Data from: The effects of body mass on immune cell concentrations of mammals

Theory predicts that body mass should affect the way organisms evolve and use immune defenses. We investigated the relationship between body mass and blood neutrophil and lymphocyte concentrations among 250+ terrestrial mammalian species. We tested whether existing theories (e.g., Protecton Theory,...

Full description

Bibliographic Details
Main Authors: Downs, Cynthia J., Dochtermann, Ned A., Ball, Ray, Klasing, Kirk C., Martin, Lynn B.
Format: Other/Unknown Material
Language:unknown
Published: Zenodo 2020
Subjects:
Macropus robustus
Nanger granti
Eulemur macaco
Odocoileus hemionus
Panthera onca
Oreotragus oreotragus
Cephalophus silvicultor
Rousettus aegyptiacus
Axis porcinus
Helarctos malayanus
Trichechus manatus
Budorcas taxicolor
Neofelis nebulosa
Varecia variegata
Phoca vitulina
Martes pennanti
Nasua nasua
Canis latrans
Ursus thibetanus
Hylobates lar
Dendrolagus matschiei
Phacochoerus africanus
Perodicticus potto
Eulemur coronatus
Potos flavus
Bassariscus sumichrasti
Aonyx cinerea
Canis mesomelas
Gazella dorcas
Connochaetes taurinus
Pteropus rodricensis
Rucervus eldii
Chinchilla lanigera
Petrogale xanthopus
Crocuta crocuta
Melursus ursinus
Saguinus midas
Helogale parvula
Boselaphus tragocamelus
Cephalophus rufilatus
Bubalus depressicornis
Vulpes velox
Dicerorhinus sumatrensis
Callosciurus prevostii
Cephalophus niger
Choloepus hoffmanni
Lagenorhynchus obliquidens
Pedetes capensis
Immunity: ecology
Pecari tajacu
Online Access:https://doi.org/10.5061/dryad.q4n4884
Description
Summary:Theory predicts that body mass should affect the way organisms evolve and use immune defenses. We investigated the relationship between body mass and blood neutrophil and lymphocyte concentrations among 250+ terrestrial mammalian species. We tested whether existing theories (e.g., Protecton Theory, immune system complexity, and rate of metabolism) accurately predicted the scaling of immune cell concentrations. We also evaluated the predictive power of body mass for these leukocyte concentrations compared to sociality, diet, life history, and phylogenetic relatedness. Phylogeny explained >65% of variation in both lymphocytes and neutrophils, and body mass appeared more informative than other interspecific trait variation. In the best-fit mass-only model, neutrophils scaled hypermetrically (b = 0.11) with body mass whereas lymphocytes scaled isometrically. Extrapolating to total cell numbers, this exponent means that an African elephant circulates 13.3 million times the neutrophils of a house mouse, whereas their masses differ by only 250k-fold. We hypothesize that such high neutrophil numbers might offset the i) higher overall parasite exposure that large animals face and/or ii) the higher relative replication capacities of pathogens to host cells. Life history and ecological data for mammals Life history and ecological data for mammals used in "The effects of body mass on immune cell concentrations of terrestrial mammals." Data include body mass (log-transformed), maximal longevity (log-transformed), maximal reproductive potential (log-transformed), trophic level, and sociality. DownsEtAl_AmNat_ScalingNL_DataDryad.csv R code for statistics used in "The effects of body mass on immune cell concentrations of mammals" R code for statistics used in The effects of body mass on immune cell concentrations of mammals by Downs et al. DownsEtAl_AmNat_ScalingNL_ScalingCode_dryad.r Funding provided by: National Science Foundation Crossref Funder Registry ID: http://dx.doi.org/10.13039/100000001 Award Number: ...

Similar Items