Literature detail

Divide-and-conquer: machine-learning integrates mammalian and viral traits with network features to predict virus-mammal associations.

Maya Wardeh^1,2 Marcus S C Blagrove³ Kieran J Sharkey⁴ Matthew Baylis^5,6

Affiliations 6 institutions

Department of Livestock and One Health, Institute of Infection, Veterinary & Ecological Sciences, University of Liverpool, Liverpool, UK. [email protected].
Department of Mathematical Sciences, University of Liverpool, Liverpool, UK. [email protected].
Department of Evolution, Ecology and Behaviour, Institute of Infection, Veterinary & Ecological Sciences, University of Liverpool, Liverpool, UK.
Department of Mathematical Sciences, University of Liverpool, Liverpool, UK.
Department of Livestock and One Health, Institute of Infection, Veterinary & Ecological Sciences, University of Liverpool, Liverpool, UK.
Health Protection Research Unit in Emerging and Zoonotic Infections, University of Liverpool, Liverpool, UK.

PMID 34172731 2021 Nat Commun eng epublish

Article

Publication summary

Our knowledge of viral host ranges remains limited. Completing this picture by identifying unknown hosts of known viruses is an important research aim that can help identify and mitigate zoonotic and animal-disease risks, such as spill-over from animal reservoirs into human populations. To address this knowledge-gap we apply a divide-and-conquer approach which separates viral, mammalian and network features into three unique perspectives, each predicting associations independently to enhance predictive power. Our approach predicts over 20,000 unknown associations between known viruses and susceptible mammalian species, suggesting that current knowledge underestimates the number of associations in wild and semi-domesticated mammals by a factor of 4.3, and the average potential mammalian host-range of viruses by a factor of 3.2. In particular, our results highlight a significant knowledge gap in the wild reservoirs of important zoonotic and domesticated mammals' viruses: specifically, lyssaviruses, bornaviruses and rotaviruses.

Machine Learning Virus Physiological Phenomena Animals Disease Reservoirs Host Specificity Humans Mammals Reproducibility of Results Virus Diseases Viruses Zoonoses

Structured evidence records

Evidence records

4 total

Reservoir Ecology 3 records

Reservoir Ecology Extraction confidence 0.75

Key finding

Machine-learning predictions indicate unknown or under-characterized wild mammalian reservoirs for lyssaviruses, bornaviruses, and rotaviruses.

Virus

Host

Location

Supporting text

Our results highlight a significant knowledge gap in the wild reservoirs of important zoonotic and domesticated mammals' viruses: specifically, lyssaviruses, bornaviruses and rotaviruses.

Method: machine learning; predictive modeling

Reservoir Ecology Extraction confidence 0.75

Key finding

Machine-learning predictions indicate unknown or under-characterized wild mammalian reservoirs for lyssaviruses, bornaviruses, and rotaviruses.

Virus

Host

Location

Supporting text

Our results highlight a significant knowledge gap in the wild reservoirs of important zoonotic and domesticated mammals' viruses: specifically, lyssaviruses, bornaviruses and rotaviruses.

Method: machine learning; predictive modeling

Reservoir Ecology Extraction confidence 0.75

Key finding

Machine-learning predictions indicate unknown or under-characterized wild mammalian reservoirs for lyssaviruses, bornaviruses, and rotaviruses.

Virus

Host

Location

Supporting text

Our results highlight a significant knowledge gap in the wild reservoirs of important zoonotic and domesticated mammals' viruses: specifically, lyssaviruses, bornaviruses and rotaviruses.

Method: machine learning; predictive modeling

Cross Species Transmission 1 records

Cross Species Transmission Extraction confidence 0.80

Key finding

Machine learning predicted numerous previously unknown viral associations among mammalian species, including lyssaviruses, bornaviruses, and rotaviruses, suggesting unrecognized animal-to-animal transmission potential.

Virus

Host

Location

Supporting text

Our approach predicts over 20,000 unknown associations between known viruses and susceptible mammalian species, suggesting that current knowledge underestimates the number of associations in wild and semi-domesticated mammals by a factor of 4.3.

Method: machine learning; network analysis
Study design: computational prediction
Transmission direction: animal-to-animal

Citation context

References

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PMID 24003179	A strategy to estimate unknown viral diversity in mammals	Anthony	2013
PMID 15378043	Transmission cycles, host range, evolution and emergence of arboviral disease	Weaver	2004
PMID 25064563	The role of viral evolution in rabies host shifts and emergence	Mollentze	2014
PMID 28636590 In OmniVira	Host and viral traits predict zoonotic spillover from mammals.	Olival	2017
PMID 17848070	Bats, civets and the emergence of SARS	Wang	2007
PMID 31843456	Enzootic patterns of Middle East respiratory syndrome coronavirus in imported African and local Arabian dromedary camels: a prospective genomic study	El-Kafrawy	2019
PMID 32218527 In OmniVira	Identifying SARS-CoV-2-related coronaviruses in Malayan pangolins.	Lam	2020
PMID 26445169 In OmniVira	Spillover and pandemic properties of zoonotic viruses with high host plasticity.	Kreuder Johnson	2015
PMID 30385576	Predicting reservoir hosts and arthropod vectors from evolutionary signatures in RNA virus genomes	Babayan	2018
PMID 26401317	Database of host-pathogen and related species interactions, and their global distribution	Wardeh	2015
PMID 32296543	Newly identified viral genomes in pangolins with fatal disease	Gao	2020
PMID 32336945 In OmniVira	Distinct spread of DNA and RNA viruses among mammals amid prominent role of domestic species.	Wells	2020
PMID 32019444 In OmniVira	Integration of shared-pathogen networks and machine learning reveals the key aspects of zoonoses and predicts mammalian reservoirs.	Wardeh	2020
PMID 23378666	A comparison of bats and rodents as reservoirs of zoonotic viruses: are bats special? Proc. R	Luis	2013
PMID 23389893	Using network theory to identify the causes of disease outbreaks of unknown origin	Bogich	2013
-	A hierarchical bayesian model for predicting ecological interactions using scaled evolutionary relationships	Elmasri	2020
PMID 35066873	Predicting missing links in global host-parasite networks. bioRxiv 10.1101/2020.02.25.965046 (2020)	Farrell	2020
PMID 28542200	Predicting cryptic links in host-parasite networks	Dallas	2017
PMID 31182813	Global estimates of mammalian viral diversity accounting for host sharing	Carlson	2019
-	Predicting wildlife hosts of betacoronaviruses for SARS-CoV-2 sampling prioritization. bioRxiv 10.1101/2020.05.22.111344 (2020)	Becker	2020
-	Link prediction via higher-order motif features. In Machine Learning and Knowledge Discovery in Databases. ECML PKDD 2019. Lecture Notes in Computer Science	Abuoda	2020
PMID 12399590	Network motifs: simple building blocks of complex networks	Milo	2002
PMID 15001784	Superfamilies of evolved and designed networks	Milo	2004
PMID 30973867	Network motifs and their origins	Stone	2019
PMID 16187794	Dynamic properties of network motifs contribute to biological network organization	Prill	2005
PMID 12732301	Motifs, modules and games in bacteria	Wolf	2003
-	Motifs in bipartite ecological networks: uncovering indirect interactions	Simmons	2019
-	Simple trophic modules for complex food webs	Bascompte	2005
PMID 21536884	General rules for managing and surveying networks of pests, diseases, and endangered species	Chadès	2011
PMID 32385239	Predicting the global mammalian viral sharing network using phylogeography	Albery	2020
PMID 18258002	Evolutionary relationships between bat coronaviruses and their hosts	Cui	2007
PMID 17848067	Emergence and persistence of hantaviruses	Klein	2007
PMID 26038558	Rodent reservoirs of future zoonotic diseases	Han	2015
PMID 16186241	Phylogenetic relationships among rhabdoviruses inferred using the L polymerase gene	Bourhy	2005
PMID 25093425	Lyssaviruses and bats: emergence and zoonotic threat	Banyard	2014
PMID 9284379	Borna disease virus infection in animals and humans	Richt	1997
PMID 26337738	Rotavirus infection: a disease of the past? Infect	Dennehy	2015
PMID 26195733	Global trends in infectious diseases at the wildlife-livestock interface	Wiethoelter	2015
PMID 28943867	Editorial: virus discovery by metagenomics: the (Im)possibilities	Dutilh	2017
PMID 26302775	The adaptive evolution of virulence: a review of theoretical predictions and empirical tests	Cressler	2016
PMID 32814037	Species-specific evolution of ebola virus during replication in human and bat cells	Whitfield	2020
PMID 29111455	Meta-transcriptomics and the evolutionary biology of RNA viruses	Shi	2018
PMID 27414412	Undiscovered bat hosts of filoviruses	Han	2016
PMID 30575757	Predicting wildlife reservoirs and global vulnerability to zoonotic Flaviviruses	Pandit	2018
PMID 21252339	Animal migration and infectious disease risk	Altizer	2011
PMID 16022772	Wildlife trade and global disease emergence	Karesh	2005
PMID 16460942	Animal movements and the spread of infectious diseases	Fèvre	2006
PMID 32881980	Possibility for reverse zoonotic transmission of sars-cov-2 to free-ranging wildlife: a case study of bats	Olival	2020
PMID 33594041	Predicting mammalian hosts in which novel coronaviruses can be generated	Wardeh	2021
PMID 29066781	Global hotspots and correlates of emerging zoonotic diseases	Allen	2017
PMID 26038558	Rodent reservoirs of future zoonotic diseases	Han	2015
PMID 23193287	GenBank. Nucleic Acids Res. 2013;41:D36–D42	Benson	2013
-	for B. I. GenBank	Bethesda (MD): National Library of Medic	1982
-	PubMed	Bethesda (MD): National Library of Medic	1946
PMID 22139910	The NCBI taxonomy database	Federhen	2012
PMID 13956816	Laboratory diagnosis of virus diseases	ISHIDA	1962
PMID 24670154	Comparison of serological and molecular panels for diagnosis of vector-borne diseases in dogs	Maggi	2014
PMID 29111456	Viruses associated with Antarctic wildlife: From serology based detection to identification of genomes using high throughput sequencing	Smeele	2018
-	V., Bowyer, K. W., Hall, L. O. & Kegelmeyer, W. P. SMOTE: synthetic minority over-sampling technique	Chawla	2002
-	Is “better data” better than “better data miners”?: on the benefits of tuning SMOTE for defect prediction. 12 10.1145/3180155.3180197	Agrawal	-
-	Do we need hundreds of classifiers to solve real world classification problems? J	Fernández-Delgado	2014
-	The impact of class rebalancing techniques on the performance and interpretation of defect prediction models. IEEE Transactions on Software Engineering 46 , 1200–1219 (2020)	Tantithamthavorn	2020
-	Building Predictive Models in R Using the caret Package	Kuhn	2008
-	Futility analysis in the cross-validation of machine learning Models1. arXiv	Kuhn	2014
PMID 20660197	Viral mutation rates viral mutation rates	Sanjuán	2010
-	Structure and classification of retroviruses. In The Retroviridae 19–49 (Springer US, 1992). 10.1007/978-1-4615-3372-6_2	Coffin	1992
PMID 15169567	Early steps of retrovirus replicative cycle. Retrovirology 1 , 9 (2004)	Nisole	2004
PMID 29250047	The different faces of rolling-circle replication and its multifunctional initiator proteins	Wawrzyniak	2017
PMID 25082896	Order and disorder control the functional rearrangement of influenza hemagglutinin	Lin	2014
PMID 29522750	Common features of enveloped viruses and implications for immunogen design for next-generation vaccines	Rey	2018
PMID 16449200	Base-stacking and base-pairing contributions into thermal stability of the DNA double helix	Yakovchuk	2006
PMID 17945261	Viral reproductive strategies: how can lytic viruses be evolutionarily competitive? J	Komarova	2007
PMID 31401961	Host phylogenetic distance drives trends in virus virulence and transmissibility across the animal–human interface. Philos. Trans. R	Guth	2019
PMID 25375777	The evolution and genetics of virus host shifts	Longdon	2014
PMID 29514973	Characterizing the phylogenetic specialism–generalism spectrum of mammal parasites	Park	2018
PMID 18445561 In OmniVira	Phylogeny and geography predict pathogen community similarity in wild primates and humans.	Davies	2008
-	A general coefficient of similarity and some of its properties	Gower JC. A general coefficient of simil	1971
-	On the challenge of treating various types of variables: application for improving the measurement of functional diversity	Pavoine	2009
PMID 23382431	Global mapping of infectious disease. Philos. Trans. R. Soc. Lond. B	Hay	2013
PMID 30760757	Global disease outbreaks associated with the 2015–2016 El Niño Event	Anyamba	2019
PMID 28029378	Urbanization and disease emergence: dynamics at the wildlife-livestock-human interface	Hassell	2017

Evidence overview

Evidence 4

Types 2

Virus 3

Host 1

Evidence types

Reservoir Ecology 3 Cross Species Transmission 1

Linked entities

Viruses

Hosts

Locations

Publication metadata

Journal: Nature communications
Volume / Issue / Pages: 12 / 1 / 3954
ISSN: 2041-1723
Journal country: England
DOI: 10.1038/s41467-021-24085-w