{"title":"将高海拔适应性鹿小鼠的红细胞功能表型与环境耐受性联系起来","authors":"Till Harter, Graham R Scott","doi":"10.1152/physiol.2024.39.s1.649","DOIUrl":null,"url":null,"abstract":"Oxygen (O2) is essential for vertebrate life, and complex cardio-respiratory systems have evolved to transport the gas from the environment to each individual cell. Even short disruptions of this O2 flux can have deleterious effects that are linked to numerous disease states. Animals that have adapted to hypoxic environments, such as deer mice ( Peromyscus maniculatus) native to high altitude, can provide valuable insight into naturally evolved solutions to O2 deprivation. Previous work has shown that high-altitude deer mice have evolved a higher hemoglobin O2 affnity and other coordinated changes across the O2 transport cascade that enable higher metabolic rates in hypoxia. Red blood cells (RBC) are the functional unit of O2 and carbon dioxide transport in the blood and play central roles in matching O2 supply and demand in the microcirculation by releasing signaling molecules such as ATP and gasotransmitters; but how these cellular mechanisms respond to hypoxic environments has not been studied. We hypothesized that high-altitude adaptation in deer mice has improved the function of RBCs for cardiovascular gas transport in hypoxia. Lab-raised breeding colonies of deer-mice were established from wild mice caught at low altitude (~400 m in the Great Plains of Nebraska) and at high altitude (~4300 m in the Rocky Mountains of Colorado). Using a common-garden experimental design, third-generation deer mice from high- and low-altitude populations were acclimated to warm normoxia (21°C, 21 kPa O2) or cold hypobaric hypoxia (5°C, 12 kPa O2) for 8 weeks. Blood samples were collected for measurements of hematocrit, hemoglobin concentration, RBC volume, plasma erythropoietin concentration, RBC contents of membrane transport and channel proteins (anion exchanger, aquaporin 1 and rhesus associated glycoprotein) by immunocytochemistry and western blotting, and carbonic anhydrase activity using biochemical techniques. The release of ATP from RBCs was measured in tonometers at decreasing levels of O2 by luminometry, and the vascular sensitivity to ATP was determined by wire myography on second-order mesenteric arteries. Finally, bone marrow samples were collected from the femurs to measure gene expression levels in the erythropoietic tissue. Our experimental design allowed us to examine the interactive effects of cold hypoxic environments on RBC phenotype, by untangling environmentally-induced plasticity from the signatures of adaptation that are unique to high-altitude natives. This work is providing a better understanding of how RBC function participates in matching cardiovascular O2 supply and demand in extreme hypoxia, which has important applications in animal and human health. This work was supported by a NSERC Canada Banting Postdoctoral Fellowship to TSH and a Discovery Grant to GRS. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. 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Animals that have adapted to hypoxic environments, such as deer mice ( Peromyscus maniculatus) native to high altitude, can provide valuable insight into naturally evolved solutions to O2 deprivation. Previous work has shown that high-altitude deer mice have evolved a higher hemoglobin O2 affnity and other coordinated changes across the O2 transport cascade that enable higher metabolic rates in hypoxia. Red blood cells (RBC) are the functional unit of O2 and carbon dioxide transport in the blood and play central roles in matching O2 supply and demand in the microcirculation by releasing signaling molecules such as ATP and gasotransmitters; but how these cellular mechanisms respond to hypoxic environments has not been studied. We hypothesized that high-altitude adaptation in deer mice has improved the function of RBCs for cardiovascular gas transport in hypoxia. Lab-raised breeding colonies of deer-mice were established from wild mice caught at low altitude (~400 m in the Great Plains of Nebraska) and at high altitude (~4300 m in the Rocky Mountains of Colorado). Using a common-garden experimental design, third-generation deer mice from high- and low-altitude populations were acclimated to warm normoxia (21°C, 21 kPa O2) or cold hypobaric hypoxia (5°C, 12 kPa O2) for 8 weeks. Blood samples were collected for measurements of hematocrit, hemoglobin concentration, RBC volume, plasma erythropoietin concentration, RBC contents of membrane transport and channel proteins (anion exchanger, aquaporin 1 and rhesus associated glycoprotein) by immunocytochemistry and western blotting, and carbonic anhydrase activity using biochemical techniques. The release of ATP from RBCs was measured in tonometers at decreasing levels of O2 by luminometry, and the vascular sensitivity to ATP was determined by wire myography on second-order mesenteric arteries. 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引用次数: 0
摘要
氧气(O2)是脊椎动物生命所必需的,复杂的心肺系统就是为了把这种气体从环境中输送到每个细胞而进化的。即使是短暂的氧气输送中断也会产生有害影响,并与多种疾病相关。适应缺氧环境的动物,如原产于高海拔地区的鹿小鼠(Peromyscus maniculatus),可以为自然进化的氧气匮乏解决方案提供宝贵的见解。先前的研究表明,高海拔地区的鹿小鼠进化出了更高的血红蛋白氧气亲和力以及氧气运输级联的其他协调变化,从而能够在缺氧条件下实现更高的新陈代谢率。红细胞(RBC)是血液中氧气和二氧化碳运输的功能单位,并通过释放 ATP 和气体递质等信号分子,在微循环中匹配氧气供需方面发挥着核心作用;但这些细胞机制如何应对缺氧环境尚未得到研究。我们假设,鹿小鼠对高海拔的适应改善了红细胞在缺氧环境下心血管气体运输的功能。我们利用在低海拔地区(内布拉斯加大平原约 400 米)和高海拔地区(科罗拉多落基山脉约 4300 米)捕获的野生小鹿建立了实验室饲养的鹿鼠繁殖群。采用共同花园实验设计,将来自高海拔和低海拔种群的第三代鹿小鼠在温暖的常氧环境(21°C,21 kPa O2)或寒冷的低压缺氧环境(5°C,12 kPa O2)中适应 8 周。采集血样用于测量血细胞比容、血红蛋白浓度、红细胞体积、血浆促红细胞生成素浓度、红细胞膜运输和通道蛋白(阴离子交换蛋白、水蒸发蛋白 1 和恒河猴相关糖蛋白)含量(免疫细胞化学和 Western 印迹)以及碳酸酐酶活性(生化技术)。在气压计中,通过荧光测定法测量红细胞在氧气浓度降低时释放出的 ATP,并通过二阶肠系膜动脉的线性肌电图测定血管对 ATP 的敏感性。最后,我们从股骨中采集了骨髓样本,以测量红细胞组织中的基因表达水平。我们的实验设计使我们能够研究低温缺氧环境对红细胞表型的交互影响,将环境诱导的可塑性与高海拔当地人特有的适应特征区分开来。这项工作让我们更好地了解了在极度缺氧的情况下,红细胞功能是如何参与匹配心血管氧气供需的,这在动物和人类健康中具有重要的应用价值。这项工作得到了加拿大国家科学研究中心班廷博士后奖学金(NSERC Canada Banting Postdoctoral Fellowship)和发现基金(Discovery Grant)的支持。本文是在 2024 年美国生理学峰会上发表的摘要全文,只有 HTML 格式。本摘要没有附加版本或附加内容。生理学》未参与同行评审过程。
Linking red blood cell functional phenotypes to environmental tolerance in high-altitude adapted deer mice
Oxygen (O2) is essential for vertebrate life, and complex cardio-respiratory systems have evolved to transport the gas from the environment to each individual cell. Even short disruptions of this O2 flux can have deleterious effects that are linked to numerous disease states. Animals that have adapted to hypoxic environments, such as deer mice ( Peromyscus maniculatus) native to high altitude, can provide valuable insight into naturally evolved solutions to O2 deprivation. Previous work has shown that high-altitude deer mice have evolved a higher hemoglobin O2 affnity and other coordinated changes across the O2 transport cascade that enable higher metabolic rates in hypoxia. Red blood cells (RBC) are the functional unit of O2 and carbon dioxide transport in the blood and play central roles in matching O2 supply and demand in the microcirculation by releasing signaling molecules such as ATP and gasotransmitters; but how these cellular mechanisms respond to hypoxic environments has not been studied. We hypothesized that high-altitude adaptation in deer mice has improved the function of RBCs for cardiovascular gas transport in hypoxia. Lab-raised breeding colonies of deer-mice were established from wild mice caught at low altitude (~400 m in the Great Plains of Nebraska) and at high altitude (~4300 m in the Rocky Mountains of Colorado). Using a common-garden experimental design, third-generation deer mice from high- and low-altitude populations were acclimated to warm normoxia (21°C, 21 kPa O2) or cold hypobaric hypoxia (5°C, 12 kPa O2) for 8 weeks. Blood samples were collected for measurements of hematocrit, hemoglobin concentration, RBC volume, plasma erythropoietin concentration, RBC contents of membrane transport and channel proteins (anion exchanger, aquaporin 1 and rhesus associated glycoprotein) by immunocytochemistry and western blotting, and carbonic anhydrase activity using biochemical techniques. The release of ATP from RBCs was measured in tonometers at decreasing levels of O2 by luminometry, and the vascular sensitivity to ATP was determined by wire myography on second-order mesenteric arteries. Finally, bone marrow samples were collected from the femurs to measure gene expression levels in the erythropoietic tissue. Our experimental design allowed us to examine the interactive effects of cold hypoxic environments on RBC phenotype, by untangling environmentally-induced plasticity from the signatures of adaptation that are unique to high-altitude natives. This work is providing a better understanding of how RBC function participates in matching cardiovascular O2 supply and demand in extreme hypoxia, which has important applications in animal and human health. This work was supported by a NSERC Canada Banting Postdoctoral Fellowship to TSH and a Discovery Grant to GRS. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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