遗传与习服因素对高原人群血红蛋白调控的差异研究：基于世居藏族与久居、急进汉族的比较*

doi:10.3969/j.issn.1671-2587.2025.06.011

临床输血与检验 ›› 2025, Vol. 27 ›› Issue (6): 814-820.DOI: 10.3969/j.issn.1671-2587.2025.06.011

遗传与习服因素对高原人群血红蛋白调控的差异研究：基于世居藏族与久居、急进汉族的比较^*

王嘉琪¹, 肖军², 李小薇², 雷慧芬², 李治材², 李翠莹^1,2

¹河北北方学院研究生院 ,河北张家口 075000;
²空军军医大学空军特色医学中心输血科,北京 100142

收稿日期:2025-08-20 出版日期:2025-12-20 发布日期:2025-12-24
通讯作者: 李翠莹,主要从事临床输血及免疫血液学研究工作,E-mail：licuiying2013@qq.com。
作者简介:王嘉琪,主要从事临床检验诊断学及临床输血学研究工作,E-mail：15832303086@163.com。
基金资助:
^*本课题受国家自然科学基金面上项目（No.81971778）资助

Differences in the Regulation of Hemoglobin by Genetic and Acclimatization Factors in Highland Populations: A Comparison Based on Native Tibetans, Long-term Resident Han, and Acute Highland-entering Han

WANG Jiaqi¹, XIAO Jun², LI Xiaowei², LEI Huifen², LI Zhicai², LI Cuiying^1,2

¹Hebei North University, Zhangjiakou, Hebei 075000;
²Department of Blood Transfusion, Air Force Medical Center of Air Force Medical University, Beijing 100142

Received:2025-08-20 Online:2025-12-20 Published:2025-12-24

摘要/Abstract

摘要： 目的探讨高原低氧环境对不同人群血红蛋白含量（Hb）的影响规律及特点分析。方法本研究共纳入263名健康成年人,分为三组：（1）世居高原藏族组（n=160）：年龄18~65（38.3±13.0）岁,海拔≥3 000米;（2）久居高原汉族组（n=50）：年龄18~65（41.0±7.5）岁,移居高原≥10年且持续居住于海拔≥3 000米;（3）急进高原组（n=53）：年龄18~36（23.9±4.4）岁,长期居住平原（基线海拔≤50米,平均43.5米）且无高原暴露史。世居组与久居组在高原居住地进行单次横断面评估。急进高原组采用纵向研究设计：在进入高原（≥3 000米）前一周于平原进行基线测量,并于高原暴露后第3天、第7天、第30天进行重复测量。对血常规进行统计学分析以比较世居藏族、久居汉族在相同高原稳态环境下的Hb水平,解析遗传因素对Hb稳态调控的影响;对比自身基线（平原）和高原不同时间点的Hb水平,观察急性高原反应和早期习服过程。结果世居高原藏族不同性别Hb均低于久居高原汉族[男性：（177±24）g/L vs（203±23）g/L,P<0.01;女性：（143±21）g/L vs（156±24）g/L,P<0.05）;世居高原藏族18~50岁年龄段Hb均值显著低于久居高原汉族[18~30岁组（157±26）g/L vs（187±18）g/L,P=0.023;30~40岁组（153±30）g/L vs（178±33）g/L,P=0.003;40~50岁组：（156±33）g/L vs（178±36）g/L,P=0.022];世居高原藏族人群血红蛋白集中于140~150 g/L（20.63%）与160~170 g/L（14.38%）;久居高原汉族人群血红蛋白极端高值（>200 g/L）占比达22%;急进高原人群的Hb水平随进入高原时间呈不同上升趋势（7天均值170 vs基线152 g/L,7天Δ+11.2%,30天Δ+4.7%,P<0.001）。结论 Hb水平是高海拔地区不同人群高原适应的敏感生理学指标,不同分组人群Hb呈现多态性分布。

关键词: 血红蛋白, 高原, 缺氧, 低氧生理, 急进高原

Abstract: Objective To investigate the patterns and characteristics of hemoglobin (Hb) levels in different populations under high-altitude hypoxic conditions. Methods This study included 263 healthy adults divided into three groups: (1) Native Tibetan group (n=160): aged 18~65 (mean 38.3±13.0) years, residing at≥3 000 meters; (2) Long-term high-altitude Han Chinese group (n=50): aged 18~65 (41.0±7.5) years, residing at≥3 000 meters for≥10 years; (3) Acute High-Altitude Group (n=53): Age 18~36 (23.9±4.4) years, long-term residence in lowland areas (baseline altitude≤50 meters, mean 43.5 meters) with no prior high-altitude exposure. The native and long-term resident groups underwent a single cross-sectional assessment at their high-altitude locations. The Rapid Altitude Group employed a longitudinal study design: baseline measurements were taken at low altitude one week prior to high-altitude exposure (≥3 000 m), with repeated measurements conducted on days 3, 7 and 30 post-exposure. Statistical analysis of complete blood counts compared Hb levels between native Tibetans and long-term Han residents under identical high-altitude steady-state conditions to elucidate the influence of genetic factors on Hb homeostasis regulation. Hb levels were compared between baseline (lowland) and various high-altitude time points to observe acute mountain sickness and early acclimatization processes. Results 1) Hb levels in both male and female indigenous Tibetans were lower than those in long-term high-altitude Han Chinese [Males: (177±24) g/L vs. (203±23) g/L, P<0.01; females: (143±21) g/L vs. (156±24) g/L, P<0.05]; 2) The mean hemoglobin (Hb) level of Tibetan on the plateau in the 18~50-year-old age group was significantly lower than that of Han Chinese who had lived on the plateau for a long time [18~30 years: (157±26) g/L vs. (187±18) g/L, P=0.023; 30~40 years: (153±30) g/L vs. (178±33) g/L, P=0.003; 40~50 years: (156±33) vs. (178±36) g/L, P=0.022). Hemoglobin levels among Tibetan populations permanently residing at high altitudes were concentrated in the ranges of 140~150 g/L (20.63%) and 160~170 g/L (14.38%); among Han populations long-term residing at high altitudes, extremely high hemoglobin values (>200 g/L) accounted for 22%. 3) Hb levels in acutely acclimated populations exhibited a increase with time spent at altitude (7-day mean: 170 vs. baseline 152 g/L, Δ+11.2% increase at 7 days, Δ+4.7% at 30 days, P<0.001). Conclusion Hemoglobin levels serve as a sensitive physiological indicator of high-altitude adaptation across different populations, exhibiting polymorphic distribution patterns among distinct groups.

Key words: Hemoglobin, Plateau, Hypoxia, Hypoxic physiology, Sudden high-altitude ascent

中图分类号:

Q349R457

王嘉琪, 肖军, 李小薇, 雷慧芬, 李治材, 李翠莹. 遗传与习服因素对高原人群血红蛋白调控的差异研究：基于世居藏族与久居、急进汉族的比较^*[J]. 临床输血与检验, 2025, 27(6): 814-820.

WANG Jiaqi, XIAO Jun, LI Xiaowei, LEI Huifen, LI Zhicai, LI Cuiying. Differences in the Regulation of Hemoglobin by Genetic and Acclimatization Factors in Highland Populations: A Comparison Based on Native Tibetans, Long-term Resident Han, and Acute Highland-entering Han[J]. JOURNAL OF CLINICAL TRANSFUSION AND LABORATORY MEDICINE, 2025, 27(6): 814-820.

参考文献

[1] WU T Y,KAYSER B.High altitude adaptation in tibetans[J]. High Alt Med Biol,2006,7(3):193-208.
[2] HORNBEIN T F,TOWNES B D,SCHOENE R B,et al.The cost to the central nervous system of climbing to extremely high altitude[J]. N Engl J Med,1989,321(25): 1714-1719.
[3] HEINICKE K,PROMMER N,CAJIGAL J,et al.Long-term exposure to intermittent hypoxia results in increased hemoglobin mass,reduced plasma volume,and elevated erythropoietin plasma levels in man[J]. Eur J Appl Physiol,2003,88(6):535-543.
[4] 李玉红. 高原环境下藏汉族之间肺通气功能和血红蛋白比较[J]. 临床肺科杂志,2014,19(10):1785-1787.
[5] GE R L,SIMONSON T S,GORDEUK V,et al.Metabolic aspects of high-altitude adaptation in Tibetans[J]. Exp Physiol,2015,100(11):1247-1255.
[6] LI C Y,LI X W,XIAO J,et al.Genetic changes in the EPAS1 gene between Tibetan and Han ethnic groups and adaptation to the plateau hypoxic environment[J]. PeerJ, 2019,7:e7943.
[7] PENG Y,YANG Z H,ZHANG H,et al.Genetic variations in Tibetan populations and high-altitude adaptation at the Himalayas[J]. Mol Biol Evol,2011,28(2):1075-1081.
[8] CHILDEBAYEVA A,JONES T R,GOODRICH J M,et al.LINE-1 and EPAS1 DNA methylation associations with high-altitude exposure[J]. Epigenetics,2019,14(1):1-15.
[9] BEFANI C,LIAKOS P.The role of hypoxia-inducible factor-2 alpha in angiogenesis[J]. J Cell Physiol,2018, 233(12):9087-9098.
[10] PETOUSI N,ROBBINS P A.Human adaptation to the hypoxia of high altitude: the Tibetan paradigm from the pregenomic to the postgenomic era[J]. J Appl Physiol, 2014,116(7):875-884.
[11] LI Y H,ZHANG Y J,ZHANG Y.Research advances in pathogenesis and prophylactic measures of acute high altitude illness[J]. Respir Med,2018,145:145-152.
[12] GAO Z,LI Z C,LI X W,et al.Regulation of erythroid differentiation in K562 cells by the EPAS1-IRS2 axis under hypoxic conditions[J]. Front Cell Dev Biol,2023, 11:1161541.
[13] 李姗珊,史宝林,刘晓艳,等. 高原驻训对官兵血红蛋白含量的影响规律及特点分析[J]. 军事医学,2023,47(3):223-227.
[14] LI C Y,LI X W,LIU J,et al.Investigation of the differences between the Tibetan and Han populations in the hemoglobin-oxygen affinity of red blood cells and in the adaptation to high-altitude environments[J]. Hematology,2018,23(5):309-313.
[15] LI Z C,XIAO J,LI C Y,et al.Correlation between hematological indicators in acclimatized high-altitude individuals and acute mountain sickness[J]. PeerJ,2024, 12:e18738.
[16] WU T Y,WANG X Q,WEI C Y,et al.Hemoglobin levels in Qinghai-Tibet: different effects of gender for Tibetans vs. Han[J]. J Appl Physiol,2005,98(2):598-604.
[17] MEHRI R,MAVRIPLIS C,FENECH M.Red blood cell aggregates and their effect on non-Newtonian blood viscosity at low hematocrit in a two-fluid low shear rate microfluidic system[J]. PLoS One,2018,13(7):e0199911.

遗传与习服因素对高原人群血红蛋白调控的差异研究：基于世居藏族与久居、急进汉族的比较^*

Differences in the Regulation of Hemoglobin by Genetic and Acclimatization Factors in Highland Populations: A Comparison Based on Native Tibetans, Long-term Resident Han, and Acute Highland-entering Han

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

关于本刊

作者中心

在线期刊

访问统计

联系我们

[1]	王菲, 王海永, 夏荣. 成年人血清醛水平与贫血的相关性分析^*[J]. 临床输血与检验, 2025, 27(5): 629-637.
[2]	侯雪佳, 杨欣, 党盼玉, 尹文, 顾顺利. 创新型输血替代策略：纳米血红蛋白氧载体的研究进展[J]. 临床输血与检验, 2025, 27(5): 655-661.
[3]	王辉, 赵琴, 陈立力, 黄永莉, 张进进, 邢颜超. HPL-CS温敏凝胶促高原糖尿病大鼠难愈性创面愈合的研究^*[J]. 临床输血与检验, 2025, 27(4): 433-441.
[4]	吴常睿, 黄远帅, 王洁. 吸烟对红细胞影响的相关研究进展^*[J]. 临床输血与检验, 2024, 26(3): 411-419.
[5]	李洋, 杨明峰, 王莹, 张坚, 刘嘉馨, 孙保亮. 血红蛋白类氧载体的研究进展及应用前景^*[J]. 临床输血与检验, 2024, 26(2): 282-288.
[6]	冯志文, 韦孟娟, 曾彦霏, 苏秋莹, 戴应忠. 急性上消化道出血患者临床输血策略回顾性分析^*[J]. 临床输血与检验, 2023, 25(6): 767-772.
[7]	钟馨, 邱浩川, 陈斯亮, 李朝晖, 毛怀东, 章俊. 低血红蛋白密度对血液透析贫血患者缺铁性贫血和铁缺乏的诊断价值分析^*[J]. 临床输血与检验, 2023, 25(5): 654-661.
[8]	王莉, 王立新, 秦莉. 应用D-L抗体检测辅助诊断阵发性冷性血红蛋白尿症1例[J]. 临床输血与检验, 2022, 24(4): 515-517.
[9]	葛艳芬, 刘均如, 黄革, 李广华, 周茂华, 林婷, 冼璐桦. 新生儿异常Hb Q的家系分析^*[J]. 临床输血与检验, 2022, 24(3): 328-332.
[10]	吴飞, 沈九龙, 邓刚. 浙江省新生儿脐带血血常规相关指标和各型血红蛋白质量百分比参考值的确定及其对血红蛋白病诊断的意义分析[J]. 临床输血与检验, 2022, 24(2): 239-243.
[11]	李翠莹, 李小薇, 肖军, 雷慧芬, 孟方园, 高瞻. 高原低氧快速适应人群筛选及其低氧适应相关基因的表达研究^*[J]. 临床输血与检验, 2021, 23(5): 564-569.
[12]	李小薇, 肖军, 雷慧芬, 白晓莹, 孟方园, 李翠莹. 藏、汉族EPAS1基因启动子区DNA甲基化的差异研究^*[J]. 临床输血与检验, 2021, 23(5): 569-573.
[13]	肖军, 李小薇, 高瞻, 孟方园, 卢江敏, 候杜娟, 李翠莹. 基于径向基函数神经网络的高原适应人群预测模型构建及应用研究^*[J]. 临床输血与检验, 2021, 23(5): 574-577.
[14]	余凤秀, 李津杞, 朱燕霞, 郭菲, 周载鑫, 顾海慧, 钱宝华. 二次重度离心制备法对冷沉淀凝血因子质量的影响^*[J]. 临床输血与检验, 2020, 22(5): 477-480.
[15]	赵铁民, 吴晓艳. 青藏高原地区大量输血治疗后患者部分检验指标检测值变化及相关因素研究[J]. 临床输血与检验, 2019, 21(5): 474-476.