Team:Peking/Project/Bioabsorbent/MBPExpression

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(Periplasmic Translocation of MBP)
(Periplasmic Translocation of MBP)
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'''Figure 6. Standardization procedure of DsbA-MBP.'''
'''Figure 6. Standardization procedure of DsbA-MBP.'''
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===RESULT===
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Periplasmic Expression DsbA-MBPs was verified by SDS-PAGE and western blotting (Fig 7).
==Reference==
==Reference==

Revision as of 14:20, 27 October 2010

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   MBP Expression


         Project > Bioabsorbent > MBP Expression
As was mentioned above, in order to implement the mercury-binding function in bacteria with as least cost as possible, we constructed a single polypeptide consisting of two repeats of MerR with a flexible linker in between (Details can be seen in the MBP Construction Part).

Since our ultimate goal is to design a high-performance and less energy-consuming bioabsorbent, the MBP will be an excellent candidate for the absorbent effector. MBP was then fused with DsbA, a periplasmic translocated protein with a signal sequence at its N-terminal, and OmpA, a membrane protein, to construct periplasmic MBP and surface displayed MBP, in order to maximize the bacterial capability of mercury binding. Finally, mercury MBP was constitutively expressed on surface, periplasm and cytosol of E.coli cells via carefully designed genetic circuits, to guarantee the maximum of Hg absorption (Fig 1).

FIG 1.png

Figure1. The genetic circuit we designed to guarantee the maximum of Hg absorption. The production of T7 RNA polymerase is constitutive. T7 polymerases will active high rating transcription at T7 promoters. Thus Hg (II) will be highly effectively accumulated by substantial amount of MBPs which are translocated to cytosol, periplasm and cell surface of the bacteria.

Contents

Cytoplasmic Expression of MBP

To design the module of cytosol expression, MBP in pSB3K3 was then to coloned into pSB1A2, prefixed by T7 promoter and RBS BBa_B0034 (Fig 2), verified by DNA sequencing.

Fig2.png

Fig 2. Construction of the cytosol expression module. MBP was cloned into the pSB1A2 step by step, prefixed by T7 promoter and RBS.

The resulting construct, T7 promoter + BBa_B0034+ MBP was transformed into BL21 (DE3) competent cells. The expression of MBP has been verified by SDS-PAGE and western blotting. (Fig 3)

FIG 3.png

Fig 3. The expression of MBP has been verified by SDS-PAGE and Western Blotting. IPTG was used as the inducer. (A) Overexpression band at about 10 KD was detected. (B) Positive band of the expected molecular weight could be detected in the cytosol

We detected overexpression band at about 10 kD, which was likely to be MBP. Then we fused a his-tag to our target protein and conducted western blotting to further verify their expression. Positive band of the expected molecular weight could be detected in the cytosol, which confirmed expression and localization of the target protein. We can also indicate from the SDS-PAGE that there are indeed a large number of MBPs existing in cytosol, ready to bind mercury ions.

Periplasmic Translocation of MBP

Though contributing to the removal of Hg2+, over-expression of the mercury-binding protein may be inefficient because of its limitation of mercury uptake . Then we pay our attention to the translocation of MBP to the periplasm or surface of the bacteria, a promising strategy that not only eliminates the limitation of the capacity of accumulating Hg2+ but also makes full use of the spaces in the bacteria besides cytosolic MBPs, thus increasing the speed of absorbability and removal.

DsbA, the commonly used signal protein which can export proteins fused to it into the periplasmic space, was selected as the candidates for the periplasmic fusion MBPs. According to previous work, DsbA, a SecA dependent signal protein , can export its C-terminal fusion protein into periplasm on the signal recognition particle (SRP) pathway , which is made up of six proteins and an RNA molecule and directs rapid co-translational translocation of many proteins .Since some protein with a rapid protein folding pathway often assembles into its stable three-dimensional structure before it has a chance to be exported, Maltose Binding Protein thus inevitably suffers from its inefficient posttranslational export . In contrast, DsbA perfectly bypasses such problem due to its cotranslational translocation that obviates the inhibitory effect of protein folding on exportation. Hence DsbA overmatches Maltose Binding Protein with a more efficient and rapid way to export the target protein (for example, the metal binding peptide) to the periplasmic space, making it the best choice for the periplasmic design (Fig. 4)

Fig 4.png

Figure 4. Result of 3D modeling for DsbA-MBP Fusion Protein. DsbA is translocated into periplasm by the co-translational pathway, which is friendly for protein folding.

Then a genetic circuit was designed as was shown in Fig 4. Bacteria will express large copy number of DsbA-MBPs and finally they will fill up the periplasmic space. In addition, RBS B0030, a weaker ribosome binding site was used as to avoid the overexpression of DsbA-MBP because it might saturate the co-translational transporter and inhibit the translocation of other proteins.

As for the standardization of the periplasmic translocation module, the entire coding region of DsbA and MBP was cloned into pSB1K3 with standard restriction enzyme sites. Particularly, the PstI restriction site inside DsbA was mutated synonymously.

Fig 5.png

Figure 5. Procedure of DsbA-MBP construction.

As to construct the fusion of DsbA-MBP, a commercial plasmid, pET-39b (+), which contains the gene encoding DsbA, was used as the backbone. The entire coding region of the MBP was amplified by PCR from full length MerR with two pairs of primers. The two PCR products were digested with Xba I / BamH I, or BamH I / Xho I, followed by cloning these 2 fragments into Spe I / Xho I digested pET-39b(+) in one step (Fig. 5) to construct pET-39b(+)-DsbA-MBP.

Fig 6.png

Figure 6. Standardization procedure of DsbA-MBP.

RESULT

Periplasmic Expression DsbA-MBPs was verified by SDS-PAGE and western blotting (Fig 7).

Reference

1.Chen, S., and D. B. Wilson. 1997. Construction and characterization of Escherichia coli genetically engineered for bioremediation of Hg2-contaminated environments. Appl. Environ. Microbiol. 63:2442–2445.

2.Chen, S., and D. B. Wilson. 1997. Genetic engineering of bacteria and their potential for Hg2 bioremediation. Biodegradation 8:97–103.

3.Chen, S., and D. B. Wilson. 1997. Construction and characterization of Escherichia coli genetically engineered for bioremediation of Hg2-contaminated environments. Appl. Environ. Microbiol. 63:2442–2445.

4.Luirink, J., and B. Dobberstein. 1994. Mammalian and Escherichia coli signal recognition particles. Mol. Microbiol. 11:9–13.

5.Debarbieux, L., and J. Beckwith. 1998. The reductive enzyme thioredoxin acts as an oxidant when it is exported to the Escherichia coli periplasm. Proc.Natl. Acad. Sci. USA. 95:10751–10756.

6.Francisco, J. A., Earhart, C. F. & Georgiou, G. (1992). Transport and anchoring of beta-lactamase to the external surface of Escherichia coli. Proc Natl Acad Sci U S A 89, 2713–2717.

7.Francisco, J. A., Campbell, R., Iverson, B. L. & Georgiou, G. (1993). Production and fluorescence-activated cell sorting of Escherichia coli expressing a function antibody fragment on the external surface. Proc Natl Acad Sci U S A 90, 10444–10448

8.Yamaguchi, K., Yu, F. & Inouye, M. (1988) Cell 53, 423-432.

9.Jie Qin,Lingyun Song,Hassan Brim, Michael J. Daly and Anne O. Summers(2006) Hg(II) sequestration and protection by the MerR metal-binding domain(MBD).Microbiology 15, 709–719

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