臺灣博碩士論文加值系統

本實驗利用二組引子以聚合酶連鎖反應的方法，能同時檢出
ZmaR及Zwit這兩個基因，且能有效率的自本土蘇力菌株篩選出能產生
雙效菌素A的菌株，在25株本土蘇力菌的篩選中，找到一株具有最高抑
菌活性的菌株D1-10a，能抑制黃色微球菌（Micrococcus luteus BCRC
10449）、胡蘿蔔軟腐桿菌（Erwinia carotovora BCRC 12613）、蘭花鐮
胞菌（Fusarium solani）、甜椒疫病菌（Phytophthora capsici）、柑桔疫
病菌（Phytophthora citricola）、薑軟腐病菌（Pythium myriotylum）。在
培養時加入鐵離子能提高其抑菌活性。利用離子交換樹脂純化後的菌
液上清液，具抑制軟腐病菌菌絲生長能力。純化後產物利用高效液相
層析儀分析的結果，可在6.5到7.5分鐘間獲得一個單一的清楚高峰，此
物質的分子量約在387.1 Da，與仙人掌桿菌UW85所產生的雙效菌素A
類似，而這個雙效菌素A的類似物亦有抑制薑軟腐病菌之游走子發芽管
萌發的效果，本研究為台灣針對雙效菌素A的首次報告。

Using polymerase chain reaction (PCR) with two pairs of
oligonucleotide primers to detect both ZmaR and Zwit genes. In this study,
we were able to efficiently screen the local Bacillus thuringiensis (B.t)
isolates that produced zwittermicin A. Of the 25 B.t isolates tested, B.t
D1-10a exhibited the highest antifungal activity which can inhibit the
growth of Micrococcus luteus、Fusarium solani、Phytophthora capsici、
Phytophthora Citricola、Pythium myriotylum.Antifungal activity can be
enhanced by the addition of ferric ion to trypticase soy broth. And the
cation-exchange hromatography (Amberliter IRC-50) purified supernatant
of broth still showed inhibition against the mycelial growth (from
zoospores) of Pythium myriotylum.The antibiotic substances were further
purified by reverse　phase C18 HPLC. A single peak was eluted at 6.5 to
7.5 minutes from HPLC. The antibiotic substances from HPLC were
identified by LC-TOF MS. The molecular weight of this compound was
determined to be approximately 387.1 Da, that was similar to the
confirmed zwittermicin A producted by B.cereus UW85. In this study, the
purified zwittermicin A-like compound can also inhibit the germination of
P. myriotylum zoospores.

中文摘要……………………………………………………………………...….……....I
英文摘要......…………………………......………………………….........................….II
致謝................................................................................................................................ III
目錄......…………………………......…………………………................................….IV
圖表目錄......…………………………......……………………................................….VI
第一章、前言 ……………………………………………………………….....…....…1
第二章、文獻回顧...........................................................................................................3
第三章、材料與方法...................................................................................................13
3-1、實驗材料與藥品..……..…..………..………………………………...13
3-2、基因體DNA (Genomic DNA)的製備………………..………………....…18
3-3、洋菜膠膠體電泳分析 (Agarose gel electrophoresis)…….………..........19
3-4、聚合酶連鎖反應 (Polymerase chain reation, PCR) ………………..…...….19
3-5、DNA片段之回收…………...…………………….………...………..……21
3-6、NCBI BLAST序列比對………….…………..….….…………..…………….21
3-7、篩選本土蘇力菌對病原細菌真菌之對峙試驗............................................22
3-8、不同培養天數之蘇力菌過濾上清液對峙病原真菌試驗……..…..…………23
3-9、加入FeCl3培養之蘇力菌上清液對峙病原真菌試驗………….….….....…24
3-10、初步分離純化抗生物質.……………………...………….....………............24
3-11、初步以陽離子交換樹酯純化抗生物質……………………….……………...25
3-12、薄層色層分析法（Thin Layer Chromatography）………...…………….....…..26
3-13、簡易固相萃取管柱進行HPLC 樣品的前處理………………….……..……27
3-14、HPLC分析初步純化物質……....………….....………....................................27
　3-15、LC-TOF MS分析...............................................................................................28
第四章、結果...................................................................................................................29
4-1、PCR篩選具雙效菌素A抗性基因之蘇力菌菌株…………………..…….…...29
4-2、PCR篩選具雙效菌素A合成基因之蘇力菌菌株..............……….....………...29
4-3、NCBI BLAST 比對結果…………...……….……………………......………...30
4-4、雙重PCR（Duplex PCR）篩選…...........………………………..............……….31
4-5、本土蘇力菌拮抗病原細菌對峙試驗...……………………………………….32
4-6、本土蘇力菌拮抗病原真菌對峙試驗………………….………………..……...33
4-7、培養天數對抑制病原真菌菌絲生長的差異..………..………………..……..34
4-8、離子交換層析法初步純化菌液上清液...........…………………..……..……...35
4-9、薄層層析法鑑定純化條件…………………………………………….……….36
4-10、HPLC的樣品前處理－簡易固相萃取管柱純化…………………………….37
4-11、HPLC初步純化後之抗生物質.………………………………………………37
4-12、LC/TOF-MS的分子量測定……………………………………..…………….38
第五章、討論…………..................………………………………………..…………...39
第六章、結論…………..................………………………………………..…………...48
第七章、參考文獻…………..................………………..……………………………...50
圖表集………….....................……………………………..………….………….........59
圖.1. The structure of (A)Zwittermicin A and (B) Kanosamine………………….…….59
圖.2. PCR of 25 Bacillus thuringiensis strains and Bacillus cereus UW85
with one pair of zmaR primers.…………................................................………...60
圖.3. PCR of 25 Bacillus thuringiensis strains and Bacillus cereus UW85
with one pair of Zwit primers..............................…………………….…………...61
圖.4. Duplex PCR of 25 Bacillus thuringiensis strains and a Bacillus cereus UW85
using two zmaR and two Zwit primers...………………………………...................62
圖.5. Growth inhibition of Micrococcus luteus BCRC10449...........................................63
圖.6. Growth inhibition of the Bacillus thuringiensis D1-10a against 4 fungi..…..64
圖.7. Growth inhibition of the Bacillus cereus UW85 against against 3 fungi.………....65
圖.8. Time course of growth inhibition against Pythium myriotylum zoospores grown
on PDA plates by the of culture filtrate of Bacillus thuringiensis D1-10a…..……..66
圖.9. Time course of growth inhibition against Pythium myriotylum zoospores grown
on PDA plates by the culture filtrate of Bacillus thuringiensisD1-10a added with 5mM FeCl3………………………………………………………………………....67
圖.10. Growth inhibition of Pythium myriotylum zoospores on PDA plates
by the elutent from Bacillus cereus UW85…..………..…………………..….…...68
圖.11. Growth inhibition of Pythium myriotylum zoospores on PDA plates by
the elutent from Bacillus thuringiensis D1-10a……………………….…………..69
圖.12. Antibiotic produced by Bacillus cereus UW85 and TLC plate was visualized under UV 254 nm light……………………………………………..……..….…...70
圖.13. Antibiotic produced by Bacillus thuringiensis D1-10a and TLC plate was visualized under UV 254 nm light……………………..…………………....…...71
圖.14. Growth inhibition of Pythium myriotylum zoospores on PDA plates by
Bacillus thuringiensis D1-10a products with different eluted solutions...............72
圖.15. HPLC analysis of ZwA produced by Bacillus thuringiensis D1-10a…..…...…....73
圖.16. Growth inhibition of Pythium myriotylum zoospores on PDA plates
by Bacillus thuringiensis D1-10a with the fraction collected from 6.5 to 7.5
mins. in HPLC anaylsis…………….....................................................................74
圖.17. The LC-TOF MS of the fraction purified from 6.5 to 7.5 min.in HPLC anaylsis……………………………………………….…………………...……..75
表.1A Characteristics of ZmaR primers used……..……………………..............….…...76
表.1B Characteristics of Zwit primers used…….….……………………..…….……….76
表.2. Antibacterial activities of Bacillus thurigiensis strains and Bacillus cereus
UW85 against 2 bacteria…….……………………………………………….…….77
表.3. Antifungal activities of Bacillus thurigiensis strains and Bacillus cereus
UW85 against 4 fungi.………………………..…………...…..…..……………....79
表.4. PCR analysis of Bacillus cereus and Bacillus thurigiensis isotates…………...…..81

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