Abstract
The response mechanism and interaction patterns of HIF-1α and p53 in animals in an hypoxic environment are crucial for their hypoxic tolerance and adaptation. Many studies have shown that underground rodents have better hypoxic adaptation characteristics. However, the mechanism by which HIF-1α and p53 in underground rodents respond to hypoxic environments compared with in ground rodents remains unclear. Further, whether a synergy between HIF-1α and p53 enables animals tolerate extremely hypoxic environments is unclear. We studied HIF-1α and p53 expression in the brain tissue and cell apoptosis in the hippocampal CA1 region during 6 hours of acute hypoxia (5% oxygen) in Lasiopodomys mandarinus (Milne-Edwards, 1871) and Lasiopodomys brandtii (Radde, 1861), two closely related small rodents with different life characteristics (underground and aboveground, respectively), using a comparative biology method to determine the mechanisms underlying their adaptation to this environment. Our results indicate that HIF-1α and p53 expression is more rapid in L. mandarinus than in L. brandtii under acute hypoxic environments, resulting in a significant synergistic effect in L. mandarinus. Correlation analysis revealed that HIF-1α expression and the apoptotic index of the hippocampal CA1 regions of the brain tissues of L. mandarinus and L. brandtii, both under hypoxia, were significantly negatively and positively correlated, respectively. Long-term existence in underground burrow systems could enable better adaptation to hypoxia in L. mandarinus than in L. brandtii. We speculate that L. mandarinus can quickly eliminate resulting damage via the synergistic effect of p53 and HIF-1α in response to acute hypoxic environments, helping the organism quickly return to a normal state after the stress.
Highlights
Oxygen is essential for the metabolism of most living organisms; in particular, it is the basis for the growth and reproduction of aerobic organisms
The expression level of HIF1α in both the brain tissues of both voles tended to first increase before subsequently decreasing, and its expression peaked in both voles at 12 hours after oxygen restoration (Fig. 1)
The expression of HIF-1α in the brain tissue of L. mandarinus was significantly higher than that in the brain tissue of L. brandtii at 12 hours after oxygen restoration (p = 0.043), whereas the expression of HIF-1α was significantly lower in the brain tissue of
Summary
Oxygen is essential for the metabolism of most living organisms; in particular, it is the basis for the growth and reproduction of aerobic organisms. Most organisms who have lived in hypoxic environments for a long time have developed several adaptive features. The adaptive characteristics in subterranean rodents are manifested by the convergence of numerous physiological, morphological, behavioral, and genomic features (Šumbera et al 2004, Kim et al 2011, Nevo 2013). Subterranean rodents naturally live in enclosed, hypoxic underground tunnels that present many challenges, including severe hypoxia and limited food availability during extended periods of rain or when the soil freezes during winter. Subterranean rodents have evolved strategies and features to address these environmental obstacles (Shams et al 2005). During the rainy season, Spalax carmeli Nevo, Ivanitskaya & Beiles, 2001 (Rodentia: Spalacidae) can maintain normal life activities in an extremely low-oxygen environment of 7.2% (Shams et al 2005). Spalax ehrenbergi Nehring, 1898 (Rodentia: Spalacidae) can survive for more than 11 hours in an extreme, 3% hypoxic environment, whereas rats can only survive for 2.5 hours in such an environment (Avivi et al 1999)
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