Ecological Context Influences Epidemic Size and Parasite-Driven Evolution

Duffy, Meghan A.; Ochs, Jessica Housley; Penczykowski, Rachel M.; Civitello, David J.; Klausmeier, Christopher A.; Hall, Spencer R.

doi:10.1126/science.1215429

Cited by 99 publications

(115 citation statements)

References 32 publications

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“…High levels of fish predation could result in populations dominated by juvenile Daphnia, which tend to be more susceptible to infection. Fish predation has been shown to limit the size of epidemics of the yeast parasite Metschnikowia bicuspidata (Duffy et al, 2012); it is thus possible that in addition to the selective culling by fish of parasitised Daphnia or reductions in overall host density (Duffy and Hall, 2008;Duffy et al, 2005), fish predation also alters epidemic size through changes in the age structure, and thus resistance competence, of the population. Of course, predators that select the smallest, and presumably youngest, individuals [like the invertebrate Chaoborus (Riessen and Young, 2005)] will have the opposite effect, resulting in populations dominated by older Daphnia.…”

Section: Research Articlementioning

confidence: 99%

“…Much work has been carried out on the causes and consequences of variation in age structure (Charlesworth, 1994;De Roos et al, 2003;Sterner, 1998), and the impact of age structure on virulence evolution and epidemic spread (Castillo-Chavez et al, 1989;Duffy et al, 2012). Empirical data on the susceptibility of different age classes could provide insight into how ecological factors that affect age structure could modulate disease resistance and spread.…”

Section: Introductionmentioning

confidence: 99%

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The development of pathogen resistance in Daphnia magna: implications for disease spread in age-structured populations

Garbutt

O'Donoghue

McTaggart

et al. 2014

Journal of Experimental Biology

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Immunity in vertebrates is well established to develop with time, but the ontogeny of defence in invertebrates is markedly less studied. Yet, age-specific capacity for defence against pathogens, coupled with age structure in populations, has widespread implications for disease spread. Thus, we sought to determine the susceptibility of hosts of different ages in an experimental invertebrate host-pathogen system. In a series of experiments, we show that the ability of Daphnia magna to resist its natural bacterial pathogen Pasteuria ramosa changes with host age. Clonal differences make it difficult to draw general conclusions, but the majority of observations indicate that resistance increases early in the life of D. magna, consistent with the idea that the defence system develops with time. Immediately following this, at about the time when a daphnid would be most heavily investing in reproduction, resistance tends to decline. Because many ecological factors influence the age structure of Daphnia populations, our results highlight a broad mechanism by which ecological context can affect disease epidemiology. We also show that a previously observed protective effect of restricted maternal food persists throughout the entire juvenile period, and that the protective effect of prior treatment with a small dose of the pathogen ('priming') persists for 7 days, observations that reinforce the idea that immunity in D. magna can change over time. Together, our experiments lead us to conclude that invertebrate defence capabilities have an ontogeny that merits consideration with respect to both their immune systems and the epidemic spread of infection.

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Section: Research Articlementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The development of pathogen resistance in Daphnia magna: implications for disease spread in age-structured populations

Garbutt

O'Donoghue

McTaggart

et al. 2014

Journal of Experimental Biology

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“…In addition, amphibian species with small-bodied, fast-developing phenotypes were more susceptible to infection by trematodes and, subsequently, more likely to be malformed and die. These and other recent studies (e.g., Nunn et al 2003;Todesco et al 2010;van der Most et al 2011;Duffy et al 2012;Huang et al 2013) suggest that large-bodied, slow-return phenotypes resist pathogen activity. As theoretical models predict that more-resistant phenotypes reduce pathogen transmission and prevalence (e.g., Roy and Kirchner 2000), the evidence suggests that small-bodied, quick-return hosts are less resistant and, thus, have greater potential to contribute to transmission.…”

Section: Developmental Tempo and Host Defenses 173mentioning

confidence: 96%

Why Is Living Fast Dangerous? Disentangling the Roles of Resistance and Tolerance of Disease

Cronin

Rúa

Mitchell

2014

The American Naturalist

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Online enhancement: appendixes. Dryad data: http://dx.doi.org/10.5061/dryad.8mq2q.abstract: Primary axes of host developmental tempo (HDT; e.g., slow-quick return continuum) represent latent biological processes and are increasingly used to a priori identify hosts that contribute disproportionately more to pathogen transmission. The influence of HDT on host contributions to transmission depends on how HDT influences both resistance and tolerance of disease. Here, we use structural equation modeling to address known limitations of conventional measures of resistance and tolerance. We first provide a general resistance-tolerance metamodel from which system-specific models can be derived. We then develop a model specific to a group of vector-transmitted viruses that infect hundreds of grass species worldwide. We tested the model using experimental inoculations of six phylogenetically paired grass species. We found that (1) host traits covaried according to a prominent HDT axis, the slow-quick continuum; (2) infection caused a greater reduction in the performance of quick returns, with 180% of that greater impact explained by lesser resistance; (3) resistance-tolerance trade-off did not occur; and (4) phylogenetic control was necessary to measure the slow-quick continuum, resistance, and tolerance. These results support the conclusion that HDT's main influence on host contributions to transmission is via resistance. More broadly, this study provides a framework for quantifying HDT's influence on host contributions to transmission.

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“…Such traits could also provide a mechanistic basis for counterselection of resistance in our model. Despite considerable attention to the evolutionary impact of pathogens on hosts in ecology, longitudinal studies documenting the inextricably linked dynamics of transmission and pathogenmediated evolutionary selection-and their environmental dependence-have been constrained to a narrow set of systems (22)(23)(24)(25)(26)59). Aided by rich datasets describing epidemiological dynamics, selection, and environmental drivers of transmission, our modeling links Victorian era observations to the longstanding mystery of what caused reductions in epidemic magnitude during the third plague pandemic in India.…”

Section: Discussionmentioning

confidence: 99%

“…Despite these direct findings regarding expansion of resistance in a host population, in few instances has it been possible to provide insight into the coupled trajectories of transmission, evolutionary dynamics, and their environmental drivers (22). In a model system of the plankton species Daphnia dentifera and its parasite Metschnikowia bicuspidata, environmental factors affecting transmission intermittently alter the intensity of selection for resistance, in turn impacting the size and timing of recurrent epidemics (23)(24)(25). In a rare example from vertebrates, the intensity of seasonal myxomatosis epidemics in Australia predicted year to year variation in the susceptibility of wild rabbits (26) in a broader context of decades-long selection for resistance (12).…”

mentioning

confidence: 99%

Climatic and evolutionary drivers of phase shifts in the plague epidemics of colonial India

Lewnard

Townsend

2016

Proc. Natl. Acad. Sci. U.S.A.

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Immune heterogeneity in wild host populations indicates that disease-mediated selection is common in nature. However, the underlying dynamic feedbacks involving the ecology of disease transmission, evolutionary processes, and their interaction with environmental drivers have proven challenging to characterize. Plague presents an optimal system for interrogating such couplings: Yersinia pestis transmission exerts intense selective pressure driving the local persistence of disease resistance among its wildlife hosts in endemic areas. Investigations undertaken in colonial India after the introduction of plague in 1896 suggest that, only a decade after plague arrived, a heritable, plague-resistant phenotype had become prevalent among commensal rats of cities undergoing severe plague epidemics. To understand the possible evolutionary basis of these observations, we developed a mathematical model coupling environmentally forced plague dynamics with evolutionary selection of rats, capitalizing on extensive archival data from Indian Plague Commission investigations. Incorporating increased plague resistance among rats as a consequence of intense natural selection permits the model to reproduce observed changes in seasonal epidemic patterns in several cities and capture experimentally observed associations between climate and flea population dynamics in India. Our model results substantiate Victorian era claims of host evolution based on experimental observations of plague resistance and reveal the buffering effect of such evolution against environmental drivers of transmission. Our analysis shows that historical datasets can yield powerful insights into the transmission dynamics of reemerging disease agents with which we have limited contemporary experience to guide quantitative modeling and inference.modeling | infectious disease | vector-borne disease | zoonosis | immunoecology

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Ecological Context Influences Epidemic Size and Parasite-Driven Evolution

Cited by 99 publications

References 32 publications

The development of pathogen resistance in Daphnia magna: implications for disease spread in age-structured populations

The development of pathogen resistance in Daphnia magna: implications for disease spread in age-structured populations

Why Is Living Fast Dangerous? Disentangling the Roles of Resistance and Tolerance of Disease

Climatic and evolutionary drivers of phase shifts in the plague epidemics of colonial India

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