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1. Coordinated changes across the O ₂ transport pathway underlie adaptive increases in thermogenic capacity in high-altitude deer mice

   https://doi.org/10.1098/rspb.2019.2750  

   Tate, Kevin B.; Wearing, Oliver H.; Ivy, Catherine M.; Cheviron, Zachary A.; Storz, Jay F.; McClelland, Grant B.; Scott, Graham R. (May 2020, Proceedings of the Royal Society B: Biological Sciences)

   null (Ed.)

   Animals native to the hypoxic and cold environment at high altitude provide an excellent opportunity to elucidate the integrative mechanisms underlying the adaptive evolution and plasticity of complex traits. The capacity for aerobic thermogenesis can be a critical determinant of survival for small mammals at high altitude, but the physiological mechanisms underlying the evolution of this performance trait remain unresolved. We examined this issue by comparing high-altitude deer mice ( Peromyscus maniculatus ) with low-altitude deer mice and white-footed mice ( P. leucopus ). Mice were bred in captivity and adults were acclimated to each of four treatments: warm (25°C) normoxia, warm hypoxia (12 kPa O 2 ), cold (5°C) normoxia or cold hypoxia. Acclimation to hypoxia and/or cold increased thermogenic capacity in deer mice, but hypoxia acclimation led to much greater increases in thermogenic capacity in highlanders than in lowlanders. The high thermogenic capacity of highlanders was associated with increases in pulmonary O 2 extraction, arterial O 2 saturation, cardiac output and arterial–venous O 2 difference. Mechanisms underlying the evolution of enhanced thermogenic capacity in highlanders were partially distinct from those underlying the ancestral acclimation responses of lowlanders. Environmental adaptation has thus enhanced phenotypic plasticity and expanded the physiological toolkit for coping with the challenges at high altitude. 

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2. Genetic variation in haemoglobin is associated with evolved changes in breathing in high-altitude deer mice

   https://doi.org/10.1242/jeb.243595  

   Ivy, Catherine M.; Wearing, Oliver H.; Natarajan, Chandrasekhar; Schweizer, Rena M.; Gutiérrez-Pinto, Natalia; Velotta, Jonathan P.; Campbell-Staton, Shane C.; Petersen, Elin E.; Fago, Angela; Cheviron, Zachary A.; et al (January 2022, Journal of Experimental Biology)

   ABSTRACT Physiological systems often have emergent properties but the effects of genetic variation on physiology are often unknown, which presents a major challenge to understanding the mechanisms of phenotypic evolution. We investigated whether genetic variants in haemoglobin (Hb) that contribute to high-altitude adaptation in deer mice (Peromyscus maniculatus) are associated with evolved changes in the control of breathing. We created F2 inter-population hybrids of highland and lowland deer mice to test for phenotypic associations of α- and β-globin variants on a mixed genetic background. Hb genotype had expected effects on Hb–O2 affinity that were associated with differences in arterial O2 saturation in hypoxia. However, high-altitude genotypes were also associated with breathing phenotypes that should contribute to enhancing O2 uptake in hypoxia. Mice with highland α-globin exhibited a more effective breathing pattern, with highland homozygotes breathing deeper but less frequently across a range of inspired O2, and this difference was comparable to the evolved changes in breathing pattern in deer mouse populations native to high altitude. The ventilatory response to hypoxia was augmented in mice that were homozygous for highland β-globin. The association of globin variants with variation in breathing phenotypes could not be recapitulated by acute manipulation of Hb–O2 affinity, because treatment with efaproxiral (a synthetic drug that acutely reduces Hb–O2 affinity) had no effect on breathing in normoxia or hypoxia. Therefore, adaptive variation in Hb may have unexpected effects on physiology in addition to the canonical function of this protein in circulatory O2 transport. 

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3. Evolved increases in hemoglobin-oxygen affinity and the Bohr effect coincided with the aquatic specialization of penguins

   https://doi.org/10.1073/pnas.2023936118  

   Signore, Anthony V.; Tift, Michael S.; Hoffmann, Federico G.; Schmitt, Todd. L.; Moriyama, Hideaki; Storz, Jay F. (March 2021, Proceedings of the National Academy of Sciences)

   null (Ed.)

   Dive capacities of air-breathing vertebrates are dictated by onboard O 2 stores, suggesting that physiologic specialization of diving birds such as penguins may have involved adaptive changes in convective O 2 transport. It has been hypothesized that increased hemoglobin (Hb)-O 2 affinity improves pulmonary O 2 extraction and enhances the capacity for breath-hold diving. To investigate evolved changes in Hb function associated with the aquatic specialization of penguins, we integrated comparative measurements of whole-blood and purified native Hb with protein engineering experiments based on site-directed mutagenesis. We reconstructed and resurrected ancestral Hb representing the common ancestor of penguins and the more ancient ancestor shared by penguins and their closest nondiving relatives (order Procellariiformes, which includes albatrosses, shearwaters, petrels, and storm petrels). These two ancestors bracket the phylogenetic interval in which penguin-specific changes in Hb function would have evolved. The experiments revealed that penguins evolved a derived increase in Hb-O 2 affinity and a greatly augmented Bohr effect (i.e., reduced Hb-O 2 affinity at low pH). Although an increased Hb-O 2 affinity reduces the gradient for O 2 diffusion from systemic capillaries to metabolizing cells, this can be compensated by a concomitant enhancement of the Bohr effect, thereby promoting O 2 unloading in acidified tissues. We suggest that the evolved increase in Hb-O 2 affinity in combination with the augmented Bohr effect maximizes both O 2 extraction from the lungs and O 2 unloading from the blood, allowing penguins to fully utilize their onboard O 2 stores and maximize underwater foraging time. 

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4. Adrenergically induced translocation of red blood cell β-adrenergic sodium-proton exchangers has ecological relevance for hypoxic and hypercapnic white seabass

   https://doi.org/10.1152/ajpregu.00175.2021  

   Harter, Till S.; Clifford, Alexander M.; Tresguerres, Martin (November 2021, American Journal of Physiology-Regulatory, Integrative and Comparative Physiology)

   White seabass ( Atractoscion nobilis) increasingly experience periods of low oxygen (O 2 ; hypoxia) and high carbon dioxide (CO 2 , hypercapnia) due to climate change and eutrophication of the coastal waters of California. Hemoglobin (Hb) is the principal O 2 carrier in the blood and in many teleost fishes Hb-O 2 binding is compromised at low pH; however, the red blood cells (RBC) of some species regulate intracellular pH with adrenergically stimulated sodium-proton-exchangers (β-NHEs). We hypothesized that RBC β-NHEs in white seabass are an important mechanism that can protect the blood O 2 -carrying capacity during hypoxia and hypercapnia. We determined the O 2 -binding characteristics of white seabass blood, the cellular and subcellular response of RBCs to adrenergic stimulation, and quantified the protective effect of β-NHE activity on Hb-O 2 saturation. White seabass had typical teleost Hb characteristics, with a moderate O 2 affinity (Po 2 at half-saturation; P 50 2.9 kPa) that was highly pH-sensitive (Bohr coefficient −0.92; Root effect 52%). Novel findings from super-resolution microscopy revealed β-NHE protein in vesicle-like structures and its translocation into the membrane after adrenergic stimulation. Microscopy data were corroborated by molecular and phylogenetic results and a functional characterization of β-NHE activity. The activation of RBC β-NHEs increased Hb-O 2 saturation by ∼8% in normoxic hypercapnia and by up to ∼20% in hypoxic normocapnia. Our results provide novel insight into the cellular mechanism of adrenergic RBC stimulation within an ecologically relevant context. β-NHE activity in white seabass has great potential to protect arterial O 2 transport during hypoxia and hypercapnia but is less effective during combinations of these stressors. 

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5. To what extent do physiological tolerances determine elevational range limits of mammals?

   https://doi.org/10.1113/JP284586  

   Storz, Jay F; Scott, Graham R (October 2023, The Journal of Physiology)

   Abstract A key question in biology concerns the extent to which distributional range limits of species are determined by intrinsic limits of physiological tolerance. Here, we use common‐garden data for wild rodents to assess whether species with higher elevational range limits typically have higher thermogenic capacities in comparison to closely related lowland species. Among South American leaf‐eared mice (genusPhyllotis), mean thermogenic performance is higher in species with higher elevational range limits, but there is little among‐species variation in the magnitude of plasticity in this trait. In the North American rodent genusPeromyscus, highland deer mice (Peromyscus maniculatus) have greater thermogenic maximal oxygen uptake () than lowland white‐footed mice (Peromyscus leucopus) at a level of hypoxia that matches the upper elevational range limit of the former species. In highland deer mice, the enhanced thermogenic in hypoxia is attributable to a combination of evolved and plastic changes in physiological pathways that govern the transport and utilization of O₂and metabolic substrates. Experiments withPeromyscusmice also demonstrate that exposure to hypoxia during different stages of development elicits plastic changes in cardiorespiratory traits that improve thermogenic via distinct physiological mechanisms. Evolved differences in thermogenic capacity provide clues about why some species are able to persist in higher‐elevation habitats that lie slightly beyond the tolerable limits of other species. Such differences in environmental tolerance also suggest why some species might be more vulnerable to climate change than others.image 

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