新的果蠅基因taroid在Hedgehog資訊傳遞的發育遺傳分析

王佑群

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DC 欄位	值	語言
dc.contributor.author	王佑群	zh_TW
dc.date.accessioned	2021-07-01T08:20:57Z	-
dc.date.available	2021-07-01T08:20:57Z	-
dc.date.issued	1998
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/76384	-
dc.description.abstract	Hedgehog（Hh）蛋白質是一種分泌性的傳訊分子，在脊椎或無脊椎動物的發育及體制形成上扮演著極為重要的角色。果蠅（Drosophila melanogaster）的hh突變體會導致胚胎腹部體節的方向極性受損，形成所謂的「節向性狀」（segment polarity phenotype），而已知的節向基因多為Wingless（Wg）或Hh資訊傳遞系統的成員。本論文報導了一個新的果蠅基因taroid(tr)的遺傳分析以及其發育功能的探討。此新基因乃篩選自221株以EMS引致突變的致死突變株，透過種細胞遺傳重組技術（the FLP-DFS technique）分析發現，缺少tr基因的母源成分的tr突變胚胎呈現出所謂的lawn-of-denticles節向性狀。在tr突變胚胎中，分別偵測Wg信息的標的engrailed(en)與Hh信息的標的wg在表皮細胞的蛋白質表現，得知Wg的分解消失比En來的早，顯示Hh資訊傳遞需要在tr的功能正常時才能進行。進一步分析tr對過量表現的Wg和Hh的遺傳上位關係（epistatic relationship），Wg異位表現的效應在tr突變胚胎中不會被抑制，反之Hh異位表現則會被tr突變所抑制，顯示tr的確作用在Hh下游而非Wg下游。然而，tr突變不會影響Hh資訊的標的基因decapentaplegic在imaginal discs上的表現，只會使眼睛分化過程中morphogenetic furrow的推進略微延遲，因此我們推測可能有重複的資訊路徑與tr的路徑平行存在，能補償缺少tr的效應。未來，我們將繼續分析tr與其他Hh傳訊成員的遺傳上位關係，同時進行tr基因的分子選殖，以確切瞭解其作用機制。本研究除了希望能探索Hh資訊傳遞路徑的未知領域，也期盼能在若干因Hh資訊失調而導致的發育不正常及癌症發生的研究中做出貢獻。	zh_TW
dc.description.abstract	The hedgehog (hh) gene family encode intercellular signaling molecules that play key roles in the pattern formation of both vertebrate and invertebrate animals. In Drosophila melanogaster, mutation of hh gene disrupts the polarity within each segment in the abdomen of embryo and is thereby belonged to the segment polarity mutation. Most of this class of mutations have been identified to play roles in either Wingless (Wg) or Hh signaling pathways. This thesis reports the recovery of a novel segment polarity gene, taroid (tr). With the efficient FLP-DFS technique, the tr1094 allele was recovered from 221 EMS-induced zygotic lethal mutations. The homozygous mutant embryos derived from tr1094 germline clones exhibited the so-called lawn-of-denticles segment polarity phenotype. Analyzing the expression of Wg and Hh target genes, Engrailed (En) and Wg, respectively, in epidermal cells of tr mutant embryos, the decay of Wg protein is earlier and more severely than that of En protein. It suggests it is more likely the requirement of tr in Hh signaling that targeted Wg expression. The epistatic interaction of tr mutant to overexpressed Wg and Hh consistently suggests that tr acts downstream of Hh but not of Wg. The effect of ectopically expressed Wg can be seen in tr null embryos while that of ectopically expressed Hh cannot. However, hh-dependent Dpp expression on imaginal discs is not affected in cells lacking tr function while the morphogenetic furrow progression of eye discs in these tr mutant cells is slightly retarded. The existence of parallel pathways that may compensate the tr function is thus hypothesized. Further investigation will focus on the verification of the epistatic relationship between tr and other known components in the Hh signaling and the molecular characterization of products encoded by the tr gene. The study of tr is intended not only to increase our realization of Hh signaling pathway but also to improve our knowledge in the mechanism of certain developmental disorders and human cancers that were recently indicated to be caused by the disruption of Hh signaling.	en
dc.description.provenance	Made available in DSpace on 2021-07-01T08:20:57Z (GMT). No. of bitstreams: 0 Previous issue date: 1998	en
dc.description.tableofcontents	List of Tables IV List of Figures V Introduction 1 Antero-posterior axis determination 1 The segment polarity genes 2 Wg signaling 4 Hh signaling 6 Finding out new genes -- taroid 8 Materials & Methods 11 Fly stocks and maintenance 11 Heat shock treatment 11 Genetic screening 11 A. Isolation of lethal mutations on the third chromosome B. The autosomal FLP-DFS technique C. Test of the maternal effects of lethal mutations Cuticular preparation 13 Mapping taroid locus 13 A. Deficiency mapping B. Meiotic mapping Mis-expression experiment 14 A. GAL4-UAS system B. hsGAL4 as driver C. hGAL4IJ3 as driver Generation of recombinant clones in somatic tissue 15 A. mini-w+ as the marker to detect recombinant clones in adult eyes B. π M as the marker and Dpp-LacZ as the reporter in imaginal discs Immunohistochemistry 16 A. Conventional immuno-staining in embryos B. Double immuno-fluorescent staining in discs Local transposition 17 Plasmid rescue 18 Results 20 221 EMS-induced zygotic lethals were analyzed for their GLC phenotypes 20 taroid is a new mutation exhibiting lawn-of-denticles phenotype 22 The segment polarity phenotype of taroid gene 23 taroid acts in Hh signaling pathway 25 Homozygous tr clones in imaginal discs do not affect the hh-dependent Dpp expression and the normal patterning 26 New mutations created by local transposition are not P-inserted alleles of tr locus verified by genetic characterization and plasmid rescue 28 Discussion 30 Screening with the FLP-DFS technique 30 taroid is a novel gene in Hh signaling 31 taroid activity may be redundant to parallel pathways for imaginal discs development 33 Future prospects 34 Acknowledgments 37 References 38
dc.language.iso	zh-TW
dc.title	新的果蠅基因taroid在Hedgehog資訊傳遞的發育遺傳分析	zh_TW
dc.title	Developmental Genetics Characterization of a Novel Drosophila gene, taroid, in Hedgehog Signaling	en
dc.date.schoolyear	86-2
dc.description.degree	碩士
dc.relation.page	84
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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