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研究生:石清華
研究生(外文):Ching-Hua Shih
論文名稱:矽藻(Skeletonemacostatum)中矽沈積相關蛋白
論文名稱(外文):Silica Deposition Associated Proteins in Diatoms (Skeletonema costatum)
指導教授:李家維李家維引用關係
指導教授(外文):Chia-Wei Li
學位類別:碩士
校院名稱:國立清華大學
系所名稱:生命科學系
學門:生命科學學門
學類:生物學類
論文種類:學術論文
論文出版年:2003
畢業學年度:91
語文別:英文
論文頁數:39
中文關鍵詞:矽藻矽沈積
外文關鍵詞:DiatomsSkeletonema costatumsilica depositionsillafin
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由生物合成的無機構造,稱之為生物礦物,在自然界中是一個廣為分佈的現象。能夠產生生物礦化的有機體利用著有機分子來產生各式各樣的構型。而矽藻的生物矽展現了令人讚嘆的多樣化構型:由奈米至微米大小所架構出的種專一性的構型。在矽藻細胞壁的形成過程中,沈積的矽產生三種的型態:作為球顆粒、作為六角柱、以及作為細絲狀。在先前的研究中,證實由在許多的矽藻細胞壁的氟化氫萃取物能夠在無機的環境下促使矽沈積的構型成為球顆粒。在此,我們的工作展示了在另一矽藻種Skeletonema costatum的細胞壁氟化氫萃取物可以促使矽沈積在無機的環境下成為另一種構型,細絲狀。
The biological formation of inorganic structures, termed biominerals, is a widespread phenomenon in nature. Biomineraling organisms use organic molecules to generate species-specific patterns. Diatom biosilica displays a dazzling variety of species-specific silica patterns that are structured on a nanometer-to-micrometer scale. Deposited silica occurs in three morphological forms in the wall formation: as spherical particles, as hexagonal columns, and as microfibrils. Previous studies demonstrated that HF-extract of cell wall of numerous diatom species can direct the silica deposition as spherical particles in vitro. Here, we demonstrate HF-extract of cell wall of Skeletonema costatum can direct silica deposition as another form, microfibrils.
I. Introduction ………………………………………6
II. Methods and Materials ……………………………12
III. Results ………………………………………………14
IV. Discussion……………………………………………17
V. Conclusion……………………………………………21
VI. Figures and Tables…………………………………22
VII. References……………………………………………35
References
1.Lowenstam H. A. 1981. Minerals formed by organisms. Science 211, 1126-1131.
2.Simpson T. L. and Volcani. B. E. 1981. Silicon and Siliceous Structures in Biological Systems, Springer-Verlag
3.Stoermer, E. F., H. S. Pankratz and C.C. Brown. 1965. Fine structure of the diatom Amphipleura pellucida. II. Cytoplasmic fine structure and frustule formation. Amer. J. Bot. 52, 1067-1078
4.Reimann, B. E. F., Lewin J. C. and Volcani B. E. 1966. Studies on the biochemistry and fine structure of silica shell formation in diatoms. II. The structure of the cell wall of Navicula pellculosa (Brèb) Hilse. J. Phycol., 2, 74-84
5.Dawson, P. A. 1973. Observations on the structure of some forms of Gomphonema parvulum Kütz III. Frustule formation. J. Phycol. 9, 353-365
6.Tippitt, D. H., K. L. McDonald and Pickett-Heaps J. D. 1975. Cell division in the centric diatom Melosira varians. Cytobiogie, 12, 52-76
7.Pickett-Heaps. J. D., K. L. McDonald and Tippit, D.H. 1975. Cell division in the pinnate diatom Diatoma vulgare. Protoplasma, 86, 205-242
8.Chiappino, M. L., and Volcani, B. E. 1977. Studies on the biochemistry and fine structure of silica shell formation in diatoms. VII. Sequential cell wall development in the pinnate Navicula pelliculosa. Protoplasma, 93, 205-221
9.Chiara Zurzolo and Chris Bowler. 2001. Exploring Bioinorganic Pattern Formation in Diatoms. A Story of Polarized Trafficking. Plant Physiol. 127, 1339-1345
10.Drum, R. W. 1963. The cytoplasmic fine structure of the diatom, Nitzschia palea. J. Cell Biol. 18, 429-440
11.Drum, R. W., Pankratz, H. S. 1964. Post mitotic fine structure of Gomphonema parvulum. J. Ultrastruct. Res. 10, 217-223
12.Stoermer, E. F., Pankratz, H. S., Brown, C. C. 1965. Fine structure of the diatom Amphipleura pellucida. II. Cytoplasmic fine structure and frustule formation. Amer. J. Bot. 52, 1067-1078
13.Dawson, P. 1973. Observations on the structure of some forms of Gomphonema parvulum Kütz. III. Frustule formation. J. Phycol. 9, 353-365
14.Pickett-Heaps, J. D., Kowalski, S. E. 1981. Value morphogenesis and the microtubule center of the diatom Hantzschia amphiowys. Europ. J. Cell Biol. 25, 150-170
15.Borowitzka, M. A., Volcani, B. E. 1978. The polymorphic diatom Phaeodactylum tricornutum: Ultrastructure of its morphotypes. J. Phycol. 14, 10-21
16.Schmid, A. M., Schulz, D. 1979. Wall morphogenesis in diatoms: deposition of silica by cytoplasmic vesicles. Protoplasma 100, 267-288
17.Li, C.-W., Volcani B. E. 1985. Studies on the Biochemistry and Fine Structure of Silica Shell Formation in Diatoms VII. Morphogenesis of the Cell Wall in a Centric Diatom, Ditylum brightwellii. Protoplasma 124, 10-29
18.Greer, R. G. 1971. The growth of colloidal silica particles. Scanning electron microscopy (part 1). Proc. 4th Annual Scanning Electron Microscopy Symposium, pp. 153-160
19.Vocani. B. E. 1981. Cell Wall Formation in Diatoms: Morphogenesis and Biochemistry. In: Simpson T. L. and Volcani. B. E. (ed.). Silicon and Siliceous Structures in Biological Systems, Springer-Verlag
20.Schmid, A. M., M. A. Borowitzka and B. E. Volcani. 1981. Morphogenesis and biochemistry of diatom cell walls. In: O. Kiermayer (ed.). Cytomorphogenesis in Plants. Springer-Verlan, Vienna.
21.Martin-Jezequel V, Hildebrand M, Brzezinski MA. 2000. Silicon metabolism in diatoms: implications for growth. J. Phycol. 36, 821-840
22.Van Den Hoek C, Mann DG, Johns HM. 1997. Algae. An Introduction to Phycology. Cambridge, UK: Cambridge Univ. Press
23.Brzezinski MA, Olson RJ, Chisholm SW. 1990. Silicon availability and cell-cycle progression in marine diatoms. Mar. Ecol. Prog. Ser. 67, 83-96
24.Martin-Jezequel V. Hildebrand M, Brzezinski MA 2000. J. Phycol. 36, 821-840
25.Vaulot D, Olson RJ, Chisholm SW. 1986. Light and dark control of the cell cycle in two phytoplankton species. Exp. Cell Res. 167, 38-52
26.Vaulot D, Olson RJ, Merkel SM, Chisholm SW. 1987. Cell cycle response to nutrient starvation in two marine phytoplankton species. Mar. Biol. 95, 625-630
27.Kröger N, Deutzman R, Sumper M. 1999. Polycationic peptides from diatom biosilica that direct silica nanosphere formation. Science 286, 1129-1132
28.Kröger N, Deutzman R, Bergsdorf C, Sumper M. 2000. Species-specific polyamines from diatoms control silica morphology. Proc. Natl. Acad. Sci. USA 97, 14133-14138
29.Mizutani, T., Nagase, H., Fujiwara, N., Ogoshi, H. 1998 Bull. Chem. Soc. Jpn. 71, 2017-2022
30.Iler, R. K. 1979 The Chemistry of Silica. Wiley, New York
31.Gordon, R. and Drum, R. W. 1994. The chemical basis for diatom morphogenesis. Int. Res. Cytol. 150, 243-372
32.Li, C. W., Volcani, B. E. 1984 Aspects of silicification in wall morphogenesis of diatoms. Philos. Trans. R. Soc. London B 304, 519-528
33.Kröger N, Lehmann G, Rachel R, Sumper M. 1997. Characterization of a 200-kDa diatom protein that is specifically associated with a silica-based substructure of the cell wall. Eur. J. Biochem. 250, 99-105
34.Kröger N, Wetherbee R. 2000. Pleuralins are involved in theca differentiation in the diatom Cylindrotheca fusiformis. Protist 151, 263-273
35.Kröger N, Bergsdorf C, Sumper M. 1994. A new calcium-binding glycoprotein family constitutes a major diatom cell wall component. EMBO J. 13, 4676-4683
36.Kröger N, Bergsdrof C, Sumper M. 1996. Frustulins: domain conservation in a protein family associated with diatom cell wall. Eur. J. Biochem. 239, 259-264
37.van de Poll WH, Vrieling EG, Gieskes WWC. 1999. Location and expression of frustulins in the pinnate diatoms Cylindrotheca fusiformis, Navicula pelliculosa, and Navicula salinarum (Bacillariophyceae). J. Phycol. 35, 1044-1053
38.Perry CC 1998. In: ed. Interrante LV, Hampden-Smith MJ. Chemistry of advanced materials: an overview. Wiley-VCH, New York, 499-562
39.Sumper M. 2002. A Phase Separation Model for the Nanopatterning of Diatom Biosilica. Science 295, 2430-2433.
40.Mann S. 1993. Molecular tectonics in biomineralization and biomimetic materials chemistry. Nature 365, 499-505
41.Oliver, S., Kupermann, A., Coombs, N., Lough, A., and Ozin G. A., 1995. Lamellar Aluminophosphates that Mimic Radiolaria and Diatom Skeletons. Nature 378, 47-50
42.Stöber, W., Fink, A. and Bohn, E. 1968. Controlled growth of monodisperse silica spheres in the micron size range. J. Colloid Interface Sci. 26, 62-69
43.Brinker, C, J. and Scherer, G. W. 1990. Sol-Gel Science. Academic, Boston
44.Parkinson, J. and Gordon, R. 1999. Beyond micromachining: the potential of diatoms. Trends Biotechnol. 17, 190-196
45.Mann S, Ozin GA 1996. Synthesis of inorganic materials with complex form. Nature 382, 313-318
46.Morse DE. 1999. Silicon biotechnology: harnessing biological silica production to construct new materials. Trends Biotechnol. 17, 230-232
47.Parkinson J, Gordon R. 1999. Beyond micromachining: the potential of diatoms. Trends Biotechnol. 17, 190-196
48.Laemmli, U.K. 1970. Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4. Nature 227, 680-685
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1. 24.黃程貫『勞動法中關於勞動關係之本質的理論』,載於【政大法學評論】,第59期。
2. 20.許育典『學習自由、教育基本權與二一退學』,載於【教育研究月刊】,第97期,2002年5月。
3. 19.許慶雄『勞工權利與憲法』,載於【律師雜誌】,219期。
4. 28.黃越欽『國際勞工公約與憲法法院-兼論司法院釋字第三七三號解釋』,載於【憲政時代】,第28卷,第3期。
5. 26.黃德祥「我國教師組織之『正』與『誤』」,載於【學校行政雙月刊】,中華民國學校行政研究學會發行,2002年5月。
6. 13.周志宏『析論美國法上之學生懲戒制度』,載於淡江大學公共行政系【法政學報】,第6期,1996年7月。
7. 16.徐元龍『我國教師組織工會問題之省思』,載於【勞工研究】,第94期。
8. 15.林明鏘『憲政改革與公務員制度-與德國法之比較研究』,載於【法令月刊】,第43卷,第2期,1993年2月。
9. 39.衛民,『公共部門的集體協商-美國公務人員的經驗』,編於【勞資關係論叢】,第2期,中正大學勞工研究所出版。
10. 38.衛民『公共部門教師組織-從勞動三權中團結權的分析』,載於空大行政學報,第6期,1996年11月。
11. 4.丘周剛『從釋字三七三號論我國公共部門勞動關係之建構』,載於【法律評論】,第61卷,第9、10期合刊,1995年。
12. 36.蔡茂寅『工作權保障與勞動基本權的關係及其特質』,編於【律師雜誌】,第219期。
13. 35.蔡秀卿『論公務員人事行政程序之保障』,載於【人事行政】,第132期,2000年6月。
14. 30.焦興鎧『國際勞動基準之發展趨勢及我國因應之道』,載於【勞工行政】,1999年,第133期。
15. 29.張煌熙『教師組織與集體談判的運用』,載於【教育資料與研究】,第8期,1996年1月。
 
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