Evolution of heterophil/lymphocyte ratios in response to ecological and life‐history traits: A comparative analysis across the avian tree of life

Minias, Piotr

doi:10.1111/1365-2656.12941

Cited by 62 publications

(51 citation statements)

References 86 publications

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“…There is published evidence that the heterophil:lymphocyte ratio varies between birds and is highly heritable (Campo and Davila, 2002). It also varies greatly amongst chicken breeds (Bilkova et al, 2017) and avian species (Minias, 2019). We did not observe any corresponding changes in circulating myeloid cells in these birds ( Figure 3 ) so this phenomenon appears specific to the spleen.…”

Section: Resultsmentioning

confidence: 99%

Analysis of the Progeny of Sibling Matings Reveals Regulatory Variation Impacting the Transcriptome of Immune Cells in Commercial Chickens

et al. 2019

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There is increasing recognition that the underlying genetic variation contributing to complex traits influences transcriptional regulation and can be detected at a population level as expression quantitative trait loci. At the level of an individual, allelic variation in transcriptional regulation of individual genes can be detected by measuring allele-specific expression in RNAseq data. We reasoned that extreme variants in gene expression could be identified by analysis of inbred progeny with shared grandparents. Commercial chickens have been intensively selected for production traits. Selection is associated with large blocks of linkage disequilibrium with considerable potential for co-selection of closely linked “hitch-hiker alleles” affecting traits unrelated to the feature being selected, such as immune function, with potential impact on the productivity and welfare of the animals. To test this hypothesis that there is extreme allelic variation in immune-associated genes we sequenced a founder population of commercial broiler and layer birds. These birds clearly segregated genetically based upon breed type. Each genome contained numerous candidate null mutations, protein-coding variants predicted to be deleterious and extensive non-coding polymorphism. We mated selected broiler-layer pairs then generated cohorts of F2 birds by sibling mating of the F1 generation. Despite the predicted prevalence of deleterious coding variation in the genomic sequence of the founders, clear detrimental impacts of inbreeding on survival and post-hatch development were detected in only one F2 sibship of 15. There was no effect on circulating leukocyte populations in hatchlings. In selected F2 sibships we performed RNAseq analysis of the spleen and isolated bone marrow-derived macrophages (with and without lipopolysaccharide stimulation). The results confirm the predicted emergence of very large differences in expression of individual genes and sets of genes. Network analysis of the results identified clusters of co-expressed genes that vary between individuals and suggested the existence of trans-acting variation in the expression in macrophages of the interferon response factor family that distinguishes the parental broiler and layer birds and influences the global response to lipopolysaccharide. This study shows that the impact of inbreeding on immune cell gene expression can be substantial at the transcriptional level, and potentially opens a route to accelerate selection using specific alleles known to be associated with desirable expression levels.

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Section: Resultsmentioning

confidence: 99%

Analysis of the Progeny of Sibling Matings Reveals Regulatory Variation Impacting the Transcriptome of Immune Cells in Commercial Chickens

et al. 2019

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“…Our second modelling exercise focused on whether lifehistory traits (maximal lifespan, maximal reproductive capacity and the interaction of both terms with body mass) explained more variation in leucocyte concentrations in birds than body mass, after accounting for phylogeny. We expected body mass to explain more variation in all three cell types than either life-history variable, but that phylogeny would also be a strong predictor as observed previously [19,[32][33][34]. We also expected the relative importance of body mass, life-history traits and phylogeny to vary among cell types because of the different defensive functions of each cell type.…”

Section: Introductionmentioning

confidence: 83%

The impacts of body mass on immune cell concentrations in birds

2020

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Body mass affects many biological traits, but its impacts on immune defences are fairly unknown. Recent research on mammals found that neutrophil concentrations disproportionately increased (scaled hypermetrically) with body mass, a result not predicted by any existing theory. Although the scaling relationship for mammals might predict how leucocyte concentrations scale with body mass in other vertebrates, vertebrate classes are distinct in many ways that might affect their current and historic interactions with parasites and hence the evolution of their immune systems. Subsequently, here, we asked which existing scaling hypothesis best-predicts relationships between body mass and lymphocyte, eosinophil and heterophil concentrations—the avian functional equivalent of neutrophils—among more than 100 species of birds. We then examined the predictive power of body mass relative to life-history variation, as extensive literature indicates that the timing of key life events has influenced immune system variation among species. Finally, we ask whether avian scaling patterns differ from the patterns we observed in mammals. We found that an intercept-only model best explained lymphocyte and eosinophil concentrations among birds, indicating that the concentrations of these cell types were both independent of body mass. For heterophils, however, body mass explained 31% of the variation in concentrations among species, much more than life-history variation (4%). As with mammalian neutrophils, avian heterophils scaled hypermetrically ( b = 0.19 ± 0.05), but more steeply than mammals (approx. 1.5 ×; 0.11 ± 0.03). As such, we discuss why birds might require more broadly protective cells compared to mammals of the same body size. Overall, body mass appears to have strong influences on the architecture of immune systems.

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“…The weak phylogenetic signal and a small percentage of variation in antibacterial curves explained by phylogeny in general were surprising. Previous analyses of scaling of leucocyte concentrations and in mammals (Downs et al 2020) and birds (Ruhs et al 2020) and leucocyte ratios in birds (Minias 2019) demonstrated that phylogeny explained the majority of interspecific variation.…”

Section: Phylogenetic Signal and Other Influences On Antibacterial Capacitymentioning

confidence: 99%

Large Mammals Have More Powerful Antibacterial Defenses Than Expected from Their Metabolic Rates

Downs

Schoenle

Goolsby

et al. 2020

Preprint

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Terrestrial mammals span 7 orders of magnitude in body size, ranging from the < 2 g pygmy shrew (Suncus etruscus) to the > 3900 kg African elephant (Loxodonta africana). Although body size has profound effects on the behavior, physiology, ecology, and evolution of animals, how body mass affects immune functions is unknown. Here, using data from >160 terrestrial species of mammals, we show that the size-scaling of antibacterial activity in serum exhibits extreme hyperallometry. Compared to small mammals, the serum of large mammals is remarkably inhospitable to bacteria. Such hypermetric scaling of immune defenses provides novel perspectives on the ecology of host-pathogen interactions, and on their co-evolutionary dynamics. These results also have implications for effectively modeling human immunity and for identifying reservoirs of zoonotic pathogens.

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Evolution of heterophil/lymphocyte ratios in response to ecological and life‐history traits: A comparative analysis across the avian tree of life

Cited by 62 publications

References 86 publications

Analysis of the Progeny of Sibling Matings Reveals Regulatory Variation Impacting the Transcriptome of Immune Cells in Commercial Chickens

Analysis of the Progeny of Sibling Matings Reveals Regulatory Variation Impacting the Transcriptome of Immune Cells in Commercial Chickens

The impacts of body mass on immune cell concentrations in birds

Large Mammals Have More Powerful Antibacterial Defenses Than Expected from Their Metabolic Rates

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