Genome Investigations of Vector Competence in Aedes aegypti to Inform Novel Arbovirus Disease Control Approaches

Severson, David W.; Behura, Susanta K.

doi:10.3390/insects7040058

Cited by 38 publications

(36 citation statements)

References 130 publications

(145 reference statements)

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“…These observations have implications for the further spread of ZIKV into distinct populations of mosquitoes across the globe. There are multiple mechanisms by which the difference in vector capacity among strains could arise, such as genetic variation in metabolic and/or immune pathways, or entry or replication factors necessary for ZIKV infection [ 35 ]. While it is impossible to make any definitive statements on genes that drive differences in vector competency based solely on the location of the microsatellite markers used to analyze genetic variability, we are able to indicate genes that are proximal to the markers driving variability among the groups, particularly AC1 and CT2 ( Table 2 ).…”

Section: Discussionmentioning

confidence: 99%

Altered vector competence in an experimental mosquito-mouse transmission model of Zika infection

et al. 2018

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Few animal models of Zika virus (ZIKV) infection have incorporated arthropod-borne transmission. Here, we establish an Aedes aegypti mosquito model of ZIKV infection of mice, and demonstrate altered vector competency among three strains, (Orlando, ORL, Ho Chi Minh, HCM, and Patilas, PAT). All strains acquired ZIKV in their midguts after a blood meal from infected mice, but ZIKV transmission only occurred in mice fed upon by HCM, and to a lesser extent PAT, but not ORL, mosquitoes. This defect in transmission from ORL or PAT mosquitoes was overcome by intrathoracic injection of ZIKV into mosquito. Genetic analysis revealed significant diversity among these strains, suggesting a genetic basis for differences in ability for mosquito strains to transmit ZIKV. The intrathoracic injection mosquito-mouse transmission model is critical to understanding the influence of mosquitoes on ZIKV transmission, infectivity and pathogenesis in the vertebrate host, and represents a natural transmission route for testing vaccines and therapeutics.

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Section: Discussionmentioning

confidence: 99%

Altered vector competence in an experimental mosquito-mouse transmission model of Zika infection

et al. 2018

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“…In Aedes aegpti, targeting male-determining factors using germline Cas9 expression could give similar results 91,96 , though research is at an earlier stage compared with Anopheline systems. Development of constructs which reduce vector competence is another area of active research 89 , with a variety of potential targets having been identified for both malaria 97,98 and arboviruses 99 .…”

Section: Novel Vector Control Technologiesmentioning

confidence: 99%

Challenges and opportunities in controlling mosquito-borne infections

Ferguson

2018

Nature

118

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Mosquito-borne diseases remain a major cause of morbidity and mortality across the tropical regions. Despite much progress in the control of malaria, malaria-associated morbidity remains high, whereas arboviruses-most notably dengue-are responsible for a rising burden of disease, even in middle-income countries that have almost completely eliminated malaria. Here I discuss how new interventions offer the promise of considerable future reductions in disease burden. However, I emphasize that intervention programmes need to be underpinned by rigorous trials and quantitative epidemiological analyses. Such analyses suggest that the long-term goal of elimination is more feasible for dengue than for malaria, even if malaria elimination would offer greater overall health benefit to the public.

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“…Their feeding behavior not only annoys us, but creates a potent pathway for disease transmission. For example, Aedes aegypti are vectors of viral diseases such as yellow fever, dengue, chikungunya and Zika [1, 2]. Certain mosquito species like Ae.…”

Section: Introductionmentioning

confidence: 99%

Genetic analysis of mosquito detection of humans

Raji

DeGennaro

2017

Current Opinion in Insect Science

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Mosquitoes detect the presence of humans by integrating chemosensory, thermal, and visual cues. Among these, odors are crucial for mosquito host detection. Insects have evolved a diverse repertoire of receptors to detect their plant and animal hosts. Genetic analysis of these receptors in Drosophila has set the stage for similar studies in mosquitoes. The diversity of the cues involved in mosquito host-seeking has made designing behavioral control strategies a challenge. The sensory receptors that are most important for mosquito detection of humans can now be determined using genome editing. Here, we will review our current understanding of the salient cues that attract mosquitoes, their receptors, and suggest ways forward for novel olfaction-based vector control strategies.

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Genome Investigations of Vector Competence in Aedes aegypti to Inform Novel Arbovirus Disease Control Approaches

Cited by 38 publications

References 130 publications

Altered vector competence in an experimental mosquito-mouse transmission model of Zika infection

Altered vector competence in an experimental mosquito-mouse transmission model of Zika infection

Challenges and opportunities in controlling mosquito-borne infections

Genetic analysis of mosquito detection of humans

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