Department of Biology, Lund University, Lund, Sweden.
Station d'Ecologie Théorique et Expérimentale du CNRS à Moulis, Moulis, France.
J Exp Zool A Ecol Integr Physiol. 2017 Aug;327(7):423-432. doi: 10.1002/jez.2115. Epub 2017 Oct 17.
Coping with novel environments may be facilitated by plastic physiological responses that enable survival during environmentally sensitive life stages. We tested the capacity for embryos of the common wall lizard (Podarcis muralis) from low altitude to cope with low-oxygen partial pressure (hypoxia) in an alpine environment. Developing embryos subjected to hypoxic atmospheric conditions (15-16% O sea-level equivalent) at 2,877 m above sea level exhibited responses common to vertebrates acclimatized to or evolutionarily adapted to high altitude: suppressed metabolism, cardiac hypertrophy, and hyperventilation. These responses might have contributed to the unaltered incubation duration and hatching success relative to the ancestral, low-altitude, condition. Even so, hypoxia constrained egg energy utilization such that larger eggs produced hatchlings with relatively low mass. These findings highlight the role of physiological plasticity in maintaining fitness-relevant phenotypes in high-altitude environments, providing impetus to further explore altitudinal limits to ecological diversification in ectothermic vertebrates.
应对新环境可能得益于能够在环境敏感生命阶段维持生存的生理可塑性反应。我们测试了来自低海拔地区的普通壁蜥(Podarcis muralis)胚胎在高原环境中应对低氧分压(缺氧)的能力。在海拔 2877 米处,处于缺氧大气条件(相当于海平面 15-16%的 O2)下的发育中的胚胎表现出与适应或进化适应高海拔的脊椎动物常见的反应:代谢抑制、心脏肥大和过度通气。这些反应可能有助于保持孵化时间和孵化成功率不变,与祖先的低海拔条件相比。即便如此,缺氧限制了卵的能量利用,导致较大的卵孵化出的幼体质量相对较低。这些发现强调了生理可塑性在维持高海拔环境中与适应度相关表型中的作用,为进一步探索变温脊椎动物的海拔生态多样化极限提供了动力。
