Oxygen binding affinities and effector sensitivities of hemoglobins of African mole rats inhabiting hypoxic and hypercapnic burrows

Abstract

African mole rats (family Bathyergidae) that excavate and inhabit deep, complex and sealed underground galleries may become subjected to severe hypoxia and hypercapnia (O2 tensions falling below that at the summit of Mount Everest, and CO2 tensions up to 10% of barometric pressure) that predictably impose austere constraints on the exchange and internal transport of respiratory gases. In contrast to high‐altitude mammals, little information is available on possible adaptations in hemoglobin (Hb) function that may mitigate these constraints. Aiming to identify the cellular and molecular mechanisms that safeguard tissue O2 supply in these mole rats, we measured the hematological characteristics as well as Hb‐O2 affinity and it's sensitivity to pH (the Bohr effect), CO2 tension, 2,3‐diphosphoglycerate (DPG, the major organic cofactor modulating Hb‐O2 affinity in mammalian red cells) and to temperature, in six (two strictly‐solitary and four social) species of mole rats originating from a range of Southern African biomes and soil types. The Hbs of the different species showed slight variation in O2 affinity and its sensitivity to pH, DPG and temperature, that did not correlate with soil‐type and sociality, but exhibited conspicuous and variable reductions in specific (pH‐independent) CO2 effects compared to other mammalian Hbs, which may be of adaptive significance in safeguarding pulmonary Hb‐O2 loading in hypercapnic burrows. The observations align with the contention that blood O2‐affinities of burrowing mammals are pre‐adapted to high altitude. Attempts are made to correlate the measured oxygenation traits with available amino acid sequences for mole rat Hbs.