Abstract
The teleost fishes represent over half of all extant vertebrates; they occupy nearly every body of water and in doing so, occupy a diverse array of environmental conditions. We propose that their success is related to a unique oxygen (O2) transport system involving their extremely pH-sensitive haemoglobin (Hb). A reduction in pH reduces both Hb-O2 affinity (Bohr effect) and carrying capacity (Root effect). This, combined with a large arterial-venous pH change (ΔpHa-v) relative to other vertebrates, may greatly enhance tissue oxygen delivery in teleosts (e.g., rainbow trout) during stress, beyond that in mammals (e.g., human). We generated oxygen equilibrium curves (OECs) at five different CO2 tensions for rainbow trout and determined that, when Hb-O2 saturation is 50% or greater, the change in oxygen partial pressure (ΔPO2) associated with ΔpHa-v can exceed that of the mammalian Bohr effect by at least 3-fold, but as much as 21-fold. Using known ΔpHa-v and assuming a constant arterial-venous PO2 difference (Pa-vO2), Root effect Hbs can enhance O2 release to the tissues by 73.5% in trout; whereas, the Bohr effect alone is responsible for enhancing O2 release by only 1.3% in humans. Disequilibrium states are likely operational in teleosts in vivo, and therefore the ΔpHa-v, and thus enhancement of O2 delivery, could be even larger. Modeling with known Pa-vO2 in fish during exercise and hypoxia indicates that O2 release from the Hb and therefore potentially tissue O2 delivery may double during exercise and triple during some levels of hypoxia. These characteristics may be central to performance of athletic fish species such as salmonids, but may indicate that general tissue oxygen delivery may have been the incipient function of Root effect Hbs in fish, a trait strongly associated with the adaptive radiation of teleosts.
Highlights
Haemoglobin (Hb) is one of the most well studied proteins to date and is key to blood oxygen (O2) transport in most vertebrates and some invertebrates, as it increases the total O2 that can be transported in the blood and optimizes tissue O2 delivery
Mean Hb-O2 saturation significantly decreased with pressure of O2 (PO2) and with each increase in CO2 tension, resulting in the characteristic rightward (Bohr effect) and downward (Root effect) shifts in the oxygen equilibrium curves (OECs) (Fig 1A)
Quantitative results confirmed theoretical predictions that–for a given pH change–Root effect Hbs in rainbow trout convey an enormous benefit to blood O2 release and delivery when compared with human blood having a Bohr effect alone
Summary
Haemoglobin (Hb) is one of the most well studied proteins to date and is key to blood oxygen (O2) transport in most vertebrates and some invertebrates, as it increases the total O2 that can be transported in the blood and optimizes tissue O2 delivery. The Bohr effect describes the PLOS ONE | DOI:10.1371/journal.pone.0139477. Enhanced O2 Delivery in Fish vs Other Vertebrates. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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