Modeling the Ecological Niche of
            <i>Bacillus anthracis</i>
            to Map Anthrax Risk in Kyrgyzstan

Blackburn, Jason K.; Matakarimov, Saitbek; Kozhokeeva, Sabira; Tagaeva, Zhyldyz; Bell, Lindsay; Kracalik, Ian; Zhunushov, Asankadyr

doi:10.4269/ajtmh.16-0758

Cited by 27 publications

(27 citation statements)

References 33 publications

(51 reference statements)

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“…Ecological niche modeling (ENM) has proven useful to forecast the distribution of a vast number of organisms [10-13] and is increasingly employed to predict parasite distributions locally and globally [14][15][16][17]. Despite great strides made in the implementation of ENM to forecast complex biological phenomena such as disease systems [18], traditional frameworks may render biologically unrealistic predictions and thus must be revised, as we show in this review.…”

Section: Challenges and Opportunities To Map Disease Riskmentioning

confidence: 99%

“…However, the black-box oversimplification may be perilous as it neglects ecological complexity (e.g., the identity of key host species for transmission). Alternatively, component-based approaches consider the individual ecologies of all species involved in disease transmission (e.g., parasites, hosts) [16,17,32]. This approach allows the identification of host species and prioritization of areas for disease surveillance and control.…”

Section: Modeling Disease Systemsmentioning

confidence: 99%

“…As human activities intensify, contact with wildlife and exposure to novel parasites increase, potentially driving zoonotic disease emergence [1,7]. Given the threat that EIDs pose to human populations, understanding the underlying drivers of parasite geographic distribution and their spillover to humans is particularly relevant for epidemiologists, public-health practitioners, and policy makers [9].Ecological niche modeling (ENM) has proven useful to forecast the distribution of a vast number of organisms [10-13] and is increasingly employed to predict parasite distributions locally and globally [14][15][16][17]. Despite great strides made in the implementation of ENM to forecast complex biological phenomena such as disease systems [18], traditional frameworks may render biologically unrealistic predictions and thus must be revised, as we show in this review.…”

mentioning

confidence: 99%

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An Ecological Framework for Modeling the Geography of Disease Transmission

Johnson

Escobar

Zambrana‐Torrelio

2019

Trends in Ecology & Evolution

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Ecological niche modeling (ENM) is widely employed in ecology to predict species' potential geographic distributions in relation to their environmental constraints and is rapidly becoming the gold-standard method for disease risk mapping. However, given the biological complexity of disease systems, the traditional ENM framework requires reevaluation. We provide an overview of the application of ENM to disease systems and propose a theoretical framework based on the biological properties of both hosts and parasites to produce reliable outputs resembling disease system distributions. Additionally, we discuss the differences between biological considerations when implementing ENM for distributional ecology and epidemiology. This new framework will help the field of disease ecology and applications of biogeography in the epidemiology of infectious diseases. Challenges and Opportunities to Map Disease RiskThe recent rise of emerging infectious diseases (EIDs) (see Glossary) [1] has increased the burden of infectious diseases and negatively impacted the global economy [2][3][4][5]. Approximately 60% of emerging human diseases are caused by pathogenic parasites of animal origin (zoonoses), particularly wildlife [6]. As human activities intensify, contact with wildlife and exposure to novel parasites increase, potentially driving zoonotic disease emergence [1,7]. Given the threat that EIDs pose to human populations, understanding the underlying drivers of parasite geographic distribution and their spillover to humans is particularly relevant for epidemiologists, public-health practitioners, and policy makers [9].Ecological niche modeling (ENM) has proven useful to forecast the distribution of a vast number of organisms [10-13] and is increasingly employed to predict parasite distributions locally and globally [14][15][16][17]. Despite great strides made in the implementation of ENM to forecast complex biological phenomena such as disease systems [18], traditional frameworks may render biologically unrealistic predictions and thus must be revised, as we show in this review. We provide an overview of the current state of disease ENM and propose a framework based on the biological properties of both parasites and hosts to produce reliable outputs resembling disease systems distributions. Specifically, our theoretical framework: (i) addresses the selection of an appropriate modeling approach and highlights the importance of including biologically sound predictor variables; (ii) proposes the concept of a microscale parasitic niche defined by host traits to identify relevant parasite-host associations; and (iii) integrates traditional parasite ENM with the proposed microscale niche to better understand geographic distributions and improve fine-scale predictions of disease transmission risk. ENM and Biotic InteractionsENM estimates the distributions of species by linking their geographic occurrence with their environmental constraints, often utilizing correlative approaches (detailed explanations in [18]). Highlights

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Section: Challenges and Opportunities To Map Disease Riskmentioning

confidence: 99%

Section: Modeling Disease Systemsmentioning

confidence: 99%

mentioning

confidence: 99%

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An Ecological Framework for Modeling the Geography of Disease Transmission

Johnson

Escobar

Zambrana‐Torrelio

2019

Trends in Ecology & Evolution

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“…It is worth noting that while anthrax is effectively cosmopolitan at a global scale, no global map of its distribution has ever been constructed; instead, most studies have mapped its distribution using ENMs constructed at the regional or national scale, often in close partnership with public health efforts. Studies using ENMs to map anthrax have been carried out in at least 12 countries, including Australia (Barro et al ., ), Cameroon, Chad, and Nigeria (Blackburn et al ., ), China (Chen et al ., ), Ghana (Kracalik et al ., ), Italy and Kazakhstan (Mullins et al ., ), Kyrgyzstan (Blackburn et al ., ), Mexico and the USA (Blackburn, ), and Zimbabwe (Chikerema et al ., ). In many of these regions, ENMs are the most accessible statistical tool for mapping risk, and therefore guide spatial prioritization for wildlife surveillance and livestock vaccination campaigns; however, follow‐up studies evaluating the efficacy of ENM‐based campaigns are currently rare (a problem not unique to anthrax work).…”

Section: Anthrax: a Case Study In Slow Integrationmentioning

confidence: 99%

Spores and soil from six sides: interdisciplinarity and the environmental biology of anthrax (Bacillus anthracis)

et al. 2018

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Environmentally transmitted diseases are comparatively poorly understood and managed, and their ecology is particularly understudied. Here we identify challenges of studying environmental transmission and persistence with a six-sided interdisciplinary review of the biology of anthrax (Bacillus anthracis). Anthrax is a zoonotic disease capable of maintaining infectious spore banks in soil for decades (or even potentially centuries), and the mechanisms of its environmental persistence have been the topic of significant research and controversy. Where anthrax is endemic, it plays an important ecological role, shaping the dynamics of entire herbivore communities. The complex eco-epidemiology of anthrax, and the mysterious biology of Bacillus anthracis during its environmental stage, have necessitated an interdisciplinary approach to pathogen research. Here, we illustrate different disciplinary perspectives through key advances made by researchers working in Etosha National Park, a long-term ecological research site in Namibia that has exemplified the complexities of the enzootic process of anthrax over decades of surveillance. In Etosha, the role of scavengers and alternative routes (waterborne transmission and flies) has proved unimportant relative to the long-term * Authors for correspondence: (Colin J. Carlson-Tel.: +1 (510) 990 2258; E-mail: ccarlson@sesync.org; Wayne M. Getz-Tel.: +1 510 642 8745; E-mail: wgetz@berkeley.edu; Nils C. Stenseth-Tel.: +47-22854584/+47-22854400; E-mail: n.c.stenseth@ibv.uio.no).Biological Reviews (2018) 000-000 © 2018 Cambridge Philosophical Society 2 Colin J. Carlson and others persistence of anthrax spores in soil and their infection of herbivore hosts. Carcass deposition facilitates green-ups of vegetation to attract herbivores, potentially facilitated by the role of anthrax spores in the rhizosphere. The underlying seasonal pattern of vegetation, and herbivores' immune and behavioural responses to anthrax risk, interact to produce regular 'anthrax seasons' that appear to be a stable feature of the Etosha ecosystem. Through the lens of microbiologists, geneticists, immunologists, ecologists, epidemiologists, and clinicians, we discuss how anthrax dynamics are shaped at the smallest scale by population genetics and interactions within the bacterial communities up to the broadest scales of ecosystem structure. We illustrate the benefits and challenges of this interdisciplinary approach to disease ecology, and suggest ways anthrax might offer insights into the biology of other important pathogens. Bacillus anthracis, and the more recently emerged Bacillus cereus biovar anthracis, share key features with other environmentally transmitted pathogens, including several zoonoses and panzootics of special interest for global health and conservation efforts. Understanding the dynamics of anthrax, and developing interdisciplinary research programs that explore environmental persistence, is a critical step forward for understanding these emerging threats.

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“…It is worth noting that while anthrax is effectively cosmopolitan on a global scale, no global map of its distribution has ever been constructed; instead, most studies have mapped its distribution using ENMs constructed at the regional or national scale, often in close partnership with public health efforts. Studies using ENMs to map anthrax have been done in at least 12 countries, including Australia 141 ; Cameroon, Chad, and Nigeria 142 ; China 143 ; Ghana 144 ; Italy and Kazakhstan 145 ; Kyrgyzstan 146 ; Mexico and the United States 147 ; and Zimbabwe. 148 In many of these regions, ENMs are the most accessible statistical tool for mapping risk, and therefore guide spatial prioritization for wildlife surveillance and livestock vaccination campaigns; however, follow-up studies evaluating the efficacy of ENM-based campaigns are currently fairly lacking (a problem not unique to anthrax work).…”

Section: Anthrax: a Case Study In Slow Integrationmentioning

confidence: 99%

Spores and soil from six sides: interdisciplinarity and the environmental biology of anthrax (Bacillus anthracis)

Carlson

Getz

Kausrud

et al. 2017

Preprint

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5Environmentally transmitted diseases are comparatively poorly understood and managed, and 3 6 their ecology is particularly understudied. Here we identify challenges of studying shaped at the smallest scale by population genetics and interactions within the bacterial 5 0 communities up to the broadest scales of ecosystem structure. We illustrate the benefits and 5 1 challenges of this interdisciplinary approach to disease ecology, and suggest ways anthrax might 5 2 offer insights into the biology of other important pathogens.

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Modeling the Ecological Niche of Bacillus anthracis to Map Anthrax Risk in Kyrgyzstan

Cited by 27 publications

References 33 publications

An Ecological Framework for Modeling the Geography of Disease Transmission

An Ecological Framework for Modeling the Geography of Disease Transmission

Spores and soil from six sides: interdisciplinarity and the environmental biology of anthrax (Bacillus anthracis)

Spores and soil from six sides: interdisciplinarity and the environmental biology of anthrax (Bacillus anthracis)

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