Energetic Lifestyle Drives Size and Shape of Avian Erythrocytes.

Carl D Soulsbury,Jessica Dobson,Piotr Minias,D Charles Deeming

doi:10.1093/icb/icab195

Carl D Soulsbury, Jessica Dobson + Show 2 more

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https://doi.org/10.1093/icb/icab195

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Journal: American Zoologist	Publication Date: Sep 28, 2021
Citations: 7	License type: CC BY 4.0

Affiliation: University of Lincoln, University of Łódź

Abstract

The size and shape of red blood cells (erythrocytes) is determined by key life history strategies in vertebrates. They have a fundamental role to deliver oxygen to tissues, and their ability to do so is shaped by the tissue's need and their shape. Despite considerable interest in how other components of blood are shaped by ecology and life history, few studies have considered erythrocytes themselves. We tested how erythrocyte size and shape varied in relation to energetically demanding activities using a dataset of 631 bird species. We found that in general, birds undergoing greater activities such as long distance migration had smaller and more elongated cells, while those with greater male-male competition had smaller and rounder cells. Smaller, more elongated erythrocytes allow more rapid oxygenation/deoxygenation and support greater aerobic activity. The rounder erythrocytes found in species with strong male–male competition may stem from younger erythrocytes deriving from androgen-induced erythropoiesis rates. Finally, diving species of bird had larger erythrocytes, indicating that erythrocytes are acting as a vital oxygen store. In summary, erythrocyte size and shape in birds are driven by the need to deliver oxygen during energetically costly activities.

Highlights

Blood oxygen-carrying capacity is one of the major determinants of the amount of oxygen delivered to tissue per unit of time, and has a critical role in shaping oxidative metabolism (Minias 2020)
We focussed on erythrocyte area, rather than mean corpuscular volume, which is usually derived by multiplying a volume of blood by the proportion of blood that is cellular, and dividing that product by the number of erythrocytes in that volume
We found no effect of mating system on erythrocyte size (Table 2), but species with larger relative testes sizes had smaller erythrocytes (Table 2; Fig. 4A)

Summary

Introduction

Blood oxygen-carrying capacity is one of the major determinants of the amount of oxygen delivered to tissue per unit of time, and has a critical role in shaping oxidative metabolism (Minias 2020). Blood oxygen-carrying capacity is often measured as total hemoglobin (Hb) concentration in blood and hamatocrit (Hct). Across species there is strong evidence that both Hct and Hb are adapted to a range of differing life history strategies, such a migratory strategy, altitude, and metabolic rate (Minias et al 2013; Yap et al 2019; Minias, 2020). In combination, these examples highlight the critical role behaviors and life history have in shaping blood oxygen-carrying capacity. While Hb and Hct are by far the most widely studied measures of blood oxygen-carrying capacity, a number of other components of blood oxygen-carrying capacity, such as erythrocyte size and shape, are important and major targets of selection

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