Adaptive immune response and resting metabolism are unaffected by manipulation of flight intensity, but negatively related to each other

Bryła, Amadeusz; Bury, Agata; Niedojadlo, Jowita; Speakman, John R.; Sadowska, Edyta T.; Cichoń, Mariusz; Bauchinger, Ulf

doi:10.1111/jav.02764

Cited by 3 publications

(1 citation statement)

References 63 publications

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“…We acknowledge that we did not directly estimate behavior, availability of resources, energetic demands and infection probability associated with postjuvenile molt and autumn migration. However, such a difference has been established for blackcaps at our study site (Chernetsov, 2002; Zelenova, 2001) and in other species with a similar ecology (Bryła et al, 2021; Emmenegger et al, 2018; Hoye & Buttemer, 2011; Murphy & King, 1992); therefore, we assume the same pattern in our study.…”

Section: Introductionsupporting

confidence: 61%

Total white blood cell counts but not HL ratio changes in the transition from post‐juvenile molt to autumn migration in the first‐year Eurasian blackcap (Sylvia atricapilla)

Demina

Tsvey

2021

J Exp Zool Pt A

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Theoretically, seasonal changes in immune functioning in animals are shaped by the trade‐off between a probability of encountering pathogens and availability of resources. We used leukocyte profile (absolute and relative leukocyte counts) as a simple measure of immune system condition to study how it changes during the transition from postjuvenile molt to autumn migration in a free‐living migratory songbird, the Eurasian blackcap (Sylvia atricapilla). We observed the higher white blood cells (WBC) and lymphocyte counts in molting birds compared to migrating individuals, but we did not find differences in heterophils and ratio of heterophils to lymphocytes (HL ratio). We suppose that the high number of WBC in molting blackcaps could reflect the heightened ability of their immune system to resists infections. The lower WBC counts in migrants compared to molting birds were mostly due to reduced lymphocyte numbers, thus representing in a downregulation of specific immunity. An absence of heterophil differences between molt and migration might indicate that various components of immunity can change relatively independently (or at different pace). Fat scores had no effect on WBC counts and HL ratio. Therefore, we found no strong evidence for a resource—immune functionality trade‐off during transition from postjuvenile molt to autumn migration in immature Eurasian blackcap. This study is an important step in understanding how immune system in general and leukocyte profile in particular changes in transition between life‐history stages in migratory songbirds.

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Section: Introductionsupporting

confidence: 61%

Total white blood cell counts but not HL ratio changes in the transition from post‐juvenile molt to autumn migration in the first‐year Eurasian blackcap (Sylvia atricapilla)

Demina

Tsvey

2021

J Exp Zool Pt A

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Measurements of body temperature and oxidative stress reveal differential costs associated with humoral immune function in a passerine bird

Bryła

Zagkle

Sadowska

et al. 2022

Journal of Experimental Biology

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Eco-immunology considers resistance to antigens a costly trait for an organism, but actual quantification of such costs appears not straight forward. Costs of the immune response (IR) are e.g., visible in impaired coloration, reduced growth or reproductive success. Activation of the humoral IR is a slow, complex, and long-lasting process, which makes the quantification of its energetic cost a potential losing game. We implemented near continuous measurements of body temperature in zebra finches (Taeniopygia guttata) as a proxy for the energetic cost with particular interests in the body temperature from activation of the humoral IR until the peak of antibody release several days later. At the peak of the antibody release we additionally measured oxygen consumption (open-flow respirometry) and markers of oxidative stress (dROMs, OXY). Birds with activated IR defended a higher night time body temperature during the first four nights after an immune challenge in comparison to controls, implying increased night time energy use. At the peak of antibody production, we did not find differences in night time body temperature and oxygen consumption but observed a differentiated results for oxygen consumption during day time. Immune challenged females had significantly higher oxygen consumption than other groups. Moreover, we found that activation of the humoral IR increases oxidative damage, a potential cost of defending higher night time body temperature crucial at the early stage of the IR. The costs generated by the immune system appear to consist of two components energetic and non-energetic, and these may appear separated in time.

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