Difference between revisions of "Part:BBa K2599016"
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<partinfo>BBa_K2599016 short</partinfo>
 
<partinfo>BBa_K2599016 short</partinfo>
  
NCTU_Formosa 2018 designed this sequence to improve the part from NCTU_Formosa 2016.
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<p style="padding-top:20px;font-size:40px"><b>Introduction</b></p>
 
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We changed the general linker to a GS linker to optimize the function of Sf1a.
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Revision as of 07:03, 16 October 2018


T7 Promoter+RBS+Sf1a+GS linker+snowdrop-lectin+linker+6X His-Tag

Introduction


Previous Part:(BBa_K1974022)

The existing part from NCTU_Formosa 2016 contains the IPTG induced PT7 (BBa_I712074), strong ribosome binding site (BBa_B0034), Sf1a, AAA linker, snowdrop lectin (BBa_K1974020) and the 6X His-Tag (BBa_K1223006).


Figure 1. Previous part


Improvement part

In many application, the fusion proteins consisting of multiple protein domains is a popular and highly successful approach to engineering new protein functions. The linker that connects the fusion protein often plays an important role in fusion proteins. Therefore, we decided to change the linker between Sf1a and lectin to try whether the function of this protein become stronger. The GS linker we used in this improvement part was also provided by NCTU_Formosa 2016. It contained 18 amino acid sequence, which is a Gly-Gly-Ser repeated linker. We utilized this linker to optimize the fuction of Sf1a and lectin.


Figure 2. Improvement part


Introduction

μ-segestritoxin-Sf1a is kind of insecticidal toxin, contains three disulfide bonds. It will inhibits insect voltage-gated sodium channels by blocking the channel pore.

Lectin is carbohydrate-binding proteins, and is able to bind soluble ectracellular and intercellular glycoproteins.


Target Insect

Result

1. Comparison of Plant Protecting Effect of Different Design of Linker between Protein Sf1a and Lectin


Figure 4. Comparison of plant protecting effects


(I): Fusion proteins with GS linker (Improvement part BBa_K2599016 ); (II): Fusion proteins with AAA linker (Previous part BBa_K1974022); (III): Negative control group of Rosetta gami DE3 solution. After feeding for 7 hours, leaf area of (I) remained unchanged compared with leaf remaining area after 3 hours; While leaf of (II) and (III) was continued consumed by larva. Through comparison, improvement group (I) is more effective in protecting leaf from larvae consuming than previous part (II).



2. Plant Protecting Effect of sequence Sf1a-GS Linker-Lectin (Improvement Part) in pET-32a


Figure 4. Plant protecting effects by inserting the improvement part into pET-32a.


Through comparison, improvement part with the highest concentration shown the most effective as it had the largest leaf area remaining.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


Reference

1. Elaine Fitches, Martin G. Edwards, Christopher Mee, Eugene Grishin, Angharad M. R. Gatehouse, John P. Edwards, John A. Gatehouse “Fusion proteins containing insect-specific toxins as pest control agents: snowdrop lectin delivers fused insecticidal spider venom toxin to insect haemolymph following oral ingestion,” Journal of Insect Physiology, 2004, 50, pp.61-71
2. Elaine C. Fitches, Prashant Pyati, Glenn F. King, John A. Gatehouse, “ Fusion to Snowdrop Lectin Magnifies the Oral Activity of Insecticidal Omega-Hexatoxin-Hv1a Peptide by Enabling Its Delivery to the Central Nervous System,”
3. Monique J. Windley, Volker Herzig, Slawomir A. Dziemborowicz, Margaret C. Hardy, Glenn F. King and Graham M. Nicholson, “Spider-Venom Peptide as Bioinsecticide,” Toxins Review, 2012, 4, pp. 191-227.
4. A. Lipkin, S. Kozlov, E. Nosyreva, A. Blake, J.D. Windass, E. Grishin (2001, April 9). Novel insecticidal toxins from the venom of the spider Segestria florentina. Toxicon, 40, 125-130.