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研究生: 陳姿汶
Tzu Wen Chen
論文名稱: 基因ACTN3、ACE與PPARD的多形性與運動表現的關聯性
The associations of ACTN3, ACE, and PPARD polymorphisms with physical fitness performance.
指導教授: 謝伸裕
Hsieh, Shen-Yu
學位類別: 碩士
Master
系所名稱: 體育學系
Department of Physical Education
論文出版年: 2009
畢業學年度: 97
語文別: 中文
論文頁數: 70
中文關鍵詞: α-actinin-3Ang IIPPAR δ體適能基因多型性
英文關鍵詞: α-actinin-3, Ang II, PPAR δ, physical fitness, gene polymorphism
論文種類: 學術論文
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  • 目的:探討一般沒有接受運動訓練的個體,所擁有ACTN3基因型RR、RX、XX;ACE基因型II、ID、DD;與PPARD 基因型TT、TC、CC,在運動能力測驗上之差異。方法:找尋411名16-18歲坐式生活沒有運動習慣的健康男性(241人)及女性(170人),測量受試者的身高、體重、BMI及體脂肪量,並接受運動測試項目為:60 m衝刺跑、立定跳遠、30秒伏地挺身、60秒伏地挺身、30秒仰臥起坐、60秒仰臥起坐、握力、25 m游泳及心肺耐力測驗(男生1600 m跑走、女生800 m跑走);收集口腔黏膜細胞,以聚合酶鏈鎖反應-限制酶片段長度多形性(PCR-RFLP)進行基因型分析,測驗所得資料進行單因子變異數及皮爾森積差相關統計分析。結果:ACTN3基因中,在女生30秒仰臥起坐測驗,RR型(19.29 ± 4.49次)表現次數多於RX型(16.88 ± 4.13次)(p< .05);女生60秒仰臥起坐測驗,RR型(35.42 ± 8.71次)表現次數多於RX型(29.91 ± 8.24次)(p< .05)。ACE基因中,女生握力成績,DD型(27.23 ± 4.39 kg)比ID型(23.58 ± 4.20 kg)(p< .05)有較好的肌力表現。結論:從運動表現來看,女生擁有ACTN3 RR及ACE DD基因型者會有較佳的肌力和肌耐力表現。

    Purpose: To examine the role of ACTN3, ACE and PPARD polymorphism on physical fitness performance in untrained person. Also, to assess the differences in effect of the polymorphism on phenotype associated with different physical performance. Methods: All 411 subjects were of native Taiwan students and aged from 16-18 years old (241 males and 170 females). Height, weight, BMI and body fat were measured. Physical fitness performance were measured in 40m sprint, 30 sec push-up, 60 sec push-up, 30 sec sit-ups, 60 sec sit-ups, handgrip strength, 25m swim, and 1600m run for males, 800m run for females. The genotype of ACTN3, ACE, and PPARD genes were determined by polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP). One-way ANOVA and Pearson’s product-moment correlation were used for statistical analysis. Results: In ACTN3, the female 30 sec sit-ups performance, RR genotype (19.29 ± 4.49 times) is greater than RX genotype (16.88 ± 4.13 times) (p < .05). In 60 sec sit-ups performance, RR genotype (35.42 ± 8.71 times) is also greater than RX genotype (29.91 ± 8.24 times) (p < .05). In ACE, the female handgrip strength performance, DD genotype (27.23± 4.39 kg) is greater than ID genotype (23.58 ± 4.20 kg) (p < .05). Conclusion: The subjects with ACTN3 RR and ACE DD genotype had better performance in 30 sec sit-ups, 60 sec sit-ups, and handgrip strength.

    第一章 緒論…………………………………………………… 01 一、問題背景………………………………………………… 01 二、研究目的………………………………………………… 04 三、研究假設………………………………………………… 05 四、名詞操作性定義………………………………………… 05 五、研究限制………………………………………………… 08 六、研究的重要性…………………………………………… 08 第二章 相關文獻探討………………………………………… 09 一、基因的簡介……………………………………………… 09 二、ACTN3、ACE與PPARD基因多形性的功能…………… 12 三、優秀運動表現與ACTN3、ACE與PPARD基因多形性    的關聯性………………………………………………… 15 四、本章結語………………………………………………… 21 第三章 研究方法……………………………………………… 22 一、受試者…………………………………………………… 22 二、實驗設計………………………………………………… 22 三、實驗的方法與步驟……………………………………… 23 四、ACTN3、ACE與PPARD基因多形性分析……………… 25 五、統計分析………………………………………………… 29 第四章 結果…………………………………………………… 30 一、受試者基本資料及運動測驗的數值…………………… 30 二、 ACTN3、ACE及PPARD基因多形性的分配…………… 31 三、不同運動測驗之間的相關性…………………………… 32 四、ACTN3、ACE及PPARD基因多形性與身體質量及運    動表現的關聯…………………………………………… 34 第五章 討論與結論…………………………………………… 39 一、受試者各基因型的分配頻率…………………………… 39 二、運動表現之間的相關性………………………………… 41 三、運動表現與基因的關聯性……………………………… 44 四、結論與建議……………………………………………… 49 引用文獻………………………………………………………… 51 一、中文部份………………………………………………… 51 二、英文部分………………………………………………… 52 附錄一 受試者需知與個人資料…………………………………………… 57 附錄二 ACTN3、ACE及PPARD 基因之引子序列、PCR反應條件……… 59 附錄三 (男生)ACTN3基因型與運動表現、BMI及體脂肪量的成績…… 60 附錄四 (男生)ACTN3基因型與運動表現、身體組成的比較………… 61 附錄五 (女生)ACTN3基因型與運動表現、BMI及體脂肪量的成績… 62 附錄六 (男生)ACE基因型與運動表現、BMI及體脂肪量的成績…… 63 附錄七 (男生)ACE基因型與運動表現、身體組成的比較…………… 64 附錄八 (女生)ACE基因型與運動表現、BMI及體脂肪量的成績…… 65 附錄九 (男生)PPARD基因型與運動表現、BMI及體脂肪量成績……… 66 附錄十 (男生)PPARD基因型與運動表現、身體組成的比較…………… 67 附錄十一 (女生)PPARD基因型與運動表現、BMI及體脂肪量成績…… 68 附錄十二 (女生)PPARD基因型與運動表現、身體組成的比較……… 69 個人小傳……………………………………………………………………… 70 表 次 表2-1 優秀運動員與ACTN3基因的關聯…………………………… 18 表2-2 訓練前後差異性的研究……………………………………… 18 表2-3 優秀運動員與ACE基因的關聯……………………………… 20 表4-1 男生、女生身體組成基本資料……………………………… 30 表4-2 受試者運動測驗資料………………………………………… 31 表4-3 受試者ACTN3 R/X、ACE I/D及PPARD T/C基因分配頻率… 32 表4-4 (男生)肌力、肌耐力、爆發力運動項目表現的相關分析…… 33 表4-5 (女生)肌力、肌耐力、爆發力運動項目表現的相關分析…… 33 表4-6 受試者肌耐力、爆發力與心肺耐力測驗的相關分析………… 34 表4-7 (女生)ACTN3基因型與運動表現、身體組成的比較……… 35 表 4-8(女生)ACTN3基因型與運動表現及體脂肪量的事後比較…… 36 表4-9 (女生)ACE 基因型與運動表現、身體組成的比較………… 37 表4-10 (女生)ACE基因型與握力運動表現的事後比較…………… 38 圖 次 圖3-1 實驗設計……………………………………………… 22 圖3-2 實驗程圖……………………………………………… 23 圖3-3 ACTN3基因型………………………………………… 27 圖3-4 ACE 基因型………………………………………… 28 圖3-5 PPARD 基因型……………………………………… 29

    一、中文部份:
    王靜、阿孜古丽•买合买提、童国玉、沈山梅、黄洪、杨东辉等(2008)。PPARδ基因+294T/C多態性與代謝綜合症的關係探討。徐州醫學院學報,28(10),651-655。

    牙買加短跑王國 能人所不能(2008,8月25日)。今日新聞奧運專版。線上檢索日期:2008年11月30日。網址:http://www.nownews.com/2008/08/25/11483-2325263.htm。

    行政院體育委員會(2009)。體能的定義與分類。2009年7月19日,取自行政院體育委員會網站,網址http://www.ncpfs.gov.tw/library/library-1.aspx? No=3&MenuID=31&Parent_ID=25

    林正焜、洪火樹(2005)。認識DNA。臺北市:商周出版。

    林瑞興、吳銘庭(2006)。ACE基因型與運動員心臟及耐力運動表現。中華民國體育季刊,20,31-39。

    松澤昭雄(2004)。圖解遺傳學。臺北縣新店市:藝軒出版

    邱麗玲、謝玲玲、顏克典、謝伸裕(2007)。ACTN3與ACE基因多形性與優秀爆發型運動員的相關性。體育學報,40,1-12。

    徐玉蘭(2008)。血管張力素轉化酶及α-輔肌動蛋白基因對跆拳道訓練後基本技能與體適能之影響。未出版碩士論文,國立新竹教育大學,新竹市。

    郭捷、楊曉琪、李寧遠(2003)。天生冠軍相?基因掌控運動表現?!。健康世界,214,9-13。

    教育部體適能網(2007)。體適能的定義與重要性。2009年7月19日,取自教育部體適能網站,網址http://www.fitness.org.tw/TW/ index.html

    張慧英、林寶城(2005)。增強式肌力訓練對高中女子籃球選手跳躍表現之影響。北體學報,13,150-159。

    張鵬遠、毛彥明、徐台閣(2007)。血管張力素轉化酶基因與優秀跆拳道選手之關係。體育學報,40,29-38。

    傳浩堅、楊錫讓(2003)。運動健身的科學原理。香港:商務。

    蔡崇濱、劉立宇、林政東、吳忠(譯)(2001)。運動訓練法。台北巿:藝軒圖書。(Tudor, O. B., 1999)

    盧思穎與林正常(2006)。五千公尺跑步成績與肌肉適能的相關研究。運動生理暨體能學報,4,139-147。

    謝純岑、楊宜瑱、翁國昌、黃建寧(2008)。Peroxisome Proliferator-Activated Receptors ( PPARs ) 和活化劑 ( agonists ):文獻回顧。內科學誌,19,14-26。

    謝文亮、蕭博文、吳福森(2008)。PPAR及其相關藥物新知。臺灣醫學,12,601-612。 
      

    二、英文部份:
    Ahmetov, I. I., Astratenkova, I. V., & Rogozkin V.A. (2007). Association of a PPARD polymorphism with human physical performance. Molekulyarnaya Biologiya, 41(5), 825-827.

    Alvarez, R., Reguero, J. R., Batalla, A., Iglesias-Cubero, G., Cortina, A., Alvarez, V., & Coto, E. (1998).Angiotensin-converting enzyme and angiotensin II receptor 1 polymorphisms: association with early coronary disease. Cardiovascular Research, 40, 375-379.

    Åstrand, P. O., & Rodahl, K. (1977). Textbook of work physiology (2nd ed.). New York: McGraw-Hill companies.

    Baudin, B. (2002). New aspects on angiotensin-converting enzyme: from gene to disease. Clinical Chemistry and Laboratory Medicine, 40(3), 256-265.

    Blanchard, A., Ohanian, V., & Critchley, D. (1989). The structure and function of α-actinin. Journal of Muscle Research and Cell Motility, 10(4), 280-289.

    Brink, M., Wellen, J., & Delafontaine, P. (1996). Angiotensin II causes weight loss and decreases circulating insulin-like growth factor I in rats through a pressor- independent mechanism. The Journal of Clinical Investigation, 97, 2509-2516.

    Cam, S., Colakoglu, M., Colakoglu, S., Sekuri, C., & Berdeli, A. (2007). ACE I/D gene polymorphism and aerobic endurance development in response to training in a non-elite female cohort. The Journal of Sports Medicine and Physical Fitness, 47(2), 234-238.

    Chuang, L. M., Chiu, K. C., Chiang, F. T., Lee, K. C, Wu, H. P., Lin, B.J., & Tai, T. Y. (1997). Insertion/deletion polymorphism of the angiotensin I-converting enzyme gene in patients with hypertension, non-insulin-dependent diabetes mellitus, and coronary heart disease in Taiwan. Metabolism, 46(10), 1211-1214.

    Clarkson, P. M., Devaney, J. M., Gordish-Dressman, H., Thomposon, P. D., Hubal, M. J., Urso, M., et al. (2005). ACTN3 genotype is associated with increases in muscle strength in response to resistance training in women. Journal of Applied Physiology, 99(1), 154-163.

    Clarkson, P. M., Hoffman, E. P., Zambraski, E., Godish-Dressman, H., Kearns, A., Hubal, M., et al. (2005). ACTN3 and MLCK genotype associations with exertional muscle damage. Journal of Applied Physiology, 99(2), 564-569.

    Coates, D. (2003). The angiotensin converting enzyme (ACE). The International Journal of Biochemistry and Cell Biology, 35, 769-773

    Druzhevskaya, A. M., Ahmetov, I. I., Astrakenkova, I. V., & Rogozkin, V. A. (2008). Association of the ACTN3 polymorphism with power athlete status in Russians. European Journal of Applied Physiology, 103(6), 631-634.

    Delmonico, M. J., Kostek, M. C., Doldo, N. A., Hand, B. D., Walsh, S., Conway, J. M., et al. (2007). Alpha-actinin-3 (ACTN3) R577X polymorphism influences knee extensor peak power response to strength training in older men and women. The Journals of Gerontology. Series A, Biological Sciences and Medical Sciences, 62(2), 206-212.

    Gayagay, G., Yu, B., Hambly, B., Boston, T., Hahn, A., Celermajer, D. S., & Trent, R. J. (1998). Elite endurance athletes and the ACE I allele-the role of genes in athletic performance. Human Genetics, 103, 48-50.

    Gordon, S. E., Davis, B. S., Carlson, C. J., & Booth, F. W. (2001). Ang II is required for optimal overload-induced skeletal muscle hypertrophy. American Journal of Physiology. Endocrinology and Metabolism, 280(1), E150-E159.

    Issemann, I., & Green, S. (1990). Activation of a member of the steroid hormone receptor superfamily by peroxisome proliferators. Nature, 347, 645-650.

    Kostek, M. C., Delmonico, M. J., Reichel, J. B., Roth, S. M., Douglass, L., Ferrell, R. E., et al. (2005). Muscle strength response to strength training is influenced by insulinlike growth factor 1 genotype in older adults. Journal of Applied Physiology, 98(6), 2147-2154.

    Lucia, A., Gómez-Gallego, F., Barroso, I., Rabadán, M., Bandrés, F., San, J.A., et al. (2005). PPARGC1A genotype (Gly482Ser) predicts exceptional endurance capacity in European men. Journal of Applied Physiology, 99(1), 344-348.

    MacArthur, D. G., & North K. N. (2004). Genes and elite athletes. Chemistry in Australia, 71 (7), 9-11.

    MacArthur, D. G., & North K. N. (2004). A gene for speed? The evolution and function of α-actinin-3. BioEssays, 26 (7), 786-795.

    MacArthur, D. G., Yang, N., Gulbin, J., & North, K. N. (2002, September). A common polymorphism in the skeletal muscle gene ACTN3 influences athletic performance. Poster session presented at the 3rd College of Health Sciences and Medical Foundation Research Conference: From Cell to Society 3, Leura, Blue Mountains, Australia.

    Mills, M., Yang, N., Weinberger, R., Vander Woude, D. L., Beggs, A. H., Esteal, S. (2001). Differential expression of the actin-binding proteins, alpha-actinin-2 and -3, in different species: implications for the evolution of functional redundancy. Human Molecular Genetics, 10(13), 1335-1346.

    Montgomery, H. E., Marshall, R., Hemingway, H., Myerson, S., Clarkson, P., Dollery, C. M., et al. (1998). Human gene for physical performance. Nature, 393, 221-222.

    Moran, C. N., Vassilopoulos, C., Tsiokanos, A., Jamurtas, A. Z., Bailey, M. E., Montgomery, H. E, et al. (2006). The associations of ACE polymorphisms with physical, physiological and skill parameters in adolescents. European Journal of Human Genetics, 14(3), 332-339.

    Moran, C. N., Yang, N., Bailey, M. E., Tsiokanos, A., Jamurtas, A., MacArthur, D. G., et al. (2007). Association analysis of the ACTN3 R577X polymorphism and complex quantitative body composition and performance phenotypes in adolescent Greeks. European Journal of Human Genetics, 15(1), 88-93.

    Myerson, S., Hemingway, H., Budget, R., Martin, J., Humphries, S., & Montgomery, H. (1999). Human angiotensin I-converting enzyme gene and endurance performance. Journal of Applied Physiology, 87, 1313-1316.

    Myerson, S. G., Montogomery, H. E., Whittingham, M.,Jubb, M., World, M. J., Humphries, S. E., & Pennell, D. J. (2001). Left Ventricular Hypertrophy with exercise and ACE gene insertion/deletion polymorphism: A randomized controlled trial with Losartan. Circulation, 103, 226-230.

    Nazarov, I. B., Woods, D. R., Montgomery, H. E., Shneider, O. V., Kazakov, V. I., Tomilin, N. V. , & Rogozkin, V. A. (2001). The angiotensin converting enzyme I/D polymorphism in Russian athletes. European journal of Human Genetics, 9(10), 797-801.

    Nicklas, B. J., Mychaleckyj, J., Kritchevsky, S., Palla, S., Lange, L. A., Lange, E. M., et al. (2005). Physical function and its response to exercise: associations with cytokine gene variation in older adults with knee osteoarthritis. The Journals of Gerontology. Series A, Biological Sciences and Medical Sciences, 60(10), 1292-1298.

    North, K. N., Yang, N., Wattanasirichaigoon, D., Mills, M., Easteal, S., & Beggs, A. H. (1999). A common nonsense mutation results in alpha-actinin-3 deficiency in the general population. Nature Genetics, 21(4), 353-354.

    Rankinen, T., Bray, M. S., Hagberg, J. M., Pérusse, L., Roth, S. M., Wolfarth, B., et al. (2006). The Human Gene Map for Performance and Health-Related Fitness Phenotypes: The 2005 Update. Medicine and Science in Sport and Exercise. 38(11), 1863-1888.

    Rigat, B., Hubert, C., Alhenc-Gelas, F., Cambien, F., Corvol, P., & Soubrier, F. (1990). An insertion/deletion polymorphism in the angiotensin I-converting enzyme gene accounting for half the variance of serum enzyme levels. The Journal of Clinical Investigation, 86(4), 1343-1346.

    Rubio, J. C., Martin, M. A., Rabadan, M., Gómez-Gallego, F., SanJuan, A. F., Alonso, J. M., et al. (2005). Frequency of the C34T mutation of the AMPD1 gene in world-class endurance athletes: does this mutation impair performance? Journal of Applied Physiology, 98(6), 2108-2112.

    Skogsberg, J., Kannisto, K., Cassel, T. N., Hamsten, A., Eriksson, P., & Ehrenborg, E. (2003). Evidence that peroxisome proliferator-activated receptor delta influences cholesterol metabolism in men. Arteriosclerosis, Thrombosis, and Vascular Biology, 23, 637-643.

    Squire, J. M. (1997). Architecture and function in the muscle sarcomere. Current Opinion in Structural Biology, 7(2), 247-257.

    Staessen, J. A., Wang, J. G., Ginocchio, G., Petrov, V., Saavedra, A. P., Soubrier, F., et al. (1997). The deletion/insertion polymorphism of the converting-enzyme and cardiovascular-renal risk. Journal of Hypertension. 15, 1479-1592

    Suminaga, R., Matsuo, M., Takeshima, Y., Nakamura, H., & Wada, H. (2000). Nonsense mutation of the alpha-actinin-3 gene is not associated with dystrophinopathy. American Journal of Medical Genetics, 92, 77-78.

    Vincent, B., De Bock, K., Ramaekers, M., VanDen, E. E., Van, L. M., Hespel, P. (2007). ACTN3 (R577X) genotype is associated with fiber type distribution. Physiological Genomics, 32(1), 58-63.

    Walsh, S., Zmuda, J. M., Cauley, J. A., Shea, P. R., Metter, E. J., Hurley, B. F., et al. (2005). Androgen receptor CAG repeat polymorphism is associated with fat-free mass in men. Journal of Applied Physiology, 98(1),132-137.

    Williams, A. G., Rayson, M. P., Jubb, M., World, M., Woods, D., Hayward, M., Martin, J., Humphries, S. E., & Montogomery, H. E. (2000). The ACE gene and muscle performance. Nature, 403, 614.

    Woods, D., Hickman, M., Jamshidi, Y., Brull, D., Vassiliou, V., Jones, A., et al. (2001). Elite swimmers and the D allele of the ACE I/D polymorphism. Human Genetics, 108, 230-232.

    Yang, N., Macarthur, D. G., Gulbin, J. P., Hahn, A. G., Geggs, A. H., Easteal, S., et al. (2003). ACTN3 genotype is associated with human elite athletic performance. The American Journal of Human Genetics, 73(3), 627-631.

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