Enhanced Placental Mitochondrial Respiration in Tibetan Women at High Altitude.

Huifang Liu,Noryung Tenzing,Muge Qile,Tana Wuren,Ri-Li Ge,Martha Tissot Van Patot

doi:10.3389/fphys.2021.697022

Huifang Liu, Noryung Tenzing + Show 4 more

Open Access

https://doi.org/10.3389/fphys.2021.697022

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Abstract

Living at high altitudes is extremely challenging as it entails exposure to hypoxia, low temperatures, and high levels of UV radiation. However, the Tibetan population has adapted to such conditions on both a physiological and genetic level over 30,000–40,000 years. It has long been speculated that fetal growth restriction is caused by abnormal placental development. We previously demonstrated that placentas from high-altitude Tibetans were protected from oxidative stress induced by labor compared to those of European descent. However, little is known about how placental mitochondria change during high-altitude adaptation. In this study, we aimed to uncover the mechanism of such adaptation by studying the respiratory function of the placental mitochondria of high-altitude Tibetans, lower-altitude Tibetans, and lower-altitude Chinese Han. We discovered that mitochondrial respiration was greater in high-altitude than in lower-altitude Tibetans in terms of OXPHOS via complexes I and I+II, ETSmax capacity, and non-phosphorylating respiration, whereas non-ETS respiration, LEAK/ETS, and OXPHOS via complex IV did not differ. Respiration in lower-altitude Tibetans and Han was similar for all tested respiratory states. Placentas from high-altitude Tibetan women were protected from acute ischemic/hypoxic insult induced by labor, and increased mitochondrial respiration may represent an acute response that induces mitochondrial adaptations.

Highlights

The oxygen content of the atmosphere is 21% regardless of altitude, while the barometric pressure decreases as the altitude increases
We observed a low respiratory control ratio (RCR) in lower-altitude Tibetan (RCR: 1.4) and Han (RCR: 1.5) mitochondria using substrates for complex I (CI), suggesting that these mitochondria have impaired respiratory efficiency
Our study provides evidence that significant differences in human placental mitochondrial respiration exist between Tibetan women living at high and those at lower altitudes

Summary

Introduction

The oxygen content of the atmosphere is 21% regardless of altitude, while the barometric pressure decreases as the altitude increases. High altitude is defined as ≥2,500 m above sea level (Julian and Moore, 2019). The main challenges at high altitudes are hypoxia, low temperatures, and high levels of UV radiation (Peacock, 1998; Butaric and Klocke, 2018; Song et al, 2020). Tibetans are protected from polycythemia, pulmonary hypertension, low birth weight, and other hypoxia-related diseases that normally result from prolonged exposure to such inhospitable environments (Yang et al, 2017; Jeong et al, 2018; Bhandari and Cavalleri, 2019; Song et al, 2020).

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