Description of the Egg ofOchlerotatus japonicus japonicus(Diptera: Culicidae) Using Variable Pressure Scanning Electron Microscopy

Haddow, Andrew D.; Moulton, John K.; Gerhardt, Reid R.; Mccuiston, Linda J.; Jones, Carl J.

doi:10.1603/033.046.0102

Cited by 11 publications

(13 citation statements)

References 18 publications

(17 reference statements)

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“…j. japonicus and Ae. triseriatus eggs (Haddow et al 2009). We found the distinctions between the two species’ eggs to be somewhat subjective and much less obvious than readily observed larval characters, and hence used the following hatching procedures to estimate viable eggs laid and ensure accurate identification of the targeted species.…”

Section: Methodsmentioning

confidence: 99%

Establishment of Aedes japonicus japonicus and Its Colonization of Container Habitats in Michigan

Kaufman

Stanuszek²,

Brouhard

et al. 2012

jnl. med. entom.

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Oviposition dynamics and colonization of container habitats by the invasive species, Aedes (Finlaya) japonicus japonicus (Theobald) were examined through the use of ovistrips placed in buckets, and larval surveys of tree holes and tires at sites in central Michigan. In general, oviposition and colonization increased during the study periods, with several sites showing large increases from <10% Ae. j. japonicus initially to over 60% in the following years. Seasonally, higher proportions of Ae. j. japonicus were found in spring and fall collection periods. Ae. j. japonicus larvae co-occurred in the artificial containers with Ae. triseriatus, Ae. hendersoni, several Culex spp., and Anopheles spp. Recent surveys of tire and tree hole habitats at our study areas in mid-Michigan revealed that Ae. j. japonicus had colonized most of these habitats, but maintained relatively low populations in tree holes occupied by Ae. triseriatus. Trends seen in tires from 2008 to 2011, and from gravid trap and New Jersey light traps in 2005–2011, suggest that Ae. j. japonicus populations are stabilizing as they integrate into native Michigan mosquito communities.

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Section: Methodsmentioning

confidence: 99%

Establishment of Aedes japonicus japonicus and Its Colonization of Container Habitats in Michigan

Kaufman

Stanuszek²,

Brouhard

et al. 2012

jnl. med. entom.

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“…j. japonicus is a cold-tolerant species that overwinters primarily in the egg stage (for egg surface characteristics, see 34), but sometimes in the larval stage (4, 5, 41, 50, 93). Bartlett-Healy et al (10) observed that Ae.…”

Section: Phenology and Temperature Tolerancesmentioning

confidence: 99%

Invasion Biology ofAedes japonicus japonicus(Diptera: Culicidae)

Kaufman

Fonseca

2014

Annu. Rev. Entomol.

200

227

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Aedes japonicus japonicus (Theobald) (Diptera: Culicidae) has recently expanded beyond its native range of Japan and Korea into large parts of North America and Central Europe. Population genetic studies begun immediately after the species was detected in North America revealed genetically distinct introductions that subsequently merged, likely contributing to the successful expansion. Interactions, particularly in the larval stage, with other known disease vectors give this invasive subspecies the potential to influence local disease dynamics. Its successful invasion likely does not involve superior direct competitive abilities, but it is associated with the use of diverse larval habitats and a cold tolerance that allows an expanded seasonal activity range in temperate climates. We predict a continued but slower expansion of Ae. j. japonicus in North America and a continued rapid expansion into other areas as this mosquito will eventually be considered a permanent resident of much of North America, Europe, Asia, and parts of Hawaii.

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“…Aedes japonicus is also a daytime biter of a variety of hosts including humans (Andreadis et al, 2001; Goudarz et al, 2009). LACV has been isolated from A. albopictus eggs and adults (Gerhardt et al, 2001; Haddow et al, 2009; Lambert et al, 2010; Westby et al, 2011) and A. japonicus adults (Westby et al, 2011) in the field. For both species, LACV positive adults have been found at case sites of LACV encephalitis in eastern Tennessee (Haddow et al, 2009, Westby et al, 2011), implicating these species as vectors of human cases in the Appalachian region.…”

Section: Biology Of Lacv Vectorsmentioning

confidence: 99%

“…LACV has been isolated from A. albopictus eggs and adults (Gerhardt et al, 2001; Haddow et al, 2009; Lambert et al, 2010; Westby et al, 2011) and A. japonicus adults (Westby et al, 2011) in the field. For both species, LACV positive adults have been found at case sites of LACV encephalitis in eastern Tennessee (Haddow et al, 2009, Westby et al, 2011), implicating these species as vectors of human cases in the Appalachian region. Laboratory infection and oral transmission rates for A. albopictus may be equal to or greater than those for A. triseriatus (Grimstad et al, 1989; Cully et al, 1992), although disseminated infection (Hughes et al, 2006) and transoviral transmission (Tesh and Gubler, 1975) rates are lower.…”

Section: Biology Of Lacv Vectorsmentioning

confidence: 99%

“…Aedes albopictus and A. japonicus are competent laboratory vectors of LACV (Grimstad et al, 1989; Cully et al, 1992; Sardelis et al, 2002). LACV has been isolated from field populations of both A. albopictus (Gerhardt et al, 2001; Haddow et al, 2009; Lambert et al, 2010; Westby et al, 2011) and A. japonicus (Westby et al, 2011). Thus, both invaders may affect the incidence of LACV in the Appalachian region by acting as important accessory vectors and by affecting the distribution and abundance of A. triseriatus by competing with the native species for resources in water-holding containers.…”

Section: Introductionmentioning

confidence: 99%

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Impacts of Climate, Land Use, and Biological Invasion on the Ecology of Immature Aedes Mosquitoes: Implications for La Crosse Emergence

Leisnham

Juliano

2012

EcoHealth

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Arthropod-borne viruses (arboviruses) cause many diseases worldwide and their transmission is likely to change with land use and climate changes. La Crosse virus is historically transmitted by the native mosquito Aedes triseriatus (Say) in the upper Midwestern U.S., but the invasive congeners Aedes albopictus (Skuse) and Aedes japonicus (Theobald), which co-occur with A. triseriatus in water-holding containers, may be important accessory vectors in the Appalachian region where La Crosse encephalitis is an emerging disease. This review focuses on evidence for how climate, land use, and biological invasions may have direct abiotic and indirect community-level impacts on immature developmental stages (eggs and larvae) of Aedes mosquitoes. Because vector-borne diseases usually vary in space and time and are related to the ecology of the vector species, we propose that the ecology of its mosquito vectors, particularly at their immature stages, has played an important role in the emergence of La Crosse encephalitis in the Appalachian region and represents a model for investigating the effects of environmental changes on other vector-borne diseases. We summarize the health effects of La Crosse virus and associated socioeconomic costs that make it the most important native mosquito-borne disease in the U.S. We review of the transmission of La Crosse virus, and present evidence for the impacts of climate, land use, and biological invasions on Aedes mosquito communities. Last, we discuss important questions about the ecology of La Crosse virus mosquito vectors that may improve our understanding of the impacts of environmental changes on La Crosse virus and other arboviruses.

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Description of the Egg ofOchlerotatus japonicus japonicus(Diptera: Culicidae) Using Variable Pressure Scanning Electron Microscopy

Cited by 11 publications

References 18 publications

Establishment of <I>Aedes japonicus japonicus</I> and Its Colonization of Container Habitats in Michigan

Establishment of <I>Aedes japonicus japonicus</I> and Its Colonization of Container Habitats in Michigan

Invasion Biology ofAedes japonicus japonicus(Diptera: Culicidae)

Impacts of Climate, Land Use, and Biological Invasion on the Ecology of Immature Aedes Mosquitoes: Implications for La Crosse Emergence

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