Difference between revisions of "Team:ZJU-China/Design/Toxinmanufacture"

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     <li> <a href="https://2015.igem.org/Team:ZJU-China/Design/Termites"> Termites </a> </li>  
 
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Revision as of 09:10, 17 September 2015

Toxin Manufacture

Introduction

Biological pesticides can be divided into two types: small compounds and biological macromolecules. On one hand, small compounds are more prone to be absorbed by termites while more costly to produce. On the other hand, macromolecules are easier and cheaper to produce whereas sometimes not as effective as small molecules. Hence, to kill termites more efficiently and effectively, we choose both - insecticidal small molecule avermectin and several toxic proteins. We plan to overexpress avermectin in its host Streptomyces avermitilis and express three kinds of toxic protein in Escherichia coli BL21(DE3) . Then we embed the engineered S. avermitilis and E.coli with CNC carrier and fed termites with the CNC embedded bacteria. For more information about CNC, please go to the main page of CNC .

Avermectin manufacture

Judging that many toxic small compounds are harmful to human being, we choose avermectin, which is highly specific to insect and does no harm to human. For one thing, being a secondary metabolite produced by Streptomyces avermitilis , avermectin is regulated by an 80kb gene cluster(1), making it difficult to express in other standardized strains, for instance, Escherichia coli . For another, the avermectin yield in wild type S. avermitilis strain is comparatively low(1). Nevertheless, we plan to engineer the wild S. avermitilis to improve the yield of avermectin, embed the engineered strain with CNC and feed termites with CNC embedded S. avermitilis .

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Toxic protein manufacture

In order to kill the termites, we have chosen four types of insecticidal toxic proteins, respectively Tc protein tcdA1, tcdB1, bt-like Plu0840 and enterotoxin-like Plu1537, from Photorhabdus luminescens TT01, a bacterium of native toxin storehouse. Then we cloned these genes from the genome of TT01 , constructed corresponding vectors, successfully expressed these proteins in Escherichia coli BL21(DE3) and fed the termites with the raw engineered BL21 and that embedded with CNC. For more information about CNC, please go to the main page of CNC.

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Reference

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2. H. Ikeda, K. Shin-ya, S. Omura, J IND MICROBIOL BIOT 41, 233 (2014).

3. H. Ikeda et al., NAT BIOTECHNOL 21, 526 (2003).

4. P. MAZODIER, R. PETTER, C. THOMPSON, J BACTERIOL 171, 3583 (1989).

5. F. Flett, V. Mersinias, C. P. Smith, FEMS MICROBIOL LETT 155, 223 (1997).

6. 孙宁, 浙江大学 (2013).

7. D. J. MACNEIL, J BACTERIOL 170, 5607 (1988).

8. R. K. Holmes, M. G. Jobling, (1996-01-19, 1996).

9. J. A. HEINEMANN, G. F. SPRAGUE, NATURE 340, 205 (1989).

10. T. Kunik et al., P NATL ACAD SCI USA 98, 1871 (2001).

11. V. L. Waters, NAT GENET 29, 375 (2001).

12. E. Duchaud et al., NAT BIOTECHNOL 21, 1307 (2003).

13. M. Li, L. H. Qiu, Y. Pang, ANN MICROBIOL 57, 313 (2007).

14. C. Gatsogiannis et al., NATURE 495, 520 (2013-03-20, 2013).

15. R. Zhao et al., APPL ENVIRON MICROB 74, 7219 (2008-12-01, 2008).

16. M. Li et al., MOL BIOL REP 36, 785 (2009).

17. M. S. Kelker et al., PLOS ONE 9, (2014).

18. J. Sha, E. V. Kozlova, A. K. Chopra, INFECT IMMUN 70, 1924 (2002).



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