中国北方汉族男性血管内皮生长因子受体2基因+4422(AC)n多态性与HiHiLo训练敏感性的关联研究

Association of VEGFR2 Gene+4422(AC) n Polymorphism with the Sensitivity to HiHiLo Training in Men of Han Nationality

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摘要目的:探讨中国北方汉族男性血管内皮生长因子受体2(VEGFR2)基因+4422(AC)n多态性与高住高练低训(HiHiLo)训练敏感性的关联。方法:选取71名中国北方平原地区汉族男子进行30天HiHiLo,方案为每日在低氧房(O2浓度为14.8%～14.3%,模拟海拔2800～3000米)居住10小时,每周进行3次75%VO2max强度的低氧训练(O2浓度为15.4%～14.8%,模拟海拔2500～2800米),运动时间为30 min/次,其余时间在常氧环境下训练。在HiHiLo前、后测定VO2 max和SpO2。其中SpO2的测定采用低氧环境下(15.4%O2,模拟海拔约2500米)的定量负荷运动实验,运动强度为HiHiLo前个体75%VO2max,运动时间15min。基因分型采用PCR结合荧光标记复合STR-genescan方法检测+4422(AC)n多态重复次数。结果:HiHiLo后,VO2 max以及定量负荷运动中SpO2均显著性提高,且(AC)11/(AC)11基因型者rVO2max的训练敏感性显著高于(AC)11/(AC)12基因型者。结论:VEGFR2基因+4422(AC)n多态性与HiHiLo后rVO2 max训练敏感性有关联,而与定量负荷下SpO2训练敏感性无关联。提示+4422(AC)n多态性可以作为预测低氧训练效果的分子遗传学标记,但还需加大样本量进一步验证。 Objective The purpose of this study was to explore the association between VEGFR2 gene＋4422（AC）n polymorphism to the sensitivity of HiHiLo.Methods Seventy one men of Han nationality in northern China underwent HiHiLo for 30 days.The subjects stayed in the hypoxic environment（14.8%～14.3%O2）10 hours per day,and performed 30-minute hypoxic exercise（15.4%～14.8%O2） three times per week at the intensity of individual baseline VO2 max.The remaining training courses were completed at sea level.VO2 max and SpO2 were monitored before and after HiHiLo,in which SpO2 was tested through fixed load exercise in hypoxic environment（15.4%O2）at the intensity of individual baseline VO2 max.The genotypes were analyzed by STR-genescan.Results The absolute（L·min-1）and relative（ml·kg-1·min-1）VO2max and SpO2 during fixed load exercise significantly increased after hypoxic training.The rVO2max of the（AC）11/（AC）11 genotype was significantly sensitive to HiHiLo as compared with the（AC）11/（AC）12.Conclusion There was an association between VEGFR2 gene ＋4422（AC）n polymorphism and the sensitivity of rVO2max to HiHiLo,while the polymorphism was not associated with the sensitivity of SpO2 during fixed load exercise to HiHiLo.It was suggested that VEGFR2 gene ＋4422（AC）n polymorphism could be used as a genetic marker for estimating the response to hypoxic training.Further investigation with greater sample size is needed to validate this finding.

作者聂晶胡扬王景玲衣龙燕乌云格日勒

机构地区江西师范大学北京体育大学山东省射击射箭训练基地内蒙古师范大学

出处《中国运动医学杂志》 CAS CSCD 北大核心 2011年第1期5-10,共6页 Chinese Journal of Sports Medicine

基金国家自然科学基金资助项目(30470834/C030314)

关键词血管内皮生长因子受体2 基因多态性低氧训练最大摄氧量脉搏血氧饱和度 VEGFR2 gene polymorphism hypoxic training VO2 max SpO2

分类号 R87 [医药卫生—运动医学]

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1Terman BI, Dougher-Vermazen M, Carrion M, et al. Identification of the KDR tyrosine kinase as a receptor for vascular endothelial cell growth factor. Biochem Biophys ResCommun, 1992, 187 (3): 1579-1586.
2Gavin TP, drew JL, kubik CJ, et al. Acute resistance exercise increases skeletal muscle angiogenic growth factor expression. Acta Physiol (Oxf), 2007, 191 (2) : 139-146.
3Gavin TP, Robinson CB, Yeager RC, et al. Angiogenic growth factor response to acute systemic exercise in human skeletal muscle. J Appl Physiol, 2004, 96 (1) 19-24.
4Gustafsson T, Ameln H, Fischer H, et al. VEGF-A splice variants and related receptor expression in human skeletal muscle following submaximal exercise. J Appl Physiol, 2005, 98 (6):2137-46.
5Gustafsson T, Rundqvist H, Norrbom J, et al. The influence of physical training on the angiopoietin and VEGF-A systems in human skeletal muscle. J Appl Physiol, 2007, 103 (3): 1012-1020.
6Lloyd PG, Prior BM, Yang HT, et al. Angiogenic growth factor expression in rat skeletal muscle in response to exercise training. Am J Physiol Heart Circ Physioh 2003, 284 (5): H1668-1678.
7Milkiewicz M, Hudlicka O, Verhaeg J, et al. Differential expression of Flk-1 and Flt-1 in rat skeletal muscle in response to chronic ischaemia .. favourable effect of muscle activity. Clin Sci Colch, 2003, 105 (4) : 473- 482.
8Motoyuki I, Seiji M, Subrina J, et al. Exercise training improves aging-induced downregulation of VEGF angio- genic signaling cascade in hearts. Am J Physiol Heart Circ Physiol, 2006, 291 (3): H1290-H1298.
9Timmons JA, Jansson E, Fisher H, et al. Modulation of extracellular matrix genes reflects the magnitude of physiological adaptation to aerobic exercise training in humans. BMCBiology, 2005, 3 (2)..19-28.
10Kariyazono H, Ohno T, Khajoee V, et al. Association of vascular endothelial growth factor (VEGF) and VEGF receptor gene polymorphisms with coronary artery lesions of Kawasaki disease. Pediatric Research, 2004, 56 (6) : 953-959.

二级参考文献24

1冯连世,宗丕芳,李福田,李泱,任一民,朱珂,张洁,杨碧英.高原训练对中长跑运动员红细胞生成的作用[J].体育科学,1998,18(4):78-81. 被引量：48
2胡扬.模拟高原训练的新发展——从HiLo到HiHiLo[J].中国运动医学杂志,2005,24(1):69-72. 被引量：74
3GUNGA H C. Vascular Endothelial Growth Factor in Exercising Humans under Different Environmental Conditions[J].Eur J Appl Physiol Occup Physiol, 1999,79(6) : 484-490.
4TISCHER E, GOSPODAROWICZ D, MITCHELL R, et al. Vascular Endothelial Growth Factor:a New Member of the Platelet-de-rived Growth Factor Gene Family [J]. Biochem Biophys Res Commun, 1989,165 : 1198-1206.
5LEUNG D W,CACHIANCE G,KUANG W J,et al. Vascular Endothelial Growth Factor Risasecreted Angiogenic Mitogen[J].Science, 1989,246:1306-1309.
6KONDO S, ASANO M, MATSUO K, et al. Significance of Vascular Endothelial Growth Factor/Vascular Permeability Factor for Solid Tumor Growth, and its Inhibition by the Antibody[J].Biochem Biophys Res Commun,1993,194 (3):1234-1241.
7SHWEIKI D, ITIN A, SOFFER D,et al. Vascular Endothelial Growth Factor Induced by Hypoxia May Mediate Hypoxiainitiated Angiogenesis [J]. Nature, 1992,359 : 843-845.
8TAKESHITA S, ZHENG L P, BROGI E, et al. Therapeautic Angiogenesis: A Single Intraartery Blous of Vascularization Inarabbiti Schemichind Limv Model[J]. J Clin Incest, 1994,93 :662-670.
9HARIAWALA M D, HOROWITZ J R, ESAKOF D, et al. VEGF Improves Myocardial Blood Flow but Produces EDRF-mediated Hypotension Porcine Hearts[J]. J Surg R ES, 1996,63:77 82.
10HAYASHI T, ABE K, ITOYAMA Y. Reduction of Ischemic Damage by Application of Vascular Endothelial Growth Factor in Rat Brain after Transient Ischemia[J]. J Cereb Bliid Flow Metab, 1998,18 : 887-895.

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2郑澜,陆爱云,周志宏.低氧训练促进大鼠心肌组织血管生成的体视学研究[J].体育科学,2005,25(9):49-52. 被引量：16
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6葛运华.血管内皮生长因子与运动的相关性[J].中国组织工程研究与临床康复,2007,11(23):4602-4605. 被引量：1
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中国北方汉族男性血管内皮生长因子受体2基因+4422(AC)n多态性与HiHiLo训练敏感性的关联研究

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