Heritable, Heterogeneous, and Costly Resistance of Sheep against Nematodes and Potential Feedbacks to Epidemiological Dynamics

Infected hosts may preserve fitness by resisting parasites (reducing parasite burden) and/or tolerating them (preventing or repairing infection-induced damage). Theory predicts that these individual-level defense strategies generate divergent population-level feedbacks that would maintain genetic he...

Full description

Saved in:
Bibliographic Details
Published in:The American naturalist 2014-08, Vol.184 (S1), p.S58-S76
Main Authors: Hayward, Adam D., Garnier, Romain, Watt, Kathryn A., Pilkington, Jill G., Grenfell, Bryan T., Matthews, Jacqueline B., Pemberton, Josephine M., Nussey, Daniel H., Graham, Andrea L.
Format: Article
Language:English
Subjects:
Age
Animal populations
Animals
Antibodies
Body weight
Eggs
Epidemiology
Gastrointestinal Diseases - parasitology
Genetic Variation
Genetics
Host-Parasite Interactions
Nematoda
Nematode eggs
Nematode Infections - immunology
Nematode Infections - parasitology
Nematodes
Parasite hosts
Parasite Load
Parasites
Phenotype
Sheep
Sheep - genetics
Sheep - parasitology
Sheep Diseases
Sheep, Domestic - genetics
Sheep, Domestic - parasitology
Statistical variance
Symposium
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Infected hosts may preserve fitness by resisting parasites (reducing parasite burden) and/or tolerating them (preventing or repairing infection-induced damage). Theory predicts that these individual-level defense strategies generate divergent population-level feedbacks that would maintain genetic heterogeneity for resistance but purge heterogeneity for tolerance. Because resistance reduces parasite abundance, selection for costly resistance traits will weaken as resistance becomes common. Such negative frequency-dependent selection contrasts with predictions for tolerance, which maintains parasite abundance and so is expected to generate positive frequency-dependent selection, unless, for example, tolerance trades off with resistance. Thus far, there have been few tests of this theory in natural systems. Here, we begin testing the predictions in a mammalian field system, using data on individual gastrointestinal nematode burdens, nematode-specific antibody titers (as a resistance metric), the slope of body weight on parasite burden (as a tolerance metric), and fitness from an unmanaged population of Soay sheep. We find that nematode resistance is costly to fitness and underpinned by genetic heterogeneity, and that resistance is independent of tolerance. Drawing upon empirical metrics such as developed here, future work will elucidate how resistance and tolerance feedbacks interact to generate population-scale patterns in the Soay sheep and other field systems.
ISSN:0003-0147
1537-5323
DOI:10.1086/676929