草蝦基因組的遺傳分析:種源鑑定及遺傳圖譜之建立

En-Min You; 尤恩民

Please use this identifier to cite or link to this item: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/37183

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???org.dspace.app.webui.jsptag.ItemTag.dcfield???	Value	Language
dc.contributor.advisor	于宏燦(Hon-Tsen Yu)
dc.contributor.author	En-Min You	en
dc.contributor.author	尤恩民	zh_TW
dc.date.accessioned	2021-06-13T15:20:49Z	-
dc.date.available	2008-08-05
dc.date.copyright	2008-08-05
dc.date.issued	2008
dc.date.submitted	2008-07-22
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/37183	-
dc.description.abstract	草蝦(Penaeus monodon)是全球養殖產業中最重要的海產物種之一，也是具有生物多樣性研究價值的海洋生物。因此，本研究利用分子遺傳標記去研究草蝦基因組的特性，包括兩個大主題: (1)草蝦地理族群的遺傳多樣性與種源分析。(2)草蝦遺傳圖譜的建構。本論文共分為四章，第一章包括研究主題之文獻回顧，與研究方法的論述，並論文的研究方向。論文的第二章，為利用分子遺傳標記進行野生草蝦族群遺傳多樣性的研究成果，此部分已發表於Animal Genetics期刊中。論文的第三章則為草蝦遺傳圖譜建構之研究成果。論文的第四章則為本研究的總結論與未來的展望。論文的第一個主題-草蝦地理族群遺傳與種源分析的研究(論文第二章)，是使用來自於8個不同地理區域，一共355隻野生草蝦作為實驗樣本，以自行開發的10個微隨體標記及粒線體控制區(mtCR)序列，來分析草蝦族群與個體的遺傳分化情形。結果顯示，不論是使用微隨體標記或粒線體控制區(mtCR)序列進行地理親緣關係分析，均得到相同的結論，即西印度洋(馬達加斯加及肯亞)與西太平洋(台灣、越南、菲律賓、澳洲及泰國東岸泰國灣)的草蝦族群在遺傳上已有明顯分隔。此項研究結果對於草蝦養殖產業的種源鑑定應大有助益。論文的第二個主題-草蝦遺傳圖譜的建構(論文第三章)，是利用多型性微隨體標記，輔以多型性AFLP標記，以一個isofemale F1家族(內含280個子代個體)為樣本，共使用148個草蝦微隨體標記以及134個AFLP標記，進行基因型分析及連鎖分析，建構出草蝦雌性及雄性遺傳圖譜。雌性遺傳圖譜含128個微隨體標記及55個AFLP標記，並組成了46個連鎖群，而連鎖群的總遺傳長度是2248.9 cM；雄性遺傳圖譜含126個微隨體標記及79個AFLP標記，並組成了43個連鎖群，而連鎖群的總遺傳長度是2286.8 cM。這兩個遺傳圖譜共同擁有106個標記，並座落於36個同源連鎖群(homologous linkage group)。此遺傳圖譜將能應用於數量性狀基因座(quantitative trait loci; QTL]的定位與分子育種選殖。	zh_TW
dc.description.abstract	The black tiger shrimp (Penaeus monodon) is an ecologically and economically important marine crustacean and is widely distributed in the Indo-Pacific region. Here I investigated the genome of P. monodon in two aspects, i.e., (1) the genetic diversity of wild populations, (2) the construction of a genetic linkage map. There are 4 chapters in this thesis. Chapter 1 contained the paper review of the research topics, the research methods, and the research aspects. In chapter 2 the genetic diversity and the stock identification of wild P. monodon populations in Indo-Pacific region was revealed, and this part of work has been published in Animal Genetics. In chapter 3 the constructed linkage maps of the tiger shrimp based on microsatellites and AFLP markers were presented. Chapter 4, the final chapter, was concerned with the research summary and future perspectives. In order to investigate the genetic diversity of wild P. monodon populations, tiger shrimps (n = 355) from eight geographical regions were genotyped using of 10 microsatellite markers. A high level of genetic variability (average HO: 0.638-0.743) and significant genetic differentiation (Pairwise FST and RST values) among the populations were revealed. The non-metric multidimensional scaling analysis indicated the presence of three geographic groups in the Indo-Pacific region, i.e., the African populations, a population from western Thailand, and the remaining populations as a whole. In addition, the phylogenetic analysis using the sequences from the mitochondrial control region (mtCR) revealed that the West Indian Ocean populations were genetically differentiated from the West Pacific populations, consistent with the result obtained from the microsatellite data. In order to acquire more genetic information of tiger shrimp genome, the linkage maps of male and female tiger shrimp (P. monodon) were constructed based on microsatellite and amplified fragment length polymorphism (AFLP) markers. 621 microsatellite and 1151 AFLP markers were tested for polymorphism. Consequently, 372 (167 microsatellite and 203 AFLP markers) were used for genotyping an isofemale F1 family comprising two parents and 280 progeny. From the linkage analysis (LOD score= 4.5), a male and a female linkage map consisting of 43 and 46 linkage groups were constructed, respectively. The male map consisted of 126 microsatellite markers and 79 AFLP markers, whereas the female map consisted of 128 microsatellite markers and 55 AFLP markers. These two maps shared 36 homologous linkage groups.	en
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dc.description.tableofcontents	目錄論文口試委員審定書………………………………………i 誌謝…………………………………………………………ii 中文摘要……………………………………………………iii 英文摘要……………………………………………………iv 第一章文獻回顧、研究原理與方法………………………1 1.1 DNA遺傳標記在養殖業上的應用………………………1 1.1.1 DNA遺傳標記記………………………………………1 1.1.2 DNA遺傳標記在養殖業上的應用……………………3 1.2以DNA遺傳標記建立草蝦遺傳圖譜之方法論……………5 1.2.1 STR基因型分析………………………………………5 1.2.1.1標記多型性測試……………………………………5 1.2.1.2 標記分離率偏離測試………………………………7 1.2.2 AFLP基因型分析………………………………………7 1.2.2.1 AFLP基因型判讀方式.……………………………7 1.2.2.2 標記分離率偏離測試.……………………………7 1.2.3 AFLP基因型屬於相似長度卻無關聯的問題與改進…8 1.2.4 草蝦遺傳連鎖圖譜的建立………9 1.2.4.1 草蝦遺傳圖譜的建立所需的F1樣本數……………9 1.2.4.2 標記連鎖及關聯性分析方法……………13 1.2.4.3 雙基因座分析………………………………………13 1.2.4.4 連鎖標記之分群……………………………………14 1.2.4.5 各連鎖群內基因座排列順序分析…………………14 1.2.4.6 Mapping function的使用…………………………15 1.2.4.7 JoinMap® 4軟體的使用……………………………15 1.2.5 計算遺傳圖譜的總長度及包含範圍…………………16 1.2.6 草蝦遺傳圖譜的重組研究……………………………16 1.3 研究方向…………………………………………………16 1.4 論文結構…………………………………………………19 第二章印度洋及太平洋地區草蝦族群的遺傳分化………21 第三章草蝦之遺傳圖譜……………………………………33 第四章研究總結與未來展望………………………………54 參考文獻………………………………………………………55 附錄一、草蝦遺傳圖譜中部分STR基因型原始資料…………63 附錄二、草蝦遺傳圖譜中部分AFLP基因型原始資料………64 圖一、AFLP實驗流程圖。……………………………………2 圖二、在不同的樣本數及預期分離率的條件下，挑選多型性基因座所獲得的統計power……………………………………………6 圖三、重組率與所需F1子代樣本數的關係圖 (A1A2B1B2 X A1A2B1B2)……………………………………11 圖四、重組率與所需F1子代樣本數的關係圖 (A1A2B1B2 X A3A4B3B4)……………………………12 表一、比較幾種製備DNA遺傳標記的DNA遺傳技術…………2 表二、本實驗中AFLP應用於建立遺傳圖譜的基因型組合…8 表三、設親代雙方在此兩基因座的基因型為AaBb X AaBb，則F1子代的基因型、出現頻率的觀察值及期望值之列表 …………………………………………………………10 表四、過去草蝦遺傳圖譜研究的成果………………………18
dc.language.iso	zh-TW
dc.subject	粒線體控制區序列	zh_TW
dc.subject	草蝦	zh_TW
dc.subject	微隨體	zh_TW
dc.subject	遺傳多樣性	zh_TW
dc.subject	遺傳圖譜	zh_TW
dc.subject	AFLP	zh_TW
dc.subject	isofemale F1家族	zh_TW
dc.subject	同源連鎖群	zh_TW
dc.subject	linkage map	en
dc.subject	isofemale F1 family	en
dc.subject	amplified fragment length polymorphism (AFLP)	en
dc.subject	Penaeus monodon	en
dc.subject	microsatellite	en
dc.subject	mitochondrial control region	en
dc.subject	genetic diversity	en
dc.subject	homologous linkage groups	en
dc.title	草蝦基因組的遺傳分析:種源鑑定及遺傳圖譜之建立	zh_TW
dc.title	Genetic analysis of tiger shrimp genome: stock identification and construction of genetic linkage map	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	陳昭倫(Chao-lun Chen),李壽先(Shou-Hsien Li),陳凱儀(Kai-Yi Chen),黃曉薇(Shiau-Wei Huang)
dc.subject.keyword	草蝦,微隨體,粒線體控制區序列,遺傳多樣性,遺傳圖譜,AFLP,isofemale F1家族,同源連鎖群,	zh_TW
dc.subject.keyword	Penaeus monodon,microsatellite,mitochondrial control region,genetic diversity,linkage map,amplified fragment length polymorphism (AFLP),isofemale F1 family,homologous linkage groups,	en
dc.relation.page	62
dc.rights.note	有償授權
dc.date.accepted	2008-07-23
dc.contributor.author-college	生命科學院	zh_TW
dc.contributor.author-dept	動物學研究所	zh_TW
Appears in Collections:	動物學研究所

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