牽牛花果蠅與高山果蠅的表皮碳氫化合物組成

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：72

、訪客IP：18.225.54.85

姓名

吳翊綱(Yi-Gang Wu) 查詢紙本館藏

畢業系所

生命科學系

論文名稱

牽牛花果蠅與高山果蠅的表皮碳氫化合物組成
(Cuticular Hydrocarbon Composition of Drosophila elegans and Drosophila gunungcola)

相關論文

★ Genetic Transformation of The Green Algae Micractinium tetrahymenae by Agrobacterium Mediated transformation	★ 跳躍子flea插入let-7 complex基因座可能導致mir-100之低表現量，進而造成果蠅存活率降低和發育遲緩
★ 牽牛花果蠅和高山果蠅體型大小與環境因子和體色之間的相關性	★ 建立 Tetrahymena utriculariae 作為研究藻類-纖毛蟲共生的模型系統
★ 探討體色與翅班對於牽牛花果蠅性選擇的影響	★ 探討mir-100對於果蠅蛹期存活率的影響
★ 果蠅基因與調情—以比較基因體學解碼果蠅翅斑和翅膀展示的共同演化	★ 耐旱性對比茶樹品種干旱響應基因的差異表達模式
★ 定位影響果蠅體色的基因—sable	★ S-palmitoylation is required for meiotic entry in Schizosaccharomyces pombe
★ Comparative transcriptome analysis reveals key pathways underlying drought stress tolerance and characterizes genetic variations for selective breeding in tea plants, Camellia sinensis

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

[檢視]

[下載]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

表皮碳氫化合物（Cuticular hydrocarbon）由烷烴和烯烴組成，是昆蟲表皮的重要成分，它們保護陸生昆蟲免於乾燥，並在各種化學傳遞過程中作為訊號，果蠅在適應不同環境過程中，會演化出相應的表皮碳氫化合物。在此研究中，我分析了牽牛花果蠅（Drosophila elegans）和高山果蠅（Drosophila gunungcola）兩近緣種的表皮碳氫化合物組成，同時透過分析牽牛花果蠅自然存在的不同體色型和體色基因突變品系，了解體色與表皮碳氫化合物可能的關聯性。經由氣相層析（Gas chromatography）分析，我發現第13、23、24、25號等四種化合物為牽牛花果蠅特有，且其中後三種化合物僅出現在雄蟲表皮中。另外第7號化合物則僅在高山果蠅的雄蟲表皮中偵測到，值得一提的是，第18號化合物在牽牛花果蠅中皆可偵測到，但在高山果蠅卻單僅在雄蟲中偵測到。進一步地定量分析中，我發現不同表皮碳氫化合物普遍存在著性別差異，其中第2、4、12號化合物一致性地在兩物種顯現性別差異。當我進行同性別牽牛花果蠅兩體色型與高山果蠅碳氫化合物定量分析時，發現不論是種內或種間之比較，相對量有顯著差異的碳氫化合物種類在雄蟲皆多於雌蟲。原先帶有yellow基因突變的果蠅品系中，我發現有幾種碳氫化合物相對量與對照野生型品系不同，但是經由遺傳背景控制交配後所帶有yellow突變的果蠅，與帶有野生型等位基因的果蠅並無差異。我的研究結果顯示，表皮碳氫化合物組成在這兩近緣種存在著種內多樣性和種間分的現象，潛在性影響種內和種間的生殖隔離，雄蟲表皮碳氫化合物相對量有較多的種內和種間差異的現象，也符合fast male hypothesis。另外，不同體色型的牽牛花果蠅，其體表碳氫化合物有一定的差異，但是這些差異是否與影響體色的遺傳變異有關，則有待釐清。

摘要(英)

Cuticular hydrocarbons (CHCs), comprising alkanes and alkenes, are key components of insect cuticles. They protect terrestrial insects from desiccation and serve as signal molecules in various chemical communication processes. Fruit flies have evolved corresponding CHC profiles to adapt to different environments. In this study, I examined the CHC profiles of two closely related species, Drosophila elegans and Drosophila gunungcola, mainly focusing on the body color morphs and pigmentation gene mutant to investigate the possible association between body color and CHC profiles. According to gas chromatography analysis, I found that the number 13, 23, 24, and 25 compounds are D. elegans specific, and the last three compounds only appeared in male cuticle extracts. Conversely, the number 7 compound was only found in D. gunungcola males. More interestingly, the number 18 compound could be found in D. elegans and male D. gunungcola, but not in female D. gunungcola. Further quantitative comparisons suggested a substantial sex difference in CHC profiles. Among those differences, the number 2, 4, and 12 compounds exhibited consistent sex differences across strains and species. When the CHCs of the same sex were compared, no matter intra- or inter-specifically, the numbers of compounds exhibiting significant differences in male comparisons were higher in female comparisons. Several CHCs of the yellow mutant strain significantly differed from the wildtype counterpart in my original analysis. However, those differences diminished after the flies were undergone a cross for genetic background control. Overall, my study showed the inter-specific diversity and inter-specific diversification of CHC profiles, potentially involved in reproductive isolation, in this pair of closely related species. That more compounds exhibiting intra- and inter-specific differences in male cuticles is also consistent with the fast male hypothesis. Moreover, there are substantial differences in CHC profiles between two body color morphs of D. elegans. But whether those CHC differences are determined by the genetic variants controlling body color difference is uncertain.

關鍵字(中)

★ 牽牛花果蠅
★ 高山果蠅
★ 表皮碳氫化合物

關鍵字(英)

★ Drosophila elegans
★ Drosophila gunungcola
★ Cuticular hydrocarbon

論文目次

目次

中文摘要......i

英文摘要......ii

目次......iii

圖目次......iv

第一章緒論......1

第二章研究目的......6

第三章材料與方法......7

第四章結果......9

第五章討論......13

第六章參考文獻......15

圖......18

附錄......a

參考文獻

Bastock, M. (1956). "A gene mutation which changes a behavior pattern." Evolution 10(4): 421-439.

Billeter, J.-C. and J. D. Levine (2013). "Who is he and what is he to you? Recognition in Drosophila melanogaster." Current Opinion in Neurobiology 23(1): 17-23.

Drapeau, M. D., S. A. Cyran, M. M. Viering, P. K. Geyer and A. D. Long (2006). "A cis-regulatory sequence within the yellow locus of Drosophila melanogaster required for normal male mating success." Genetics 172(2): 1009-1030.

Drapeau, M. D., A. Radovic, P. J. Wittkopp and A. D. Long (2003). "A gene necessary for normal male courtship, yellow, acts downstream of fruitless in the Drosophila melanogaster larval brain." Journal of Neurobiology 55(1): 53-72.

Duménil, C., D. Woud, F. Pinto, J. T. Alkema, I. Jansen, A. M. Van Der Geest, S. Roessingh and J.-C. Billeter (2016). "Pheromonal cues deposited by mated females convey social information about egg-laying sites in Drosophila melanogaster." Journal of Chemical Ecology 42(3): 259-269.

Ferveur, J.-F., J. Cortot, B. Moussian, M. Cobb and C. Everaerts (2024). "Replenishment of Drosophila male pheromone after mating." Journal of Chemical Ecology 50(3): 100-109.

Foley, B. R. and M. Telonis-Scott (2011). "Quantitative genetic analysis suggests causal association between cuticular hydrocarbon composition and desiccation survival in Drosophila melanogaster." Heredity 106(1): 68-77.

Gibbs, A. G. (1998). "Water-proofing properties of cuticular lipids1." American Zoologist 38(3): 471-482.

Gibbs, A. G., A. K. Chippindale and M. R. Rose (1997). "Physiological mechanisms of evolved desiccation resistance in Drosophila melanogaster." Journal of Experimental Biology 200(12): 1821-1832.

Ginzel, M. D. and G. J. Blomquist (2016). Insect hydrocarbons: Biochemistry and chemical ecology. Extracellular composite matrices in arthropods. E. Cohen and B. Moussian. Cham, Springer International Publishing: 221-252.

Hirai, Y. and M. T. Kimura (1997). "Incipient reproductive isolation between two morphs of Drosophila elegans (Diptera: Drosophilidae)." Biological Journal of the Linnean Society 61(4): 501-513.

Holze, H., L. Schrader and J. Buellesbach (2021). "Advances in deciphering the genetic basis of insect cuticular hydrocarbon biosynthesis and variation." Heredity 126(2): 219-234.

Krupp, J. J., K. Nayal, A. Wong, J. G. Millar and J. D. Levine (2020). "Desiccation resistance is an adaptive life-history trait dependent upon cuticular hydrocarbons, and influenced by mating status and temperature in D. melanogaster." Journal of Insect Physiology 121: 103990.

Lin, C.-C., K. A. Prokop-Prigge, G. Preti and C. J. Potter (2015). "Food odors trigger Drosophila males to deposit a pheromone that guides aggregation and female oviposition decisions." eLife 4: e08688.

Massey, J. H., N. Akiyama, T. Bien, K. Dreisewerd, P. J. Wittkopp, J. Y. Yew and A. Takahashi (2019). "Pleiotropic effects of ebony and tan on pigmentation and cuticular hydrocarbon composition in Drosophila melanogaster." Frontiers in Physiology 10.

Takahashi, A. (2013). "Pigmentation and behavior: Potential association through pleiotropic genes in Drosophila." Genes & Genetic Systems 88(3): 165-174.

Verschut, T. A., R. Ng, N. P. Doubovetzky, G. Le Calvez, J. L. Sneep, A. J. Minnaard, C.-Y. Su, M. A. Carlsson, B. Wertheim and J.-C. Billeter (2023). "Aggregation pheromones have a non-linear effect on oviposition behavior in Drosophila melanogaster." Nature Communications 14(1): 1544.

Wittkopp, P. J. and P. Beldade (2009). "Development and evolution of insect pigmentation: Genetic mechanisms and the potential consequences of pleiotropy." Seminars in Cell & Developmental Biology 20(1): 65-71.

Yew, J. Y. and H. Chung (2015). "Insect pheromones: An overview of function, form, and discovery." Progress in Lipid Research 59: 88-105.

Zawistowski, S. and R. C. Richmond (1986). "Inhibition of courtship and mating of Drosophila melanogaster by the male-produced lipid, cis-vaccenyl acetate." Journal of Insect Physiology 32(3): 189-192.

指導教授

葉淑丹(Shu-Dan Yeh)

審核日期

2024-8-20

推文