Mosquitoes are the most important vectors of emerging infectious diseases. During the past decade, our understanding of the diversity of viruses they carry has greatly expanded. Most of these viruses are considered mosquito-specific but there is increasing evidence that these viruses may affect the vector competence of mosquitoes. Metagenomics approaches have focused on specific mosquito species for the identification of what is called the core virome. Despite the fact that, in most ecosystems, multiple species may participate in virus emergence and circulation, there is a lack of understanding of the virus-carrier/host network for both vector-borne and mosquito-specific viruses. Here, we studied the core virome of mosquitoes in a diverse local ecosystem that had 24 different mosquito species. Analysis of the viromes of these 24 mosquito species resulted in the identification of 34 viruses, which included 15 novel viruses, as determined according to the species demarcation criteria of the respective virus families. Most of the mosquito species had never been analysed previously and a comparison of the individual viromes of the 24 mosquito species revealed novel relationships among mosquito species and virus families. Groups of related viruses and mosquito species from multiple genera formed a complex web in the local ecosystem. Furthermore, analyses of the virome of mixed-species pools of mosquitoes from representative traps of the local ecosystem showed almost complete overlap with the individual-species viromes identified in the study. Quantitative analysis of viruses’ relative abundance revealed a linear relationship to the abundance of the respective carrier/host mosquito species, supporting the theory of a stable core virome in the most abundant species of the local ecosystem. Finally, our study highlights the importance of using a holistic approach to investigating mosquito viromes relationships in rich and diverse ecosystems.
Dengue epidemics in Brazil have become more frequent and more severe and involving larger populations in the last years. In Brazil Aedes aegypti is the only known vector. During the 2007-2008 period, Rio de Janeiro state experienced the most severe dengue epidemics ever reported in terms of morbidity and mortality. During this period, 322,371 cases and 240 deaths were registered, with 100 deaths due to dengue haemorragic fever/ dengue shock syndrome and 140 due to other dengue-related complications. Dengue transmission is influenced by closely related factors, many of which directly associated to the environment. Every city has its own specificities that are mainly given by its landscape and human populations. Rio de Janeiro is a city of 6 million individuals who share a heterogeneous space of ~1,200km 2 . Human population density ranges from 5,000 inhabitants/km 2 average mainly in the lowlands, with slums (or favelas) mainly in the slopes, where densities reach ~40,000 inhabitants/km 2 . These 6 million individuals live in highly urbanized, medium-urbanized and peri-urban transition zones with pockets of rural and semi-rural areas surrounded by the expanding city, mostly in the lowlands interspersed by three mountain complexes. To analyze the heterogeneous space of the city of Rio de Janeiro in relation to dengue, neighborhoods land cover maps where juxtaposed to dengue georeferenced cases, during the epidemic period 2007-2008. This analysis resulted in the observation of spatial clusters of high incidence dengue cases (hotspots) in 7 areas, namely, Jacarepaguá, Downtown, Island, Guaratiba, Northern, Western and Pedra. The most important cluster was constituted by the Jacarepaguá lowland urban ecosystem. Do the different urban ecosystems differ epidemiologically in terms of when and how dengue is transmitted? In Rio de Janeiro, is there a dengue of highly urbanized areas, a dengue of medium urbanized areas and a dengue of medium-high vegetated areas? Or in all those different urban ecosystems there is a shared characteristic that favor dengue transmission? Even though further studies should be conducted taking other aspects into account, the present study indicates that the different urban ecosystems observed might influence dengue transmission in Rio de Janeiro. Keywords: Dengue; Rio de Janeiro; urban ecosystem. RESUMODENGUE E A HETEROGENEIDADE DA COBERTURA DA TERRA NO RIO DE JANEIRO. As epidemias de dengue no Brasil têm sido cada vez mais frequentes, de maior incidência e gravidade. No
BackgroundMosquitoes are the most important vectors of emerging infectious diseases. During the past decade, our understanding of the diversity of viruses they carry has greatly expanded. Most of these viruses are considered mosquito-specific, while there is increasing evidence that these viruses may affect mosquito vector potential. Metagenomics approaches have focused on specific mosquito species for the identification of what is called core virome. However, in most ecosystems, multiple species may participate in virus emergence and circulation, while there is lack of understanding on the viruses-carrier/host network for both vector-borne and mosquito-specific viruses. Results Here, we studied the core mosquito virome in a diverse ecosystem comprised of 24 different mosquito species. Analysis of these 24 diverse viromes resulted in the discovery of 35 viruses with known genetic traits and 9 novel viruses. Comparison of the viromes of the 24 individual species revealed novel relationships between mosquito species and virus families, as most of the mosquito species had never been analysed in the past. Groups of related viruses and mosquito species from multiple genera formed a complex network in the ecosystem. Analyses of whole traps of mosquitoes of variable composition not only showed a stable core virome for each species but also a relationship between mosquito population and virome composition.ConclusionsOur study highlighted the importance of a holistic approach regarding mosquito viromes in rich and diverse ecosystems. Our data further supported the idea of a stable core virome, characteristic of each mosquito species. The remarkable stability of the core virome seemed to determine the composition of the total mosquito core virome of a habitat in the ecosystem.
BACKGROUND Prokaryotic and eukaryotic organisms share the same basic biochemical pathways for protein production, denoting their common evolution. The use of prokaryotic cells as bioreactors coincides with the advent of agriculture in human history and dates back to 10,000 years ago with fermentation for the production of wines, cheeses and breads.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.