新立體影像技術量化萼形柱珊瑚之共棲微菌聚生體特徵

Ming-Tsung Hsu; 徐銘從

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/8080

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	湯森林(Sen-Lin Tang)
dc.contributor.author	Ming-Tsung Hsu	en
dc.contributor.author	徐銘從	zh_TW
dc.date.accessioned	2021-05-20T00:48:46Z	-
dc.date.available	2025-12-21
dc.date.available	2021-05-20T00:48:46Z	-
dc.date.copyright	2021-01-05
dc.date.issued	2020
dc.date.submitted	2020-12-21
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/8080	-
dc.description.abstract	珊瑚能在清澈卻貧瘠的海域中生長，除了倚靠共生藻提供的光合能量，還有賴各種共棲於珊瑚周遭 (體內 )的微生物，包含細菌、古菌、真菌、病毒等，綜合珊瑚自身、共生藻、共棲微生物，整個生物群體稱作珊瑚共生體 (Coral holobiont)。珊瑚共生體中關於細菌與珊瑚的互動仍未被闡明，部分的珊瑚共棲細菌常以聚生體的形式 (Coral-associated microbial aggregate, CAMA)出現在多種珊瑚的組織間， CAMA對珊瑚組織並無負面損害，且已知能組成 CAMA的內生桿菌 (Endozoicomonas)也被認為與珊瑚的健康有正相關，然而因觀察技術的限制，針對其如數量、大小等資訊都未曾被清楚地描述或比較。本實驗使用台灣墾丁與日本沖繩的萼柱珊瑚(Stylophora pistillata)，透過組織透化 (Tissue clearing)技術與螢光原位雜合連鎖反應(DNA-HCR)標定，首度以層光顯微鏡 (Lightsheet microscope)原位觀察到單一珊瑚蟲體內的 CAMA，並經由分析影像軟體 Imaris建立出的珊瑚蟲與 CAMA立體影像，獲得珊瑚蟲體內 CAMA的分布、數量、預估體積。另外，我們也在珊瑚組織切片上以 DNA-HCR和 DAPI標定 CAMA內部的細菌，透過共軛焦顯微鏡 (Confocal microscope)建構出 CAMA內部菌體的高解析度立體影像，並藉此計算出 CAMA內的平均細菌密度 (cell/μm3)。結合上述 CAMA的數量、體積、細菌密度我們將可以針對每個 CAMA、每個珊瑚蟲，甚至珊瑚群落內所含有的平均 CAMA細菌生物量進行估算。比較墾丁與沖繩的 CAMA特徵，我們發現兩樣點的 CAMA皆分布在觸手的位置，平均數量約為三個左右；而在 CAMA的平均體積和細菌密度上，墾丁樣本則顯著地高於沖繩樣本，平均每個珊瑚蟲體內的 CAMA生物量，墾丁樣本約是沖繩的三倍之多。分布和數量的相似可能表示宿主的內部調控較環境影響大；體積與密度的相異則代表著特定特徵仍受環境因子所作用，但不能排除珊瑚個體差異存在。本實驗以立體影像技術來檢視CAMA的各項特徵，使 CAMA研究不再侷限於組織切片觀察，而菌體立體影像的計數也能再做更多元的應用，希望藉由這些新穎的研究方法能為將來與 CAMA相關的實驗帶來更多不同角度的理解。	zh_TW
dc.description.abstract	Corals harbor a wide variety of microbes including symbiotic algae, bacteria, archaea, fungi, and viruses, the whole entity is named “Coral holobiont”. Inside coral holobiont, the relation between coral and their associated bacterium remain unclear. Some of the coral-associated bacteria favored to form aggregates inside coral tissue, named coral-associated microbial aggregate (CAMA). Studies have suggested that CAMA cannot be harmful to corals, and one of the CAMA forming bacteria, Endozoicomonas, is a potential probiotic bacteria candidate. However, due to the limitation on observation, few of CAMA characters were described and compared. In this study, Stylophora pistillata coral branches were collected from Kenting and Okinawa for comparative analysis. First, we conducted the first whole coral polyp fluorescence in situ hybridization chain reaction (DNA-HCR) experiment coupled with tissue clearing methods to reconstruct the three-dimensional (3D) single polyp and CAMA model by Lightsheet microscopy. The 3D model provided us the information of CAMA distribution, numbers, and volume estimation. Second, by DNA-HCR and DAPI staining to thick coral tissue sections, we rebuild the high-resolution 3D cell model inside CAMA by Confocal microscopy. By manual cell counting, we were able to quantify the cell number within a defined volume, in terms of cell density (cell/μm3). Compiling CAMA’s numbers, volume estimation, and cell density data, we can estimate the total biomass of CAMA inside a single polyp. After data analysis, we found that most CAMAs were distributed in tentacles across two sample sites with average 3 CAMAs inside each polyp. The average CAMA volume and cell density were significantly different between locations. Kenting samples had a three times greater biomass than Okinawa samples. The similarity of CAMA distribution and number indicated that regulation from host may be the major factors, however environment difference still affected some certain CAMA characters, like volume. Our study using 3D-imaging technique advances CAMA research from limited 2D observation, providing us more understanding about CAMA. Moreover, 3D cell counting can also be applied to different study fields to gain a better estimation on cell density. Further research for revealing the interaction between CAMA, coral, and environment will be facilitated by our novel experiment result.	en
dc.description.provenance	Made available in DSpace on 2021-05-20T00:48:46Z (GMT). No. of bitstreams: 1 U0001-1812202017020500.pdf: 3944969 bytes, checksum: 7405f39ce44aa4eeb7ec6587582ae35b (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	目錄論文口試委員審定書 1 謝辭 I 中文摘要 II 英文摘要 IV 目錄 VI 圖目錄 IX 表目錄 X 壹、緒論 1 1. 珊瑚與珊瑚礁生態系 1 1.1. 珊瑚與珊瑚蟲基本構造 1 1.2. 珊瑚礁的生態意義與威脅 2 2. 珊瑚共生體(Coral holobiont) 3 2.1 珊瑚共生體多樣性 3 2.2 珊瑚共棲菌分布及微棲地 4 3. 珊瑚共棲微生物聚生體(Coral-associated Microbial Aggregate, CAMA) 6 3.1 細菌聚生體(Bacterial aggregate) 6 3.2 珊瑚體內的細菌聚生體 7 4. 細菌分布與計數 9 4.1 宿主器官與細菌分布 9 4.2 細菌數目的生態意義 11 5. 研究目的 13 貳、材料與方法 15 1. 樣本採集和固定 15 2. 脫鈣處理 15 3. 全珊瑚蟲螢光原位雜合連鎖反應 (Whole polyp fluorescence in situ hybridization chain reaction, DNA-HCR) 15 3.1 組織透明化處理 17 3.2. 起始探針(Initiator probe)雜合 17 3.3. 增幅探針(Amplifier probe)雜合 18 3.4. 丙烯酰胺膠體(Acrylamide gel)包埋 19 3.5. 折射率同步(Refractive Index matching, RI matching)與DAPI染色 19 4. 層光顯微鏡(Lightsheet microscope)樣品觀察 19 5. 細菌聚生體立體影像分析 20 6. 珊瑚組織切片螢光原位雜合連鎖反應(Fluorescence in situ hybridization chain reaction, DNA-HCR) 21 6.1. 石蠟包埋與切片 21 6.2. 樣本脫蠟 21 6.3. 探針穿透處理(Probe permeabilization) 22 6.4. 起始探針雜合 22 6.5. 增幅探針雜合 22 6.6. DAPI染色和樣本封片 23 7. 共軛焦顯微鏡(Confocal microscope)切片觀察 23 8. 細菌體影像分析和計數 24 9. 統計分析 25 參、結果 26 1. 珊瑚蟲組織透化效果 26 2. 全形珊瑚蟲與珊瑚共棲菌聚生體立體影像 26 3. 珊瑚共棲細菌聚生體於單一珊瑚蟲內的分布 28 4. 珊瑚共棲細菌聚生體於單一珊瑚蟲內的數量分布 28 5. 珊瑚共棲細菌聚生體於單一珊瑚蟲內的體積 29 6. 珊瑚共棲細菌聚生體內部菌體立體影像 31 7. 珊瑚共棲細菌聚生體的細菌密度 32 肆、討論 34 1. 單一珊瑚蟲體內珊瑚共棲細菌聚生體的分布 34 2. 單一珊瑚蟲體內珊瑚共棲細菌聚生體的生物量 36 2.1. 兩採樣地點間的差異 38 2.2. 各珊瑚群落間的差異 40 3. 立體影像技術與珊瑚共棲菌聚生體 42 3.1. 組織透明化 42 3.2. 立體影像對CAMA研究 44 3.3. 立體影像對CAMA細菌計數 46 4. 珊瑚與珊瑚共棲細菌聚生體 48 伍、結論 50 陸、未來展望 51 柒、圖與表 53 捌、參考文獻 82
dc.language.iso	zh-TW
dc.title	新立體影像技術量化萼形柱珊瑚之共棲微菌聚生體特徵	zh_TW
dc.title	Quantitative characterization of the coral Stylophora pistillata-associated microbial aggregate using a newly developed technique of 3D imaging	en
dc.type	Thesis
dc.date.schoolyear	109-1
dc.description.degree	碩士
dc.contributor.coadvisor	謝志豪(Chih-hao Hsieh)
dc.contributor.oralexamcommittee	楊姍樺(Shan-Hua Yang),識名信也(Shikina Shinya),樊同雲(Tung-Yung Fan)
dc.subject.keyword	珊瑚共棲細菌,珊瑚共棲細菌聚生體,組織透化,層光顯微鏡,共軛焦顯微鏡,立體影像分析,	zh_TW
dc.subject.keyword	Coral-associated bacteria,Coral-associated microbial aggregate,Tissue clearing,Lightsheet microscope,Confocal microscope,3D image analysis,	en
dc.relation.page	99
dc.identifier.doi	10.6342/NTU202004432
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2020-12-22
dc.contributor.author-college	理學院	zh_TW
dc.contributor.author-dept	海洋研究所	zh_TW
dc.date.embargo-lift	2025-12-21	-
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