Snyder L R
J Appl Physiol (1985). 1985 Jan;58(1):193-9. doi: 10.1152/jappl.1985.58.1.193.
Whereas it is widely believed that animals native to high altitude show lower O2 partial pressures at 50% hemoglobin saturation (P50) than do related animals native to low altitude, that "fact" has not been well documented. Consequently, P50 at pH 7.4, PCO2(7.4), the CO2 Bohr effect, and the buffer slope (delta log PCO2/delta pH) were determined via the mixing technique in Peromyscus maniculatus native to a range of altitudes but acclimated to 340 or 3,800 m. PCO2(7.4) and buffer slope were substantially lower at high altitude. The change in P50(7.4) between acclimation altitudes was minimal (0.8% increase at 3,800 m), because of counterbalancing changes in PCO2, 2,3-diphospho-D-glycerate concentration, and perhaps other factors. At both acclimation altitudes there was a highly significant negative correlation between P50(7.4) and native altitude. Since pH in vivo probably increases slightly at high altitude, the data on P50 corrected to pH 7.4 are probably underestimates of the difference in in vivo P50 at low vs. high altitude. Hence these results corroborate theoretical predictions that low P50 is advantageous under severe hypoxic stress.
尽管人们普遍认为,与生活在低海拔地区的相关动物相比,生活在高海拔地区的原生动物在血红蛋白饱和度为50%时的氧分压(P50)较低,但这一“事实”尚未得到充分的记录。因此,通过混合技术,对生活在一系列海拔高度但适应于340米或3800米高度的鹿鼠进行了pH值为7.4时的P50、二氧化碳分压(PCO2(7.4))、二氧化碳玻尔效应和缓冲斜率(δlog PCO2/δpH)的测定。高海拔地区的PCO2(7.4)和缓冲斜率明显较低。由于二氧化碳分压、2,3-二磷酸-D-甘油酸浓度以及可能的其他因素的相互抵消变化,适应海拔高度之间的P50(7.4)变化很小(在3800米处增加0.8%)。在两个适应海拔高度下,P50(7.4)与原生海拔高度之间都存在高度显著的负相关。由于高海拔地区体内pH值可能会略有升高,校正到pH值为7.4时的P50数据可能低估了低海拔与高海拔地区体内P50的差异。因此,这些结果证实了理论预测,即在严重缺氧应激下,低P50是有利的。
