Faculty Opinions recommendation of Host-parasite 'Red Queen' dynamics archived in pond sediment.

AbstractWinnerless coevolution of hosts and parasites could exhibit Red Queen dynamics, which is characterized by parasite-driven cyclic switching of expressed host phenotypes. We hypothesize that the application of antibiotics to suppress the reproduction of parasites can provide opportunity for the hosts to escape such winnerless coevolution. Here, we formulate a minimal mathematical model of host-parasite interaction involving multiple host phenotypes that are targeted by adapting parasites. Our model predicts the levels of antibiotic effectiveness that can steer the parasite-driven cyclic switching of host phenotypes (heteroclinic oscillations) to a stable equilibrium of host survival. Our simulations show that uninterrupted application of antibiotic with high-level effectiveness (> 85%) is needed to escape the Red Queen dynamics. Intermittent and low level of antibiotic effectiveness are indeed useless to stop host-parasite coevolution. This study can be a guide in designing good practices and protocols to minimize risk of further progression of parasitic infections.

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Host–parasite co-evolution

10.1093/oso/9780198832140.003.0014 ◽

2021 ◽

pp. 389-416

Author(s):

Paul Schmid-Hempel

Keyword(s):

Meiotic Recombination ◽

Evolutionary Process ◽

Host Switching ◽

Response To Selection ◽

Red Queen ◽

Arms Races ◽

Migration Rates ◽

Frequency Changes ◽

Host Parasite ◽

Relative Migration

Macroevolutionary patterns concern phylogenies of hosts and their parasites. From those, co-speciation occurs; but host switching is a common evolutionary process and more likely when hosts are close phylogenetically and geographical ranges overlap. Microevolutionary processes refer to allele frequency changes within population. In arms races, traits of hosts and parasites evolve in one direction in response to selection by the other party. With selective sweeps, advantageous alleles rapidly spread in host or parasite population and can become fixed. With antagonistic negative frequency-dependent fluctuations (Red Queen dynamics) genetic polymorphism in populations can be maintained, even through speciation events. A Red Queen co-evolutionary process can favour sexual over asexual reproduction and maintain meiotic recombination despite its other disadvantages (two-fold cost of sex). Local adaptation of host and parasites exist in various combinations; the relative migration rates of the two parties, embedded in a geographical mosaic, are important for this process.

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Red Queen strange attractors in host–parasite replicator gene-for-gene coevolution

Chaos Solitons & Fractals ◽

10.1016/j.chaos.2006.08.031 ◽

2007 ◽

Vol 32 (5) ◽

pp. 1666-1678 ◽

Cited By ~ 8

Author(s):

Josep Sardanyés ◽

Ricard V. Solé

Keyword(s):

Strange Attractors ◽

Red Queen ◽

Host Parasite ◽

Gene For Gene

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Feedback Between Coevolution and Epidemiology Can Help or Hinder the Maintenance of Genetic Variation in Host-Parasite Models

10.1101/2020.04.07.029322 ◽

2020 ◽

Author(s):

Ailene MacPherson ◽

Matthew J. Keeling ◽

Sarah P. Otto

Keyword(s):

Genetic Variation ◽

Population Fluctuations ◽

Red Queen ◽

Neutral Drift ◽

Disease Epidemiology ◽

Two Factors ◽

Population Sizes ◽

Host Genetic ◽

Host Parasite ◽

The Impact

AbstractUnderstanding if and when coevolution helps maintains genetic variation in hosts of a directly-transmissible pathogen is fundamental to quantifying the prevalence and impact of coevolution on disease epidemiology. Here, we extend our previous work on the maintenance of genetic variation in a classic matching-alleles coevolutionary model by exploring the effects of ecological and epidemiological feedbacks, where both allele frequencies and population sizes are allowed to vary over time. In general, we find that coevolution rarely maintains more host genetic variation than expected under neutral genetic drift alone. When and if coevolution maintains or depletes genetic variation relative to neutral drift is determined, predominantly, by two factors: the deterministic stability of the Red Queen allele frequency cycles and the frequency at which pathogen fixation occurs, as this results in directional selection and the depletion of genetic variation in the host. Compared to purely coevolutionary models with constant host and pathogen population sizes, ecological and epidemiological feedbacks stabilize Red Queen cycles deterministically, but population fluctuations in the pathogen increase the rate of pathogen fixation, especially in epidemiological models. Taken together our results illustrate the importance of considering the ecological and epidemiological context in which coevolution occurs when examining the impact of Red Queen cycles on genetic variation.

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The potential for arms race and Red Queen coevolution in a protist host–parasite system

Ecology and Evolution ◽

10.1002/ece3.1314 ◽

2014 ◽

Vol 4 (24) ◽

pp. 4775-4785 ◽

Cited By ~ 18

Author(s):

Lars Råberg ◽

Elisabet Alacid ◽

Esther Garces ◽

Rosa Figueroa

Keyword(s):

Arms Race ◽

Red Queen ◽

Host Parasite

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Host-parasite Red Queen dynamics with phase-locked rare genotypes

Science Advances ◽

10.1126/sciadv.1501548 ◽

2016 ◽

Vol 2 (3) ◽

pp. e1501548 ◽

Cited By ~ 21

Author(s):

Jomar F. Rabajante ◽

Jerrold M. Tubay ◽

Hiromu Ito ◽

Takashi Uehara ◽

Satoshi Kakishima ◽

...

Keyword(s):

Controlled Environment ◽

Stochastic Noise ◽

Red Queen ◽

Negative Frequency Dependent Selection ◽

Cyclic Changes ◽

Marine Microbial Communities ◽

Host Parasite ◽

Low Amplitude ◽

First Time ◽

The Red Queen

Interactions between hosts and parasites have been hypothesized to cause winnerless coevolution, called Red Queen dynamics. The canonical Red Queen dynamics assume that all interacting genotypes of hosts and parasites undergo cyclic changes in abundance through negative frequency-dependent selection, which means that any genotype could become frequent at some stage. However, this prediction cannot explain why many rare genotypes stay rare in natural host-parasite systems. To investigate this, we build a mathematical model involving multihost and multiparasite genotypes. In a deterministic and controlled environment, Red Queen dynamics occur between two genotypes undergoing cyclic dominance changes, whereas the rest of the genotypes remain subordinate for long periods of time in phase-locked synchronized dynamics with low amplitude. However, introduction of stochastic noise in the model might allow the subordinate cyclic host and parasite types to replace dominant cyclic types as new players in the Red Queen dynamics. The factors that influence such evolutionary switching are interhost competition, specificity of parasitism, and degree of stochastic noise. Our model can explain, for the first time, the persistence of rare, hardly cycling genotypes in populations (for example, marine microbial communities) undergoing host-parasite coevolution.

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The Red Queen and King in finite populations

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1702020114 ◽

2017 ◽

Vol 114 (27) ◽

pp. E5396-E5405 ◽

Cited By ~ 12

Author(s):

Carl Veller ◽

Laura K. Hayward ◽

Christian Hilbe ◽

Martin A. Nowak

Keyword(s):

Red Queen ◽

Rates Of Evolution ◽

Generation Times ◽

Host Parasite ◽

Red Queen Effect ◽

Two Populations ◽

The Red Queen ◽

Demographic Evolution ◽

Insight Into

In antagonistic symbioses, such as host–parasite interactions, one population’s success is the other’s loss. In mutualistic symbioses, such as division of labor, both parties can gain, but they might have different preferences over the possible mutualistic arrangements. The rates of evolution of the two populations in a symbiosis are important determinants of which population will be more successful: Faster evolution is thought to be favored in antagonistic symbioses (the “Red Queen effect”), but disfavored in certain mutualistic symbioses (the “Red King effect”). However, it remains unclear which biological parameters drive these effects. Here, we analyze the effects of the various determinants of evolutionary rate: generation time, mutation rate, population size, and the intensity of natural selection. Our main results hold for the case where mutation is infrequent. Slower evolution causes a long-term advantage in an important class of mutualistic interactions. Surprisingly, less intense selection is the strongest driver of this Red King effect, whereas relative mutation rates and generation times have little effect. In antagonistic interactions, faster evolution by any means is beneficial. Our results provide insight into the demographic evolution of symbionts.

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