BatFly : A database of N eotropical bat–fly interactions

Global changes have increased the risk of emerging infectious diseases, which can be prevented or mitigated by studying host–parasite interactions, among other measures. Bats and their ectoparasitic flies of the families Streblidae and Nycteribiidae are an excellent study model but, so far, our know...

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Veröffentlicht in:Ecology (Durham) 2024-03, Vol.105 (3)
Hauptverfasser: Zapata‐Mesa, Natalya, Montoya‐Bustamante, Sebastián, Hoyos, Juliana, Peña, Daniela, Galindo‐González, Jorge, Chacón‐Pacheco, Julio J., Ballesteros‐Correa, Jesús, Pastrana‐Montiel, Maria Raquel, Graciolli, Gustavo, Nogueira, Marcelo R., Mello, Marco A. R.
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container_issue 3
container_start_page
container_title Ecology (Durham)
container_volume 105
creator Zapata‐Mesa, Natalya
Montoya‐Bustamante, Sebastián
Hoyos, Juliana
Peña, Daniela
Galindo‐González, Jorge
Chacón‐Pacheco, Julio J.
Ballesteros‐Correa, Jesús
Pastrana‐Montiel, Maria Raquel
Graciolli, Gustavo
Nogueira, Marcelo R.
Mello, Marco A. R.
description Global changes have increased the risk of emerging infectious diseases, which can be prevented or mitigated by studying host–parasite interactions, among other measures. Bats and their ectoparasitic flies of the families Streblidae and Nycteribiidae are an excellent study model but, so far, our knowledge has been restricted to fragmented records at a local scale. To help boost research, we assembled a data set of bat–fly interactions from 174 studies published between 1904 and 2022 plus three original data sets. Altogether, these studies were carried out at 650 sites in the Neotropics, mainly distributed in Mexico, Brazil, Argentina, southern USA, and Colombia, among other countries. In total, our data set contains 3984 interaction records between 237 bat species and 255 fly species. The bat species with the largest number of recorded interactions were Carollia perspicillata (357), Artibeus jamaicensis (263), and Artibeus lituratus (228). The fly species with the largest number of recorded interactions were Trichobius joblingi (256), Megistopoda aranea (235), and Megistopoda proxima (215). The interaction data were extracted, filtered, taxonomically harmonized, and made available in a tidy format together with linked data on bat population, fly population, study reference, sampling methods and geographic information from the study sites. This interconnected structure enables the expansion of information for each interaction record, encompassing where and how each interaction occurred, as well as the number of bats and flies involved. We expect BatFly to open new avenues for research focused on different levels of ecological organization and spatial scales. It will help consolidate knowledge about ecological specialization, resource distribution, pathogen transmission, and the drivers of parasite prevalence over a broad spatial range. It may also help to answer key questions such as: Are there differences in fly prevalence or mean infestation across Neotropical ecoregions? What ecological drivers explain those differences? How do specialization patterns vary among fly species in the Neotropics? Furthermore, we expect BatFly to inspire research aimed at understanding how climate and land‐use changes may impact host–parasite interactions and disease outbreaks. This kind of research may help us reach Sustainable Development Goal 3, Good Health and Wellbeing, outlined by the United Nations. The data are released under a Creative Commons Attribution 4.0 Internat
doi_str_mv 10.1002/ecy.4249
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Altogether, these studies were carried out at 650 sites in the Neotropics, mainly distributed in Mexico, Brazil, Argentina, southern USA, and Colombia, among other countries. In total, our data set contains 3984 interaction records between 237 bat species and 255 fly species. The bat species with the largest number of recorded interactions were Carollia perspicillata (357), Artibeus jamaicensis (263), and Artibeus lituratus (228). The fly species with the largest number of recorded interactions were Trichobius joblingi (256), Megistopoda aranea (235), and Megistopoda proxima (215). The interaction data were extracted, filtered, taxonomically harmonized, and made available in a tidy format together with linked data on bat population, fly population, study reference, sampling methods and geographic information from the study sites. This interconnected structure enables the expansion of information for each interaction record, encompassing where and how each interaction occurred, as well as the number of bats and flies involved. We expect BatFly to open new avenues for research focused on different levels of ecological organization and spatial scales. It will help consolidate knowledge about ecological specialization, resource distribution, pathogen transmission, and the drivers of parasite prevalence over a broad spatial range. It may also help to answer key questions such as: Are there differences in fly prevalence or mean infestation across Neotropical ecoregions? What ecological drivers explain those differences? How do specialization patterns vary among fly species in the Neotropics? Furthermore, we expect BatFly to inspire research aimed at understanding how climate and land‐use changes may impact host–parasite interactions and disease outbreaks. 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title BatFly : A database of N eotropical bat–fly interactions
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