The Molecular Clock as a Tool for Understanding Host-Parasite Evolution

Evolutionary diversification can occur in allopatry or sympatry, can be unselected or driven by selection, and can be phenotypically manifested immediately or remain phenotypically latent until later manifestation in a newly encountered environment. Diversification of host-parasite interactions is frequently studied in the context of intrinsically selective coevolution, but the potential for host-parasite interaction phenotypes to diversify latently during parasite-blind evolution is rarely considered. Here we use a social bacterium experimentally adapted to several environments in the absence of phage to analyse allopatric diversification of latent host quality - the degree to which a host population supports a viral epidemic. Phage-blind evolution reduced host quality overall, with some bacteria becoming completely resistant to growth suppression by phage. Selective-environment differences generated only mild divergence in host-quality. However, selective environments nonetheless played a major role in shaping evolution by determining the degree of stochastic diversification among replicate populations within treatments. Ancestral motility genotype was also found to strongly shape patterns of latent hostquality evolution and diversification. These outcomes show that adaptive landscapes can differ in how they constrain stochastic diversification of a latent phenotype and that major effects of selection on biological diversification can be missed by focusing on trait means. Collectively, our findings suggest that latent-phenotype evolution (LPE) should inform host-parasite evolution theory and that diversification should be conceived broadly to include latent phenotypes.

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Comparative population structure and genetic diversity of Arceuthobium americanum (Viscaceae) and its Pinus host species: insight into host-parasite evolution in parasitic angiosperms

Molecular Ecology ◽

10.1046/j.0962-1083.2002.01462.x ◽

2002 ◽

Vol 11 (3) ◽

pp. 407-420 ◽

Cited By ~ 28

Author(s):

Cheryl A. Jerome ◽

Bruce A. Ford

Keyword(s):

Genetic Diversity ◽

Population Structure ◽

Host Species ◽

Arceuthobium Americanum ◽

Parasite Evolution ◽

Parasitic Angiosperms ◽

Host Parasite ◽

Insight Into ◽

Comparative Population

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Estimating effective population size for a cestode parasite infecting three-spined sticklebacks

Parasitology ◽

10.1017/s0031182018002226 ◽

2019 ◽

Vol 146 (07) ◽

pp. 883-896

Author(s):

Hannah M. Strobel ◽

Sara J. Hays ◽

Kristine N. Moody ◽

Michael J. Blum ◽

David C. Heins

Keyword(s):

Population Size ◽

Effective Population Size ◽

Gasterosteus Aculeatus ◽

Microsatellite Data ◽

Effective Population ◽

Cestode Parasite ◽

Schistocephalus Solidus ◽

Host Parasite Interactions ◽

Parasite Evolution ◽

Host Parasite

AbstractRemarkably few attempts have been made to estimate contemporary effective population size (Ne) for parasitic species, despite the valuable perspectives it can offer on the tempo and pace of parasite evolution as well as coevolutionary dynamics of host–parasite interactions. In this study, we utilized multi-locus microsatellite data to derive single-sample and temporal estimates of contemporaryNefor a cestode parasite (Schistocephalus solidus) as well as three-spined stickleback hosts (Gasterosteus aculeatus) in lakes across Alaska. Consistent with prior studies, both approaches recovered small and highly variable estimates of parasite and hostNe. We also found that estimates of hostNeand parasiteNewere sensitive to assumptions about population genetic structure and connectivity. And, while prior work on the stickleback–cestode system indicates that physiographic factors external to stickleback hosts largely govern genetic variation inS. solidus, our findings indicate that stickleback host attributes and factors internal to the host – namely body length, genetic diversity and infection – shape contemporaryNeof cestode parasites.

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Frozen Antarctic path for dispersal initiated parallel host-parasite evolution on different continents

Molecular Phylogenetics and Evolution ◽

10.1016/j.ympev.2019.02.023 ◽

2019 ◽

Vol 135 ◽

pp. 67-77 ◽

Cited By ~ 2

Author(s):

Daniel Benda ◽

Yuta Nakase ◽

Jakub Straka

Keyword(s):

Parasite Evolution ◽

Host Parasite

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Host-Parasite Evolution: General Principles and Avian Models

Journal of Animal Ecology ◽

10.2307/6007 ◽

1997 ◽

Vol 66 (6) ◽

pp. 913

Author(s):

A. K. Lindholm ◽

D. H. Clayton ◽

J. Moore

Keyword(s):

Parasite Evolution ◽

Host Parasite

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The implications of immunopathology for parasite evolution

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2012.0647 ◽

2012 ◽

Vol 279 (1741) ◽

pp. 3234-3240 ◽

Cited By ~ 11

Author(s):

Alex Best ◽

Gráinne Long ◽

Andy White ◽

Mike Boots

Keyword(s):

Immune Response ◽

Disease Severity ◽

Host Immune Response ◽

Disease Symptoms ◽

Direct Damage ◽

Host Parasite Interactions ◽

Parasite Evolution ◽

Selection For ◽

Host Parasite ◽

Individual Disease

By definition, parasites harm their hosts, but in many infections much of the pathology is driven by the host immune response rather than through direct damage inflicted by parasites. While these immunopathological effects are often well studied and understood mechanistically in individual disease interactions, there remains relatively little understanding of their broader impact on the evolution of parasites and their hosts. Here, we theoretically investigate the implications of immunopathology, broadly defined as additional mortality associated with the host's immune response, on parasite evolution. In particular, we examine how immunopathology acting on different epidemiological traits (namely transmission, virulence and recovery) affects the evolution of disease severity. When immunopathology is costly to parasites, such that it reduces their fitness, for example by decreasing transmission, there is always selection for increased disease severity. However, we highlight a number of host–parasite interactions where the parasite may benefit from immunopathology, and highlight scenarios that may lead to the evolution of slower growing parasites and potentially reduced disease severity. Importantly, we find that conclusions on disease severity are highly dependent on how severity is measured. Finally, we discuss the effect of treatments used to combat disease symptoms caused by immunopathology.

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Host-Parasite Evolution: General Principles and Avian Models Dale H. Clayton Janice Moore

The Auk ◽

10.2307/4089224 ◽

1998 ◽

Vol 115 (2) ◽

pp. 546-547

Author(s):

Marlene Zuk ◽

George Lozano

Keyword(s):

Parasite Evolution ◽

Host Parasite

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Hidden paths to endless forms most wonderful: parasite-blind diversification of host quality

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2021.0456 ◽

2021 ◽

Vol 288 (1949) ◽

Author(s):

Lisa Freund ◽

Marie Vasse ◽

Gregory J. Velicer

Keyword(s):

Host Population ◽

Host Quality ◽

Evolution Theory ◽

Evolutionary Diversification ◽

Adaptive Landscapes ◽

Host Parasite Interactions ◽

Parasite Evolution ◽

Host Evolution ◽

Host Parasite ◽

Selective Environment

Evolutionary diversification can occur in allopatry or sympatry, can be driven by selection or unselected, and can be phenotypically manifested immediately or remain latent until manifested in a newly encountered environment. Diversification of host–parasite interactions is frequently studied in the context of intrinsically selective coevolution, but the potential for host–parasite interaction phenotypes to diversify latently during parasite-blind host evolution is rarely considered. Here, we use a social bacterium experimentally adapted to several environments in the absence of phage to analyse allopatric diversification of host quality—the degree to which a host population supports a viral epidemic. Phage-blind evolution reduced host quality overall, with some bacteria becoming completely resistant to growth suppression by phage. Selective-environment differences generated only mild divergence in host quality. However, selective environments nonetheless played a major role in shaping evolution by determining the degree of stochastic diversification among replicate populations within treatments. Ancestral motility genotype was also found to strongly shape patterns of latent host-quality evolution and diversification. These outcomes show that (i) adaptive landscapes can differ in how they constrain stochastic diversification of a latent phenotype and (ii) major effects of selection on biological diversification can be missed by focusing on trait means. Collectively, our findings suggest that latent-phenotype evolution should inform host–parasite evolution theory and that diversification should be conceived broadly to include latent phenotypes.

Download Full-text