高原鼠兔肺动脉血管功能及形态变化

目的研究肺循环对慢性缺氧的适应机理.方法在4300m的高度捕捉到高原适应动物鼠兔,带到2260m的高度并和10只Wistar大鼠在模拟4300m和5000m高度的低压仓内进行了肺动脉压的测定,观察肺组织学和组织免疫化学的改变.结果在2260m,鼠兔的Ppa明显低于Wistar大鼠,二者分别为(1.5±0@07)kPa和(2.9±1.1)kPa(P＜0.01).随着海拔高度的增加,鼠兔的Ppa上升不明显,而Wistar大鼠增加显著.左右心室比重鼠兔为0.22,而Wistar大鼠为0.45.鼠兔的Hb,Hct和2.3-DPG均低于大鼠.大鼠肺小血管周围可见肥大细胞(7.1±0.33)mm2,免疫组化染色mastcelltyptase颗粒呈阳性,鼠兔未发现肥大细胞及此种免疫反应.肺小动脉中层较鼠兔厚,分别为27.21%和9.22%,壁的厚度和Ppa有很好的(r=0.763).结论鼠兔无低氧性肺血管收缩,是一种遗传性适应.大鼠肥大细胞通过激活某些生长因子,在肺血管的再建过程中可能起一定作用.     

Thoracic adaptation to high altitude

Growth in the thoracic region and its adaptation to higher altitude was investigated in boys between 5 to 18 years of Rajput origin at two altitudes, i. e. Rampur Bushahr (800 m above sea level) and Kinnaur (3,000 m above sea level). Both places are located in Himachal Pradesh. The sample includes 405 individuals From Bushahr and 676 individuals from Kinnaur. The results of this study reveal that as the higher altitudes are attained the vital capacity also increases relatively more, and these differences become more pronounced after adolescence, indicating longer time of apnoea. The population living at higher altitudes is also characterised by a significant greater chest length.     

Changes in fibrinolysis components during short-term adaptation to high altitude]

In studying hemocoagulation in dogs under conditions of Frunze (760 m above the sea level) and Tuya-Ashu (3200 m above the sea level) it was shown that in the "emergency" phase of adaptation (the first three days) there was seen activation of fibrinolysin and profibrinolysin with depression of antifibrinolysins and inhibitors of profibrinolysin activators. The concentration of plasma fibrinogen at that period decreased by 100 mg%, which could promote an increase in the vascular permeability and improvement of oxygen approach to the tissues. Later, along with elevation of fibrinolysin and profibrinolysin activators there was a marked increase in the level of fibrinolysis inhibitors. Correlation of all the fibrinolysis components was established at a new level.     

动物对高原低氧的适应性研究进展

本文从血液学、肺动脉、心肺发育及其它方面简要介绍了动物对高原低氧适应的生理、生化及形态学特征,同时也对其中低氧诱导因子的作用及其遗传性方面的研究进行了概述。关于高原低氧适应的遗传机制仍需进一步的深入研究。     

Developmental adaptation to high altitude hypoxia

Experimental studies on animals and humans exposed to hypoxic stress have been reviewed. These data suggest that the influence of hypoxic stress, and the organism's response to it, are greater during growth than during adulthood. The organism's responses include alterations in the quantity and size of the alveolar units of the lungs, enlargement of the right ventricle of the heart, slower somatic growth as measured by birth weight and body size, increased aerobic capacity during maximal work, and greater control of ventilation. It is postulated that the organism is more sensitive to the influence of environmental factors during growth and development than during adulthood. Consequently, adaptive traits acquired during the developmental period have profound, long-term consequences, which are reflected in the physiological and morphological characteristics of the adult organism. It is concluded that the differences between the highland and lowland natives in their physiological performance and morphology are mostly due to adaptations acquired during the developmental period.Attention is called to the fact that the principle of developmental sensitivity and plasticity does not imply equally adaptive responses in all biological parameters. In other words, what we consider a deficiency in a given variable may actually reflect the indirect influence of the adaptive success of another variable.Presented at the Seventh International Biometeorological Congress, 17–23 August 1975, College Park Maryland, USA.     

Functional changes in hematopoiesis in healthy subjects during adaptation to a high altitude hypoxia

In the article, findings of the studies of white blood in healthy subjects during a short-term adaptation to high altitude (per. Tuya-Ashu, 3200 m), are discussed. A 40-day adaptation of healthy people has led to positive shifts: an increase of the number of leukocytes with prevalence of the absolute count of neutrophiles and lymphocytes, as well as an activation of the latter during the first days of stay at high altitude. An effect of the high-altitude hypoxia resulted in intensification of erythropoiesis that manifests itself in an improvement of red cell hemoglobinization and a decrease of the degree of non-effective erythropoiesis. The data obtained support the data of the myelograms demonstrating an improvement of differentiation of white hematopoiesis.     

Genetic adaptation to high altitude in the Ethiopian highlands

Background

Genomic analysis of high-altitude populations residing in the Andes and Tibet has revealed several candidate loci for involvement in high-altitude adaptation, a subset of which have also been shown to be associated with hemoglobin levels, including EPAS1, EGLN1, and PPARA, which play a role in the HIF-1 pathway. Here, we have extended this work to high- and low-altitude populations living in Ethiopia, for which we have measured hemoglobin levels. We genotyped the Illumina 1M SNP array and employed several genome-wide scans for selection and targeted association with hemoglobin levels to identify genes that play a role in adaptation to high altitude.

Results

We have identified a set of candidate genes for positive selection in our high-altitude population sample, demonstrated significantly different hemoglobin levels between high- and low-altitude Ethiopians and have identified a subset of candidate genes for selection, several of which also show suggestive associations with hemoglobin levels.

Conclusions

We highlight several candidate genes for involvement in high-altitude adaptation in Ethiopia, including CBARA1, VAV3, ARNT2 and THRB. Although most of these genes have not been identified in previous studies of high-altitude Tibetan or Andean population samples, two of these genes (THRB and ARNT2) play a role in the HIF-1 pathway, a pathway implicated in previous work reported in Tibetan and Andean studies. These combined results suggest that adaptation to high altitude arose independently due to convergent evolution in high-altitude Amhara populations in Ethiopia.     

Control of breathing and adaptation to high altitude in the bar-headed goose

The bar-headed goose flies over the Himalayan mountains on its migratory route between South and Central Asia, reaching altitudes of up to 9,000 m. We compared control of breathing in this species with that of low-altitude waterfowl by exposing birds to step decreases in inspired O(2) under both poikilocapnic and isocapnic conditions. Bar-headed geese breathed substantially more than both greylag geese and pekin ducks during severe environmental (poikilocapnic) hypoxia (5% inspired O(2)). This was entirely due to an enhanced tidal volume response to hypoxia, which would have further improved parabronchial (effective) ventilation. Consequently, O(2) loading into the blood and arterial Po(2) were substantially improved. Because air convection requirements were similar between species at 5% inspired O(2), it was the enhanced tidal volume response (not total ventilation per se) that improved O(2) loading in bar-headed geese. Other observations suggest that bar-headed geese depress metabolism less than low-altitude birds during hypoxia and also may be capable of generating higher inspiratory airflows. There were no differences between species in ventilatory sensitivities to isocapnic hypoxia, the hypoxia-induced changes in blood CO(2) tensions or pH, or hypercapnic ventilatory sensitivities. Overall, our results suggest that evolutionary changes in the respiratory control system of bar-headed geese enhance O(2) loading into the blood and may contribute to this species' exceptional ability to fly high.     

Functional adaptation of spiriferide brachiopod morphology

It has been suggested that spiriferide morphologies have evolved to adapt to a variety of environmental conditions. Through a computational fluid dynamics approach, we examined how the spiriferide original form was optimized for a lotic condition, specifically addressing the functionalization of the Devonian spiriferide brachiopod Paraspirifer bownockeri to generate passive feeding flows. The results using four models, each of which differed in the development of the spiriferide shell depression, i.e. sulcus, showed that a deeper sulcus functions to create strong spiral flows so as to align on the feeding organ inside the shell. Among the sulcus‐developed models, only the mimic of the natural form could generate comparative slow flows with a stable inflow area. The fossil record of spiriferides shows a morphological trade‐off between the development of the sulcus and wing form. We concluded that spiriferide shells with such a morphological combination evolved to produce various feeding strategies, resulting in diversification.     

Evolution of pulmonary diffusing capacity in man during high altitude acclimatization]

Pulmonary diffusing capacity (DLCO) has been measured at 3500 m in highlander and lowlander subjects. DLCO is more elevated in highlanders than in lowlanders. In these subjects, a transient increase of DLCO is observed during the first hours of hypoxia which is related to transient changes in pulmonary circulation.     

Effect of adaptation to high altitude on components of blood and urine of lowlanders compared with high altitude natives

Some of the blood and urinary constituents, oral glucose tolerance and urea clearance were determined in lowlanders at sea level (200 m) and at an altitude of 4, 000 m after their stay of two years. These data were compared with those of natives of high altitude area. The concentration of proteins, cholesterol, creatinephosphokinase and aspartate aminotransferase in blood among lowlanders after 2 year acclimatization were similar to that observed among highlanders. The urinary excretion of creatine and creatinine was of similar magnitude in highlanders and in acclimatized lowlanders but that of 17-keto and 17-hydroxysteroids was higher among highlanders. High altitude acclimatization among lowlanders facilitated appearance of a sharp peak in oral glucose tolerance curves and a decreased fasting blood glucose values. It also induced a restriction in renal filtration as indicated by a depressed urea clearance among lowlanders.