松果腺激素（MELATONIN）對大花鼠睪丸類固醇激素生成之調控：分子作用機制之離體研究

Jyun-Wen Wang; 王俊文

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完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.author	Jyun-Wen Wang	en
dc.contributor.author	王俊文	zh_TW
dc.date.accessioned	2021-07-01T08:14:28Z	-
dc.date.available	2021-07-01T08:14:28Z	-
dc.date.issued	1988
dc.identifier.citation	王錫五，張維新，余玉林（1984）助孕素抗體之製備．中華民國內分泌暨糖尿病學會，第二屆第二次會員大會暨學術演講會．臺北．李匡正，陳新淦，馬孟大，楊台基（1986）密宗．靜坐．瑜伽，第七版，中國瑜伽出版社．臺北．宋麗娟（1985）脊椎動物促濾泡激素生成活性之比較--離體大白鼠生精細管環單磷酸腺?之生成．國立台灣大學動物學研究所碩士論文．林孜平（1984）松果腺激素（Melatonin）對鼠類睪丸雄性素生成之影響．國立台灣大學動物學研究所碩士論文． Abe, K., G.A. Robison, G.W. Liddle, R.W. Butcher, W.E. Nicholson, C.E. Baird (1969) Role of cyclic AMP in mediating the effect of MSH, norepinephrine and melatonin on frog skin color. Endocrinology 85, 674. Ashman, D.F., R.Lipton, M.M. Melicow and T.D. Price (1963) Isolation of adenosine 3', 5'-monophosphate and guanosine 3', 5'-monophosphate from rat urine. Biochem. Biophys. Res. Commun. 11, 330. Bailey, C.J., T.W. Atkins and A.J. Matty (1974) Melatonin inhibition of insulin secretion in the rat and mouse. Horm. Res. 5, 21. Balment, R.J. and B. Lahlou (1987) Atrial natriuretic peptide (ANP) modulation of second messenger activity in isolated trout gill cells. J. Endocrinol. Suppl. 115, 164. Baschieri, L., F. De Luca, L. Cramarossa, C. 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(1972) Effects of pinealectomy, constant light and darkness on growth hormone in the pituitary and plasma of the rat. J. Endocrinol. 53, 289. Relkin, R (1983) The Pineal Gland. pp82-89 Elsevier Biomedical. New York, Amsterdam and Oxford. Rudman, D. (1976) Injection of melatonin into cisterna magna increases concentration of 3', 5'-cyclic guanosine monophosphate in cerebrospinal fluid. Neuroendocrinology 20, 235. Schulster, D. and A. Levitzki (1980) Cellular Receptors. pp353-367 John Wiley & Sons. Chichester, New York, Brisbane and Toronto. Schwartz, L.M. and J.W. Truman (1984) Cyclic GMP may serve as a second messenger in peptide-induced muscle degeneration in an insect. Proc. Natl. Acad. Sci. 81, 6718. Singh, D.V., G.D. Narang and C.W. Turner (1969) Effect of melatonin and its withdrawal on thyroid hormone secretion rate of female rats. J. Endocrinol. 43, 489. Smith, J.B. and T.M. Lincoln (1987) Angiotensin decreases cyclic GMP accumulation produced by atrial natriuretic factor. Am. 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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/75656	-
dc.description.abstract	松果腺激素（melatonin）主要為松果腺所分泌，具有抑制生殖之作用；早期實驗證明其可直接抑制睪丸助孕素與睪固酮之間的轉化，使睪固酮之生成減少，而增加助孕素的產量。同時，許多實驗證明，melatonin能引發多種組織產生c G.MP （guanosine 3′, 5′-monophosphate）。雖然也有少數證據顯示c GMP能產生類似melatonin之作用，但迄今仍無證據明確指出二者之相關性，甚至尚無以c GMP為second messenger之報告出現。本研究之目的即嘗試證明melatonin是否經由環核?酸作為second messenger，以進一步探討其分子作用方式。實驗動物為八週齡雄性大花鼠（Long Evans rats）；以酵素分離法取得睪丸精間細胞，作離體培養（Medium 199, pH7.4, 34℃培養4小時，每分鐘震盪90次）。培養液中加入不同劑量之促黃體生成激素（LH）促進睪固酮生成，並加以melatonin, c AMP, c GMP, 2′, 3′-c GMP, c IMP, c UMP, c C M P以及細胞c G M P生成之促進劑或抑制劑。以放射免疫分析法定量所產生的睪固酮、助孕素及c GMP，而以競爭性蛋白質結合分析法定量c AMP及c GMP。研究結果簡述如下：）在所有測試的環核?酸中，只有c GMP能模擬melatonin之作用，其他則稍有或幾無作用。而且，二者不僅定性上作用型式相同，定量上其抑制L H及c AMP（L H之second messenger）所引發睪固酮生成及增加助孕素產量之幅度亦極為近似；2）Sodium nitroprusside（細胞c GMP生成促進劑）同樣也顯著降低睪固酮之產量，而增加助孕素之分泌；3）在已知一些c GMP生成之抑制劑（methyl paraben, 3′-GMP , cystamine, dithioerythritol, mycophenolic acid及methylene blue）當中，尚無法找到能拮抗melatonin之作用者，因此有待進一步之研究；4）以放射免疫分析法或競爭性蛋白質結合分析法定量c GMP及c AMP，證明melatonin確實也能促進c GMP之產生，但不影響L H所引發c AMP之生成。綜合以上結果，充分顯示c G M P很可能是melatonin的second messenger，或者至少是melatonin作用機制中一重要之介體（mediator）。此一發現，當有助於吾人對melatonin之分子作用方式作更進一步的瞭解；同時，藉由melatonin之調控作用，也將為性腺類固醇激素生成機制之探討提供一個嶄新的研究方向。	zh_TW
dc.description.abstract	Melatonin, the major hormone secreted from pineal gland, has long been recognized to be antigonadotrophic. Early studies have proved that it inhibits the biotransformation from progesterone to testosterone, resulting in the reduction of testosterone production and the elevation of progesterone secretion. Melatonin has also been proved to be able to stimulate the formation of guanosine 3', 5'-monophosphate (cyclic GMP) in a variety of tissues. Albeit some evidences have also shown that cyclic GMP partially mimics the action of melatonin, no one has, so far, clearly pointed out the interrelations between the two biomolecules. The study was thus directed to prove whether the modulatory effect of melatonin on testicular steroidogenesis is mediated through the formation of such cyclic nucleotide, or more strictly, whether cyclic GMP is the second messenger of melatonin. Testicular interstitial cells, obtained by collagenase dispersion from 8-wk-old male Long Evans rats, were incubated in medium 199 (pH 7.4 , 34℃) with additions of ovine LH, melatonin, cyclic nucleotides, and certain stimulators or inhibitors of cyclic GMP generating system in the cell. After 4h of incubation, testosterone and progesterone were measured by radioimmunoassays (RIA's) while cyclic AMP was measured by the competitive protein binding assay (CPB assay). Cyclic GMP was quantified by both RIA and CPB assay. The results are summarized as follows: 1). among all the cyclic nucleotides tested, cyclic GMP was the only one that could mimic the action of melatonin, while the others had little or no effect. Besides, the mimicry was not only qualitative, but also quantitative. Therefore, cyclic GMP completely mimics the action of melatonin in rat testicular steroidogenesis by inhibiting testosterone formation and promoting progesterone secretion; 2). sodium nitroprusside, a chemical that directly stimulates guanylate cyclase and thus promotes mass production of cyclic GMP, also blocked the conversion from progesterone to testosterone; 3). among those inhibitors of cyclic GMP generating system in the cell (eg. methyl paraben, cystamine, 3'-GMP, dithioerythritol, mycophenolic acid, methylene blue), no one was found to antagonize the action of melatonin. Further investigations are therefore required to elucidate this phenomenon; 4). no matter whether with or without the stimulation of exogenous LH, melatonin stimulated cyclic GMP production by rat testicular interstitial cells and did not affect cyclic AMP formation. In conclusion, the results from the present study strongly imply that cyclic GMP is the second messenger or one of the mediators of the action of melatonin. Such a finding, therefore, helps better understand the molecular mechanism of melatonin. From the study of the modulatory action of melatonin and the inhibitory effect of cyclic GMP, it will also lead us to a new domain in the research of testicular steroidogenesis. Furthermore, the mode of action of melatonin by producing cyclic GMP as its mediator may not only be limited to the testis, but also a universal pattern in all other endocrine organs.	en
dc.description.provenance	Made available in DSpace on 2021-07-01T08:14:28Z (GMT). No. of bitstreams: 0 Previous issue date: 1988	en
dc.description.tableofcontents	圖表目錄………………………IV 誌謝………………………1 中文摘要………………………3 緒言………………………6 材料與方法………………………14 一、實驗材料………………………14 (一)實驗動物………………………14 (二)藥品………………………14 二、實驗方法………………………19 (一)大花鼠睪丸精間細胞之分離與培養………………………19 (二)類固醇激素之測定………………………22 (三)環核?酸之測定………………………24 結果………………………31 一、Melatonin與cyclic GMP對大花鼠睪丸精間細胞類固醇激素生成影響之比較研究………………………31 (一)Cyclic GMP對LH所引發睪固酮及助孕素生成之影響………………………31 (二)Cyclic GMP對cyclic AMP所引發睪固酮及助孕素生成之影響………………………32 (三)Cyclic GMP對大花鼠睪丸精間細胞睪固酮生成與分泌之影響………………………32 (四)Melatonin與cyclic GMP對LH所引發睪固酮及助孕素生成影響之比較………………………33 二、他種環核?酸對大花鼠睪丸精間細胞睪固酮生成之影響………………………35 三、細胞cyclic GMP生成促進劑對大花鼠睪丸精間細胞睪固酮及助孕素生成之影響………………………35 四、Melatonin對大花鼠睪丸精間細胞cyclic GMP與cyclic AMP生成之影響………………………36 (一)Cyclic GMP競爭性蛋白質結合分析法之建立………………………36 (二)Melatonin對睪丸精間細胞cyclic GMP與cyclic AMP生成之影響………………………38 討論………………………39 一、Melatonin與cyclic GMP作用方式之比較………………………39 二、Cyclic GMP與他種環核?酸作用之比較………………………42 三、Melatonin與細胞cyclic GMP生成促進劑作用之比較………………………43 四、Melatonin與細胞cyclic GMP生成抑制劑作用之比較………………………45 五、Melatonin對大花鼠睪丸精間細胞cyclic GMP生成之影響………………………50 六、Melatonin對大花鼠睪丸精間細胞cyclic AMP生成之影響………………………52 七、假說之提出………………………53 結論………………………55 引用文獻………………………57 英文摘要………………………120 著作一覽表………………………123
dc.language.iso	zh-TW
dc.title	松果腺激素（MELATONIN）對大花鼠睪丸類固醇激素生成之調控：分子作用機制之離體研究	zh_TW
dc.title	MODULATION OF MELATONIN ON RAT TESTICULAR STEROIDOGENESIS： AN IN VITRO STUDY OF ITS MOLECULAR MECHANISM	en
dc.date.schoolyear	76-2
dc.description.degree	碩士
dc.relation.page	123
dc.rights.note	未授權
dc.contributor.author-dept	生命科學院	zh_TW
dc.contributor.author-dept	動物學研究所	zh_TW
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