Department of Biological Sciences, University of North Texas, Denton, TX 76203, USA.
Am J Physiol Regul Integr Comp Physiol. 2013 Jun 1;304(11):R966-79. doi: 10.1152/ajpregu.00595.2012. Epub 2013 Apr 3.
Reptile embryos tolerate large decreases in the concentration of ambient oxygen. However, we do not fully understand the mechanisms that underlie embryonic cardiovascular short- or long-term responses to hypoxia in most species. We therefore measured cardiac growth and function in snapping turtle embryos incubated under normoxic (N21; 21% O₂) or chronic hypoxic conditions (H10; 10% O₂). We determined heart rate (fH) and mean arterial pressure (Pm) in acute normoxic (21% O₂) and acute hypoxic (10% O₂) conditions, as well as embryonic responses to cholinergic, adrenergic, and ganglionic pharmacological blockade. Compared with N21 embryos, chronic H10 embryos had smaller bodies and relatively larger hearts and were hypotensive, tachycardic, and following autonomic neural blockade showed reduced intrinsic fH at 90% of incubation. Unlike other reptile embryos, cholinergic and ganglionic receptor blockade both increased fH. β-Adrenergic receptor blockade with propranolol decreased fH, and α-adrenergic blockade with phentolamine decreased Pm. We also measured cardiac mRNA expression. Cholinergic tone was reduced in H10 embryos, but cholinergic receptor (Chrm2) mRNA levels were unchanged. However, expression of adrenergic receptor mRNA (Adrb1, Adra1a, Adra2c) and growth factor mRNA (Igf1, Igf2, Igf2r, Pdgfb) was lowered in H10 embryos. Hypoxia altered the balance between cholinergic receptors, α-adrenoreceptor and β-adrenoreceptor function, which was reflected in altered intrinsic fH and adrenergic receptor mRNA levels. This is the first study to link gene expression with morphological and cardioregulatory plasticity in a developing reptile embryo.
爬行动物胚胎能耐受周围环境中氧气浓度的大幅下降。然而,我们还不完全了解大多数物种胚胎心血管系统对缺氧的短期或长期反应的机制。因此,我们测量了在常氧(N21;21% O₂)或慢性低氧(H10;10% O₂)条件下孵化的 snapping 龟胚胎的心脏生长和功能。我们在急性常氧(21% O₂)和急性低氧(10% O₂)条件下测定了心率(fH)和平均动脉压(Pm),以及胚胎对胆碱能、肾上腺素能和神经节药理学阻断的反应。与 N21 胚胎相比,慢性 H10 胚胎的体型较小,心脏相对较大,且血压较低、心率较快,自主神经阻断后,孵化 90%时的内在 fH 降低。与其他爬行动物胚胎不同的是,胆碱能和神经节受体阻断都增加了 fH。β-肾上腺素能受体阻断剂普萘洛尔降低了 fH,而α-肾上腺素能受体阻断剂酚妥拉明降低了 Pm。我们还测量了心脏的 mRNA 表达。H10 胚胎中的胆碱能张力降低,但胆碱能受体(Chrm2)mRNA 水平不变。然而,肾上腺素能受体 mRNA(Adrb1、Adra1a、Adra2c)和生长因子 mRNA(Igf1、Igf2、Igf2r、Pdgfb)的表达在 H10 胚胎中降低。缺氧改变了胆碱能受体、α-肾上腺素能受体和β-肾上腺素能受体功能之间的平衡,这反映在内在 fH 和肾上腺素能受体 mRNA 水平的改变上。这是第一项将基因表达与发育中爬行动物胚胎的形态和心脏调节可塑性联系起来的研究。
