Composite

Part:BBa_K3182000

Designed by: Oliver Hild Walett   Group: iGEM19_Linkoping_Sweden   (2019-07-08)
Revision as of 15:36, 4 October 2019 by Emmbe580 (Talk | contribs)

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 580
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


Introduction

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Figure 1. Mechanism of action. The CBDcipA-fusion is attached to a polysaccaride material. By adding thrombin from any source the fusion protein will be cleaved and the C-terminal fusion protein will be released into the solution. By changing the fusion protein to an antimicrobial peptide/enzyme, and using the material as a bandage, the peptide/enzyme can be released into a wound by native human thrombin.

This part consists of a carbohydrate binding domain (CBD) from Clostridium thermocellum (C. thermocellum) cellulose scaffolding protein (CipA) and is a central part Clostridium thermocellum's cellusome. The CBD-fusion were fused using a flexible GS-linker (-GGGGSGGGGS-). A thrombin cleavage site (-LVPRGS-) was added to the end of the linker and its breakage will leave a glycine and serine attached to the N-terminal of the fusion protein.

Protease site and use

The thrombin site was added to enable the ability to release the fusion protein down into skin wounds. Because of our integrated human practice we learned that infection span much deeper into wounds that we thought. Simply attaching the CBD-fusion protein to a carbohydrate material wouldn't make the fusion protein reach far into the wound. The thrombin site was also chosen because of thrombins endogenous occurrence in humans.

Assembly compabilities

An internal BamHI recognition sequence (RS) has been added to enable changeable fusion proteins. BamHI was chosen because its RS codes for glycine and serine, fitting it to the end of the thrombin site. It is also a cost-effective enzyme and is unaffected by methylated DNA.




CBDcipA crystal structure

Figure 1. Crystal structure of CBDcipA with a resolution of 1.75 Å which were solved by [http://www.ncbi.nlm.nih.gov/pmc/PMC452321 Tormo et al. 1989]. PDB code 1NBC. In red from the left, W118, R112, D56, H57 and Y67, thought to be the surface which interacts strongly with polysaccarides.

Important molecular faces

CBDcipA is composed of a nine-stranded beta sandwich with a jelly roll topology and binds a calcium ion. It further contains conserved residues exposed on the surface which map into two clear surfaces on each side of the molecule. One of faces mainly contains planar strips of aromatic and polar residues which may be the carbohydrate binding part. Further aspect are unknown and unique with this CBD such as the other conserved residues which are contained in a groove.

Carbohydrate binding domain specificity

Since the CBD is from the cellusome of C. thermocellum some researches call it a cellulose binding domain. However, iGEM19 Linköping noticed that this domain could also bind to different sources of polysaccaride materials. This serves as a domain for iGEM19 Linköpings modular bandage, where the polysaccaride material can be changed for anything and not exclusively cellulose.

The choice of carbohydrate binding domain

iGEM Linköping 2019 choose CBDcipA due to many other iGEM teams exploring the possibilities of this domain. Our basic design was influenced by [http://2014.igem.org/Team:Imperial iGEM14 Imperial], [http://2015.igem.org/Team:edinburgh iGEM15 Edinburgh] and [http://2018.igem.org/Team:ecuador iGEM18 Ecuador]. Purification and where to place the fusion protein (N- or C-terminal) was determined by studying the former projects. CBDcipA also originates from a thermophilic bacteria which further increases the domains applications.



Expression system

The part has a strong expression with a T7-RNA-polymerase promotor (BBa_I719005) as well as a 5'-UTR (BBa_K1758100) region which has been shown to further increase expression in E. coli (BBa_K1758106), ([http://www.ncbi.nlm.nih.gov/pubmed/2676996 Olins et al. 1989]), ([http://www.ncbi.nlm.nih.gov/pubmed/23927491 Takahashi et al. 2013]).

Figure B. Benchling screenshot of the expression system. The T7-RNA-polymerase promotor is followed by a T7 g10 leader sequence which enhances the binding to the 16S ribosomal RNA. After the leader sequence a poly A spacer is found, which has been shown to increase translation in vitro. Before the start codon a strong RBS, g10-L, followed by an AT-rich spacer can be seen, which will slightly increase translation of the following gene.

Usage and Biology

Figure 4. A: E. coli BL21 cells expressing the biobrick, incubated for 16 hours at 16°C at 80 rpm in 1L of LB-miller. B: Lysated (via sonication) BL21s which are expressing the biobrick. It is lysate from the culture above in figure 4. Incubated for 16 hours at 16°C at 80 rpm in 1 litre of LB-miller. C:Centrifuged lysate of BL21 culture which express the biobrick. It is the same culture as figure 4 and 5. A pellet of non-lysated bacteria can be observed.

A pink colony from an agar plate was selected and cultured in 10 ml LB-miller for 16h at 37°C, 180rpm. This culture was afterwards added to 1L of LB-miller which was grown for 16h, 80rpm at 16°C. This result can be observed in figure 4. Approximately 45ml of the culture was poured to a 50ml Falcon tube and sonicated which is displayed in figure 5. This tube was later centrifuged and a pink pellet was formed (seen in figure 6).





Figure 7. Lysate (via sonication) from BL21 E. coli was incubated with Epiprotect (microbial cellulose bandage) for 1h and washed thrice with 70% ethanol. To the right is Epiprotect that has not been incubated with AsPink-CBD lysate.





































AsPink bound to cellulose bandage

Epiprotect (microbial cellulose bandage, S2Medical) was incubated in AsPink lysate from BL21 (DE3) Gold for 30 min. Epiprotect was later washed with 70% ethanol three times. To the left is AsPink incubated Epiprotect and to the right is plain Epiprotect.

Figure 8. Lysate (via sonication) from BL21 E. coli was incubated with cellulose fibres (Whatman CF-11 Fibrous Medium Cellulose Powder). Saturated cellulose was incubated with different units (U) of thrombin (Novagen, #69671).The leftmost is cellulose with cleavage buffer and the control contains bound AsPink with cleavage buffer. All tubes has been incubated over-night in R.T on an end-to-end rotator.




















Thrombin Cleavage

In figure 9 bacterial lysate of sonicated E. coli BL21 was incubated with cellulose (Whatman CF-11 Fibrous Medium Cellulose Powder) in 1h on an end-to-end rotator at R.T. The cellulose was saturated with AsPink lysate. The samples were afterwards centriuged at 3000 g in 1 min and the supernatant was removed. In all samples cleavage buffer (20 mM Tris-HCl pH 8.4, 150 mM NaCl and 2.5 mM CaCl₂) was added and three different dilutions of thrombin (Novagen, #69671) was added. The dilutions were 0,02, 9,94 and 0,08 units (U). One unit refers to the amount of thrombin needed to cleave 1 mg of protein for 16h at R.T in a 200 µl reaction containing the cleavage buffer. The samples were put on an end-to-end rotator over-night (ca 16h) and left at R.T. The control with only cleavage buffer has a transparent supernatant and a pink pellet of cellulose, the most diluted (0,02 U) has a slightly pinker supernatant and less pink pellet however the 0,04 U and 0,08 U dilutions has a pinker supernatant and paler pellet with 0,08 U dilution being the sample with most cleaved AsPink due to the more intense supernatant.



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