Fig. 1. The enzyme reaction by multiple complex To connect different enzymes will make continuous reaction efficiently.
We made a platform of technology for constructing covalently linked multi-enzyme-complex through disulfide bonds recruited by self-assembling peptide (SAP). By fusing SAP to the end of a protein, it will condense with other proteins’ SAP domains and form the complex. The SAP domains is pinched by short linkers (SL) that have cysteine residues. When the SAPs gather and SLs get close, disulfide bonds are formed between other SLs. So, we will make unbreakable complex. By using this method, we’ll be able to connect several enzymes and allow huge complexed proteins to be formed. It’ll improve the efficiency of a continuous reaction.
Fig. 2. Huge complex using SAP To connect same enzymes like fluorescent proteins will amplify thir effects.
However, the ordinary method uses linkers to connect proteins. We think the new method using SAP is superior to the ordinary one for these reasons (Table. 1).
Table. 1. Comparison between linkers and SAPs
Linker Method
SAP Method
Regulated by one promoter (Fig. 3)
Each protein can be produced individually (Fig. 4)
Difficult to produce several huge complex
Possible to synthesize the proteins individually. Can also form a huge complex (Fig. 4)
The possibility of deformation of the 3D-structure (Fig. 5)
Low possibility of deformation since they only connect with proteins which can condense
Fig. 3. Using linkers Expressions of gene A, B and C which code protein A, B and C are regulated by one promoter. If you connect some huge proteins, the expression efficiency may be decreased because the coding sequence is too long.
Fig. 4. Using SAPs You can produce protein A, B and C individually. After expression, they gather by SAPs and form disufide bonds by SLs.
Fig. 5. Demerit of using linkers In linker method, you need to consider the linker length to avoid the steric hindrance.
We thought the SAP method was best one but it had also disadvantages. Since the number of the possible combination of several different proteins is infinite, there is no guarantee that we can always obtain the expected combination.
One solution to the problem is limiting the number of combination by using different SAP. That can reduce probability of incorrect connection a little.
Fig. 6. Demerit of using SAP method
If some kinds of protein are expressed, there are so many combination. You may not be able to get the correct combination.
Fig. 7. Resolution for infinite combinations When you use some kinds of SAP, incorrect connections will decrease.
Multimerization is very useful.As forming protein complex with different functions, this multimer let us create more functional units. When same kinds of protein are used, it’ll be a large block and its function is expected to be enhanced.
We tried to establish novel uses of SAP in this yaer. We challenged multimerization using it and not only used it but also made firmly connection.
Fig. 8. Method for verifying whether proteins form multiple complex
We tried forming multimers using the self-assembling peptide, P11-4 and RADA16-I. We
Connected short linker(GGCGG) and SAP to both ends of the protein. In this experiment, we
formed the multimers of GFP. GFP’s molecular mass is 26891Da. When fusing with P11-4, it’s
31709Da. With RADA16-I, it’s 31943Da. When they form multimer, the molecular mass will be more
than 60kDa. Consequently, we used the filter which filters out the proteins with mass of more than 50KDa.
For the evaluation, we ordered IDT the designed constructions and put them on the vectors. Then,
we introduced them to E.coli. Using IPTG induction , the proteins were expressed. Causing bacteriolysis with freeze-thaw, we acquired the supernatant contains the proteins by centrifugal
separation. Purifying the protein with Ni-affinity chromatography, we filtrated the solution
to separate the proteins with mass of less than 50KDa. We irradiated 480nm light to filtrate and observed
whether 580nm wave-length light was emitted.
Fig. 9. キャプション
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Fig. 9. Construct of multimerization using SAP This is the construct for making multiple complex. We used RADA16-I and P11-4 as SAP. C is a cysteine residues in short linker.
Fig. 10. Construct of a negative control We made a negative control which had only GFP to test the effect of SAPs.
Fig. 11. Construct for making subunits of artificial multi-enzyme-complex We designed this construct to had a cloning site. If you design the protein which ends are BamHI site, you can make the multimer easily.
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