Team:Potsdam Bioware/Project/Details Selection

From 2011.igem.org

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*Lucast, L. J., Batey, R. T., and Doudna, J. A. (2001). Large-scale purification of a stable form of recombinant tobacco etch virus protease. Biotechniques 30: 544-550.<br>
*Lucast, L. J., Batey, R. T., and Doudna, J. A. (2001). Large-scale purification of a stable form of recombinant tobacco etch virus protease. Biotechniques 30: 544-550.<br>
*Wanga QM, Chen SH., Human rhinovirus 3C protease as a potential target for the development of antiviral agents.  Curr Protein Pept Sci. 2007 Feb;8(1):19-27. <br>
*Wanga QM, Chen SH., Human rhinovirus 3C protease as a potential target for the development of antiviral agents.  Curr Protein Pept Sci. 2007 Feb;8(1):19-27. <br>
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*Shih S. R., Chen S. J., Hakimelahi G. H., Liu H. J., Tseng C. T., Shia K. S., Selective human enterovirus and rhinovirus inhibitors: An overview of capsid-binding and protease-inhibiting molecules.

Revision as of 13:11, 28 October 2011

Contents

In Vivo Selection

Introduction

In addition to the phage display we developed a novel selection system. The design aimed for a cheap and time-saving alternative in contrast to an in vitro screen of protease inhibition kinetics. The assay allows us to select effective inhibitors for any protease, among the billions of randomly generated mutants of the Microviridin. For this purpose we designed a plasmid containing two devices, first a protease activity detector and second a protease generator. We used the BioBrick <partinfo>I757010</partinfo> (β-lactamase) and <partinfo>K208005</partinfo> (ssTorA) and fused them together via a linker peptide to create our first device. The protease generator is an Arabinose inducible protease in iGEM standard.

Figure 1: Schema of our constructed selection vector containing protease generator and protease activity detector

The system works in a combined manner of the two devices. In order to confer β-lactam antibiotic resistance to cells the β-lactamase has to be exported in the periplasm. This transport is mediated by the TorA export sequence via the Twin-Arginine Translocation (TAT) system (DeLisa, 2008). The linker peptide between the TorA export sequence and the β-lactamase displays the corresponding protease cleavage site. In addition the linker peptide is chosen as short as possible to imitate folding because the TAT pathway only allows transport of correctly folded substrates. The linker peptide as well as the protease are designed as exchangeable parts.

If the protease device is functional, it will cleave the linker peptide between TorA and β-lactamase construct which leaves the cell without any antibiotic resistance. The construct was tested with increasing Ampicillin concentrations. The number of surviving colonies was depended on the export rate of the β-lactamase into the periplasm. A high cleavage rate of the linker peptide leads to a reduced Ampicillin resistance. With expressed protease a dramatically drop of the number of surviving colonies could be observed.
The survival assay was carried out with and without expressed protease. By increasing of the Ampicillin concentration we could detect a cutoff ampicillin concentration. The colony forming units (CFU) were counted and compared.

Site-directed mutagenesis of TEV and 14_3C proteases in iGEM standard

We chose two model proteases, the Tobacco Etch Virus protease, further along called TEV, and the 14_3C protease from the human rhinovirus, also known as PreScission. Both proteases contained iGEM restriction sites, one in case of the TEV and three for 14 3C, respectively.

Figure 2: complete sequence alignment of the 14_3C protease
Figure 3: complete sequence alignment of the 14_3C protease



Thus, site-directed mutagenesis was applied to mutate each restriction site in E. coli. For every mutation a forward and a reverse primer had to be designed. The following pictures show the forward primers for the side directed mutagenesis, the reverse primers are the reverse complement sequence of the forward primers.

For the 14_3C protease:

Figure 4:Reverse primer to add the iGEM suffix on the HRV 14_3C protease
Figure 5:Forward primer to mutate the SpeI restriction site in the gene sequence of the HRV 14_3C protease
Figure 6:Forward primer to mutate the first XbaI restriction site in the gene sequence of the HRV 14_3C protease
Figure 7:Forward primer to mutate the second XbaI restriction site in the gene sequence of the HRV 14_3C protease
Figure 8: Forward primer to add the iGEM prefix to the HRV 14_3C protease






































For the TEV protease:

Figure 9: Reverse primer to add the iGEM suffix to the TEV protease
Figure 10: Forward primer to mutate the SpeI restriction site in the gene sequence of the TEV protease
Figure 11:Forward primer to add the iGEM prefix to the TEV protease
























We used assembly PCR to gain the final product. In case of PreScission two assembly PCRs had to be done. The expected size of the fragments are shown in the gel picture. In the following picture all fragments contain the correct sizes.

Figure 12:Picture of the, via PCR amplified and mutated Fragment of both protease


Cloning of arabinose inducible induction system for fusion with both proteases, TEV and 14_3C

The need of time independent induction of the ssTorA_CS-Protease_blaFL device and the protease, we amplified the arabinose inducible induction system out of the pBAD_iGEMexpress vector. The fusion of both, protease and induction system was performed via an NgoMIV restriction site we introduced with our amplification primers.

Figure 13: Reverse primer for the amplification of the arabinose inducible induction system
Figure 14: Forward primer for the amplification of the arabinose inducible induction system

We used the RFC 23 cloning strategy to get a fusion protein of our desired protease and the induction system, which allows us to induce the protease. Both genes were amplified with PCR using two special primers generating a NgoMIV restrictioin site at the end of the induction system and in front of the protease. The amplified protease were digested with BamHI and NgoMIV, the arabinose inducible induction system with NgoMIV and HindIII. The vector, which contains the ssTorA_CS-Protease_blaFL device was digested with HindIII and BamHI. A triple ligation yielded the final construct with both devices: the protease detector and the protease generator. The two pictures below show the final vector constructs , which where used for the survival screening.

Figure 15: Final vector construct containing arabinose inducible TEV protease fusion and the protease detector device
Figure 16: Final vector construct containing arabinose inducible HRV 14_3C protease fusion and the protease detector device

Testing the protease detector activity

Both pictures below show the surviving rate of transformed cells with constructed vector:

Figure 17: Survival test at different ampicillin concentrations: A) approx. 1000 cfu platet on agar plates containing chloramphenicol; B) Reduced amount of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1mM IPTG to induce ampicillin resistance via BBa_K627012 and 400µg/ml ampicillin; C)no culture growth of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1mM IPTG to induce ampicillin resistance via BBa_K627012 and 600µg/ml ampicillin
Figure 18: Survival test at different ampicillin concentrations: A) approx. 1000 cfu platet on agar plates containing chloramphenicol; B)Influence of resistance induction with 1 mM IPTG, approx. 1000 cfu where platet on agar plates containing chloramphenicol and 1mM IPTG; C)Reduced amount of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1 mM IPTG to induce ampicillin resistance via BBa_K627013 and 50 µg/ml ampicillin; D)Reduced amount of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1 mM IPTG to induce ampicillin resistance via BBa_K627013 and 100 µg/ml ampicillin;E)Reduced amount of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1 mM IPTG to induce ampicillin resistance via BBa_K627013 and 200 µg/ml ampicillin; F)Reduced amount of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1 mM IPTG to induce ampicillin resistance via BBa_K627013 and 400 µg/ml ampicillin; G)No culture growth of E.coli colonies, approx. 1000 cfu were platet on agar plates containing chloramphenicol, 1 mM IPTG to induce ampicillin resistance via BBa_K627013 and 800 µg/ml ampicillin

Background

Twin Arginine Translocon (TAT)

The TAT pathway is responsible for the transport of folded proteins across energy-transducing membranes and it is able of discriminating of unfolded proteins. This transport pathway is common for bacteria, archea and plants and translocates circa 6% of E.coli produced secreted proteins. The translocated proteins must have a signal peptide for targeting of the TAT-transporter, such proteins are e.g. hydrogenases, dehydrogenases and reductases. The signal sequence itself is composed of an N-terminal positive charged domain, a hydrophobic domain and a C-terminal domain.
The translocon is composed of three parts: TatA, TatB and TatC. The transport-pore is proposed to be formed during substrate binding by these three parts. The TatA, TatB and TatC proteins may form complexes of different sizes, which on the other hand form pores matching the size of the folded substrate. The transport of proteins through the TAT pathway depends on the proton motive force. Calculations by Adler & Theg showed that the transport of one folded substrate molecule requires the release of approximately 7.9x104 protons, which equals 10.000 ATP molecules. The signal sequence is cleaved off after translocation.

Figure 19: schematic representation of TorA-signal sequence. Figure adopted from: Philip A. Lee, Danielle Tullman-Ercekand George Georgiou Annu. Rev. Microbiol. 2006. 60:373–95


The used signal sequence originates from the TorA protein (Trimethylamin-N-Oxid-Reductase). It is the main respiratory enzyme which reduces TMAO under anaerobic conditions in the periplasm, where it is transported by the TAT pathway.

Figure 20: schematic representation of TAT-dependent pathway. Figure adopted from: Philip A. Lee, Danielle Tullman-Ercekand George Georgiou Annu. Rev. Microbiol. 2006. 60:373–95



Tobacco Etch Virus (TEV) protease

TEV protease is the common name for the 27 kDa catalytic domain of the Nuclear Inclusion a endopeptidase (NIa) encoded by the tobacco etch virus. TEV protease is a useful reagent for cleaving fusion proteins. It recognizes a linear epitope of the general form E-Xaa-Xaa-Y -Xaa-Q-(G/S), with cleavage occurring between Q and G or Q and S. In TEV protease the serine nucleophile of the conventional Ser-Asp-His triad is a cysteine instead. This probably explains why TEV protease is resistant to many commonly used protease inhibitors.

14_3C-Protease

The 14_3C protease originates from the human rhinovirus. Rhinoviruses are the most frequent reason for infections of the upper and lower respiratory tract, also known as the cold. Because the 3C protease of human rhinovirus is necessary for the cleavage of the polyprotein translated from viral RNA it may serve as a potential target for development of antiviral targets. The recombinant type 14_3C protease from human rhinovirus (HRV 3C) recognizes the same cleavage site as the native enzyme: LeuGluValLeuPheGln↓GlyPro. The small, 22-kDa size of the protease got its optimal activity at 4°C but is still very active at 37 °C. It is commonly used for an easy tag removal after the purification of recombinant proteins carrying his-tag. The 14_3C works with a catalytic triade, containing the amino acid residues Ser-Asp-His at its active site.

References

  • Philip A. Lee, Danielle Tullman-Ercekand George Georgiou Annu. Rev. Microbiol. 2006. 60:373–95
  • Olivier Genest, Marianne Ilbert, Vincent Méjean and Chantal Iobbi-Nivol April 22, 2005 The Journal of Biological Chemistry, 280, 15644-15648.
  • Cabrita, L. D., Gilis, D., Robertson, A. L., Dehouck, Y., Rooman, M. and Bottomley, S.P. (2007). Enhancing the stability and solubility of TEV protease using in silico design. Protein Sci. 16: 2360-2367
  • Kapust, R. B., Tözsér, J., Fox, J. D., Anderson, D. E., Cherry, S., Copeland, T. D., and
  • Waugh, D. S. (2001). Tobacco etch virus protease: Mechanism of autolysis and rational design of stable mutants with wild-type catalytic proficiency. Prot. Eng. 14: 993-1000.
  • Lucast, L. J., Batey, R. T., and Doudna, J. A. (2001). Large-scale purification of a stable form of recombinant tobacco etch virus protease. Biotechniques 30: 544-550.
  • Wanga QM, Chen SH., Human rhinovirus 3C protease as a potential target for the development of antiviral agents. Curr Protein Pept Sci. 2007 Feb;8(1):19-27.
  • Shih S. R., Chen S. J., Hakimelahi G. H., Liu H. J., Tseng C. T., Shia K. S., Selective human enterovirus and rhinovirus inhibitors: An overview of capsid-binding and protease-inhibiting molecules.