探討光照對Rhizopus oligosporus轉換豆漿中異黃酮醣苷之影響

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楊佳叡(Chia-Jui Yang) 查詢紙本館藏

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化學工程與材料工程學系

論文名稱

探討光照對Rhizopus oligosporus轉換豆漿中異黃酮醣苷之影響
(Effect of light condition on bioconversion of isoflavone glycosides in soymilk by Rhizopus oligosporus)

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摘要(中)

苷元型異黃酮(isoflavone aglycones)因具有降低心血管疾病、預防骨質疏鬆、抗腫瘤、改善肥胖症等特性，因此被廣泛地討論。本實驗利用微生物發酵法，以豆漿取代傳統大豆作為基質，透過Rhizopus oligosporus將醣苷型異黃酮(isoflavone glucosides)轉化成苷元型異黃酮(isoflavone aglycones)。而在微生物發酵中，不同光源也會影響微生物的生理狀態和發酵行為，因此本研究主要的目的是在於探討「光照」環境因子對於Rhizopus oligosporus生產苷元型異黃酮之影響，探討不同光源以及不同光照度對於菌體的生長及產物的變化。

本研究結果顯示在光照的條件下，紅光200 lux最有利於Rhizopus oligosporus的菌體生長，能將菌體重量提升至避光組的1.38倍，而在藍光100 lux的情況下，則有最佳的單位菌重轉化產物能力，約為控制組的1.35倍。因此，本研究設計了以紅光接續藍光的兩階段光照的策略，以提升最佳的菌體重量與產物產量。在兩階段光照的條件下，大豆苷元的產量可以高達24.5 µg/ml，與單純紅光照相比及單純藍光照相比，皆提升了約26%。此外，經由兩階段光照條件下的染料木黃酮產量，可提升至20.26 µg/ml，與單純紅光照相比，提升了約15%。

摘要(英)

Isoflavone aglycones have been reported to help in the prevention of cancer, cardiovascular diseases, osteoporosis, obesity . It plays an important role in human health and has been discussed for several years. Isoflavone aglycones can be produced from isoflavone glucosides. In this work, a fermentation process with soymilk which replaces traditional soybean as substrate has been performed. Besides, different light conditions will also has a strong connection with microbial growth and fermentation behavior.

In this work, we have explored the effects of light condition on bioconversion of isoflavone glucosides into isoflavone aglycones using Rhizopus oligosporus as well as develop strategies to enhance isoflavone aglycones production. Experimental results showed that at red light 200 lux condition performed the optimum cells growth, which was 38% higher than dark group. But at blue light condition, which light intensity was 100 lux, was more favorable for product yield based on biomass. It could perform 35% higher than the dark group. Therefore, two-stage shake flask fermentation by light control was conducted. Daidzein concentration using two-stage fermentation was 24.5µg/ml which corresponds to 26 % higher than single-light fermentation at red and blue light. On the other hand, Genisrein concentration using two-stage fermentation was 20.26µg/ml which corresponds to 15 % higher than single-light fermentation at red light.

關鍵字(中)

★ 異黃酮
★ 少孢根黴菌
★ 兩階段
★ 大豆苷元
★ 染料木黃酮
★ 光照

關鍵字(英)

論文目次

目錄
摘要 ii
Abstract iii
誌謝 iv
目錄 v
表目錄 viii
圖目錄 ix
第一章緒論 1
1-1研究動機 1
1-2研究目的 2
第二章文獻回顧 3
2-1大豆 3
2-2天貝 4
2-3豆漿 5
2-4大豆異黃酮 7
2-4-1異黃酮基本性質介紹 7
2-4-2異黃酮特性及應用 8
2-4-3轉換醣苷型異黃酮的β-葡萄糖苷酶(beta-glucosidase) 9
2-4-4大豆苷元(daidzein)與金雀異黃酮(genistein) 10
2-5少孢根黴(Rhizopus oligosporus)菌種介紹 13
2-6 影響發酵之因素 14
2-6-1 培養基組成 14
2-6-2 pH值 16
2-6-3 通氣速率 16
2-6-4 溫度 16
2-6-5 光 17
第三章材料與方法 23
3-1 實驗規劃 23
3-2 實驗材料與設備 24
3-2-1 實驗菌株 24
3-2-2 實驗藥品 25
3-2-3 實驗儀器與設備 26
3-2-4 數據呈現之參數符號設定 28
3-3 實驗方法 29
3-3-1 分離菌種 29
3-3-2 培養基組成 31
3-4 分析方法 32
3-4-1 液態培養菌重測定 32
3-4-2 固態培養菌重測定 33
3-4-3異黃酮分析 34
第四章實驗結果與討論 39
4-1 搖瓶實驗之避光組與紅光強度對少孢根黴菌生產大豆異黃酮發酵動力曲線影響 39
4-1-1 紅光強度對少孢根黴菌生產菌體影響 44
4-1-2 紅光強度對少孢根黴生產大豆苷元之影響 44
4-1-3 紅光強度對少孢根黴生產染料木黃酮之影響 46
4-2 搖瓶實驗之避光組與藍光強度對少孢根黴菌生產大豆異黃酮發酵動力曲線之影響 48
4-2-1藍光強度對少孢根黴生產菌體之影響 53
4-2-2藍光強度對少孢根黴生產大豆苷元之影響 53
4-2-3藍光強度對少孢根黴生產染料木黃酮之影響 55
4-3搖瓶實驗之避光組與兩階段光照對少孢根黴菌生產大豆異黃酮發酵動力曲線之影響 57
4-3-1兩階段光照對少孢根黴生產菌體之影響 58
4-3-2兩階段光照對少孢根黴生產大豆異黃酮之影響 60
4-3-3兩階段光照對少孢根黴生產染料木黃酮之影響 61
4-4固態培養與搖瓶實驗對少孢根黴菌生產大豆異黃酮發酵動力曲線之影響 63
4-4-1固態培養對少孢根黴生產菌體之影響 65
4-4-2固態培養對少孢根黴每單位黃豆所含反應物之影響 66
4-4-3固態培養對少孢根黴每單位黃豆可生成產物之影響 67
4-4-4固態培養對少孢根黴每單位菌重可生成產物之影響 68
第五章結論及建議 69
5-1 結論 69
5-2 建議 70
參考文獻 71

表目錄
表2- 1每100g大豆中所含營養成分 4
表2-2金雀異黃酮對相關疾病影響 12
表2-3工業發酵常用碳源與氮源 15
表2-4光波長影響植物發育關係 17
表2-5光接收器種類 19
表3-1 藥品清單 25
表3-2 實驗設備清單 26
表3-3 數據符號定義 28
表4-1避光與紅光照射下搖瓶發酵參數值 43
表4-2避光與藍光照射下搖瓶發酵參數值 52
表4-3避光下固態發酵與搖瓶發酵參數值 64

圖目錄
圖2-1天貝外觀 5
圖2-2各式豆漿製程 6
圖2-3異黃酮化學結構式 7
圖2-4β-葡萄糖苷酶對異黃酮醣苷的反應機制 10
圖2-5大豆苷元藥理作用 11
圖3-1實驗規劃示意圖 23
圖3-2市售天貝菌粉 24
圖3-3 Rhizopus oligosporus生長於PDA外觀 30
圖3-4搖瓶光照配置 32
圖3-5各產物之HPLC圖譜 35
圖3-6大豆醣苷標準品濃度之檢量線 36
圖3-7染料木苷標準品濃度之檢量線 36
圖3-8大豆苷元標準品濃度之檢量線 37
圖3-9染料木黃酮標準品濃度之檢量線 37
圖3-10葡萄糖胺標準品濃度檢量線 38
圖3-11菌重濃度對葡萄糖胺檢量線 38
圖4-1 Rhizopus oligosporus在避光0 lux對大豆苷元發酵曲線 39
圖4-2 Rhizopus oligosporus在避光0 lux對染料木黃酮發酵曲線 40
圖4-3 Rhizopus oligosporus在紅光100 lux對大豆苷元發酵曲線 40
圖4-4 Rhizopus oligosporus在紅光100 lux對染料木黃酮發酵曲線 41
圖4-5 Rhizopus oligosporus在紅光200 lux對大豆苷元發酵曲線 41
圖4-6 Rhizopus oligosporus在紅光200 lux對染料木黃酮發酵曲線 42
圖4-7 Rhizopus oligosporus在紅光300 lux對大豆苷元發酵曲線 42
圖4-8 Rhizopus oligosporus在紅光300 lux對染料木黃酮發酵曲線 43
圖4-9不同紅光強度對Rhizopus oligosporus最大菌重圖 44
圖4-10不同紅光強度對Rhizopus oligosporus生產最大大豆苷元圖 45
圖4-11不同紅光強度對Rhizopus oligosporus單位菌重對大豆苷元轉化率 45
圖4-12不同紅光強度對Rhizopus oligosporus生產最大染料木黃酮圖 46
圖4-13不同紅光強度對Rhizopus oligosporus單位菌重對染料木黃酮轉化率 47
圖4-14 Rhizopus oligosporus在避光0 lux對大豆苷元發酵曲線 48
圖4-15 Rhizopus oligosporus在避光0 lux對染料木黃酮發酵曲線 49
圖4-16 Rhizopus oligosporus在藍光100 lux對大豆苷元發酵曲線 49
圖4-17 Rhizopus oligosporus在藍光100 lux對染料木黃酮發酵曲線 50
圖4-18 Rhizopus oligosporus在藍光200 lux對大豆苷元發酵曲線 50
圖4-19 Rhizopus oligosporus在藍光200 lux對染料木黃酮發酵曲線 51
圖4-20 Rhizopus oligosporus在藍光300 lux對大豆苷元發酵曲線 51
圖4-21 Rhizopus oligosporus在藍光300 lux對染料木黃酮發酵曲線 52
圖4-22不同藍光強度對Rhizopus oligosporus最大菌重圖 53
圖4-23不同藍光強度對Rhizopus oligosporus生產最大大豆苷元圖 54
圖4-24不同藍光強度對Rhizopus oligosporus單位菌重對大豆苷元轉化率 54
圖4-25不同藍光強度對Rhizopus oligosporus生產最大染料木黃酮圖 55
圖4-26不同藍光強度對Rhizopus oligosporus單位菌重對染料木黃酮轉化率 56
圖4-27 Rhizopus oligosporus在兩階段光照對大豆苷元發酵曲線 57
圖4-28 Rhizopus oligosporus在兩階段光照對染料木黃酮發酵曲線 58
圖4-29兩階段光照與不同紅光強度對Rhizopus oligosporus最大菌重圖 59
圖4-30兩階段光照與不同蘭光強度對Rhizopus oligosporus最大菌重圖 59
圖4-31兩階段光照與不同紅光強度對Rhizopus oligosporus生產最大大豆苷元圖 60
圖4-32兩階段光照與不同藍光強度對Rhizopus oligosporus生產最大大豆苷元圖 61
圖4-33兩階段光照不同紅光強度對Rhizopus oligosporus生產最大染料木黃酮圖 62
圖4-34兩階段光照不同藍光強度對Rhizopus oligosporus生產最大染料木黃酮圖 62
圖4-35固態培養避光對Rhizopus oligosporus對大豆苷元發酵曲線 63
圖4-36固態培養避光對Rhizopus oligosporus對染料木黃酮發酵曲線 64
圖4-37固態培養與搖瓶培養對Rhizopus oligosporus最大菌重產率圖 65
圖4-38固態培養與搖瓶培養對Rhizopus oligosporus單位黃豆所含大豆醣苷及單位黃豆所含染料木苷圖 66
圖4-39固態培養與搖瓶培養對Rhizopus oligosporus單位黃豆可生成大豆苷元及單位黃豆可生成染料木黃酮圖 67
圖4-40固態培養與搖瓶培養對Rhizopus oligosporus單位菌重可生成大豆苷元及單位菌重可生成染料木黃酮圖 68

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指導教授

徐敬衡

審核日期

2020-1-15

推文