Phylogenetic and biogeographical traits predict unrecognized hosts of zoonotic leishmaniasis

The spatio-temporal distribution of leishmaniasis, a parasitic vector-borne zoonotic disease, is significantly impacted by land-use change and climate warming in the Americas. However, predicting and containing outbreaks is challenging as the zoonotic Leishmania system is highly complex: leishmanias...

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Veröffentlicht in:	PLoS neglected tropical diseases 2023-05, Vol.17 (5), p.e0010879
Hauptverfasser:	Glidden, Caroline K, Murran, Aisling Roya, Silva, Rafaella Albuquerque, Castellanos, Adrian A, Han, Barbara A, Mordecai, Erin A
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural land Animals Animals, Wild Bacterial infections Biogeography Biology and Life Sciences Cladistics Climate Climate change Computer and Information Sciences Diagnosis Disease susceptibility Distribution Earth Sciences Ecology and Environmental Sciences Environmental changes Environmental impact Evaluation Global warming Health risks Host range Hosts Humans Infections Infectious diseases Land cover Land use Leishmania Leishmania - genetics Leishmaniasis Leishmaniasis - epidemiology Leishmaniasis - veterinary Machine learning Mammals Medicine and Health Sciences Parasites Parasitic diseases Pathogens Phlebotomus - parasitology Phylogenetics Phylogeny Physiology Protozoa Psychodidae - parasitology Spatial distribution Surveillance Taxonomy Temporal distribution Transmission Tropical diseases Urban agriculture Vector-borne diseases Wildlife Zoonoses
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description	The spatio-temporal distribution of leishmaniasis, a parasitic vector-borne zoonotic disease, is significantly impacted by land-use change and climate warming in the Americas. However, predicting and containing outbreaks is challenging as the zoonotic Leishmania system is highly complex: leishmaniasis (visceral, cutaneous and muco-cutaneous) in humans is caused by up to 14 different Leishmania species, and the parasite is transmitted by dozens of sandfly species and is known to infect almost twice as many wildlife species. Despite the already broad known host range, new hosts are discovered almost annually and Leishmania transmission to humans occurs in absence of a known host. As such, the full range of Leishmania hosts is undetermined, inhibiting the use of ecological interventions to limit pathogen spread and the ability to accurately predict the impact of global change on disease risk. Here, we employed a machine learning approach to generate trait profiles of known zoonotic Leishmania wildlife hosts (mammals that are naturally exposed and susceptible to infection) and used trait-profiles of known hosts to identify potentially unrecognized hosts. We found that biogeography, phylogenetic distance, and study effort best predicted Leishmania host status. Traits associated with global change, such as agricultural land-cover, urban land-cover, and climate, were among the top predictors of host status. Most notably, our analysis suggested that zoonotic Leishmania hosts are significantly undersampled, as our model predicted just as many unrecognized hosts as unknown hosts. Overall, our analysis facilitates targeted surveillance strategies and improved understanding of the impact of environmental change on local transmission cycles.
doi_str_mv	10.1371/journal.pntd.0010879
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subjects	Agricultural land Animals Animals, Wild Bacterial infections Biogeography Biology and Life Sciences Cladistics Climate Climate change Computer and Information Sciences Diagnosis Disease susceptibility Distribution Earth Sciences Ecology and Environmental Sciences Environmental changes Environmental impact Evaluation Global warming Health risks Host range Hosts Humans Infections Infectious diseases Land cover Land use Leishmania Leishmania - genetics Leishmaniasis Leishmaniasis - epidemiology Leishmaniasis - veterinary Machine learning Mammals Medicine and Health Sciences Parasites Parasitic diseases Pathogens Phlebotomus - parasitology Phylogenetics Phylogeny Physiology Protozoa Psychodidae - parasitology Spatial distribution Surveillance Taxonomy Temporal distribution Transmission Tropical diseases Urban agriculture Vector-borne diseases Wildlife Zoonoses
title	Phylogenetic and biogeographical traits predict unrecognized hosts of zoonotic leishmaniasis
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