Costs and Benefits of Experimentally Induced Changes in the Allocation of Growth versus Immune Function under Differential Exposure to Ectoparasites

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RESEARCH PRODUCT

Costs and Benefits of Experimentally Induced Changes in the Allocation of Growth versus Immune Function under Differential Exposure to Ectoparasites

Lars Gustafsson Natalia Pitala Heli Siitari Jon E. Brommer

subject

0106 biological sciences lcsh:Medicine Evolutionary Biology/Developmental Evolution Weight Gain 01 natural sciences Nesting Behavior chemistry.chemical_compound EVOLUTIONARY ECOLOGY Methionine NESTLING GREAT TITS Passeriformes Ceratophyllus gallinae lcsh:Science 0303 health sciences Multidisciplinary biology Fledge Cyanistes CELL-MEDIATED-IMMUNITY TRADE-OFFS FICEDULA-HYPOLEUCA SULFUR AMINO-ACIDS DELICHON-URBICA Siphonaptera Female Immunocompetence medicine.symptom Research Article education Zoology Evolutionary Biology/Evolutionary Ecology 010603 evolutionary biology Host-Parasite Interactions 03 medical and health sciences Immune system Immunity Ecology/Evolutionary Ecology GLUTATHIONE DEPLETION medicine Animals Parasites 030304 developmental biology Methionine lcsh:R CERATOPHYLLUS-GALLINAE LOCAL RECRUITMENT biology.organism_classification Survival Analysis chemistry Immunology Dietary Supplements lcsh:Q 118 Biological sciences Weight gain

description

Background Ecological immunology has focused on the costs of investment in immunocompetence. However, understanding optimal resource allocation to immune defence requires also identification of its benefits, which are likely to occur only when parasites are abundant. Methodology We manipulated the abundance of parasitic hen fleas in blue tit (Cyanistes caeruleus) nests, and supplemented their hosts, the nestlings, with methionine (a sulphur amino acid enhancing cell-mediated immunity) during day 3–6. We found a significant interaction between these two experimental factors on the development of immune defences and growth rates. Only in parasitized nests did methionine supplementation boost immune (PHA) response, and did nestling with experimentally increased immunocompetence show a relatively faster growth rate than control nestlings between days 6–9. Hence, the allocation of resources into immune defence and its growth-benefits are apparent only in presence of parasites. The main cost of methionine-induced increased allocation to the immune system was an increase in mortality, independently of ectoparasites. Nestlings in all treatments compensated initial growth reduction and all reached equal body size at day 16 (just prior to fledging), indicating a lack of long-term benefits. In addition, methionine treatment tended (P = 0.09) to lower circulating plasma immunoglobulin levels, possibly indicating a trade-off between the cell-mediated and humoral components of the immune system. Conclusions We found no strong benefits of an increased investment in immunocompetence in a parasite-rich environment. Any deviation from the growth trajectory (due to changes in allocation induced by methionine) is largely detrimental for survival. Hence, while costs are apparent identifying the benefits of investment in immunocompetence during ontogeny is challenging.

year	journal	country	edition	language
2010-05-01

10.1371/journal.pone.0010814 http://hdl.handle.net/10138/165605