y-27838T(type, h+) and UWOPS 04-110.4=CBS 10059=NRRL Y-27837 (allotype, h−).

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Increased Population Densities of Amblyomma americanum (Acari: Ixodidae) on Long Island, New York

Ginsberg

Ewing²,

O’Connell³

et al. 1991

The Journal of Parasitology

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Lone star ticks, Amblyomma americanum comprised a significantly greater proportion of total ticks flagged on eastern Long Island and Fire Island, New York, in 1986 and 1990 than in samples reported by other authors from the 1940s (when A. americanum was not collected by flagging or from hosts) and the 1970s. Therefore, population densities of A. americanum apparently have increased in recent years on southeastern Long Island, where this species now is distributed widely.

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Curtis P. Ewing

Comparison of flagging, walking, trapping, and collecting from hosts as sampling methods for northern deer ticks,Ixodes dammini, and lone-star ticks,Amblyomma americanum (Acari: Ixodidae)

Community assembly on isolated islands: macroecology meets evolution

Habitat Distribution of Ixodes dammini (Acari: Ixodidae) and Lyme Disease Spirochetes on Fire Island, New York

Metschnikowia hamakuensis sp. nov., Metschnikowia kamakouana sp. nov. and Metschnikowia mauinuiana sp. nov., three endemic yeasts from Hawaiian nitidulid beetles

Increased Population Densities of Amblyomma americanum (Acari: Ixodidae) on Long Island, New York

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