Wiki/Team:Warsaw/igem project.htm

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of constructs on pET15b: OmpA_alpha and OmpA_omega
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of constructs: OmpA_alpha and OmpA_omega #2"><img src="https://static.igem.org/mediawiki/2008/6/62/Notepad_small.png" style="display: inline;" ></a><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-alpha>OmpA_alpha</a></td><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-omega>OmpA_omega</a></td></tr>
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"><img src="https://static.igem.org/mediawiki/2008/6/62/Notepad_small.png" style="display: inline;" ></a><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-alpha>OmpA_alpha</a></td><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-omega>OmpA_omega</a></td></tr>
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<tr><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-A-alpha>OmpA_A_alpha</a></td><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-Z-alpha>OmpA_Z_alpha</td></tr>
<tr><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-A-alpha>OmpA_A_alpha</a></td><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-Z-alpha>OmpA_Z_alpha</td></tr>
<tr><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-A-omega>OmpA_A_omega</a></td><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-Z-omega>OmpA_Z_omega</a></td></tr>
<tr><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-A-omega>OmpA_A_omega</a></td><td align="left"><a href=https://2008.igem.org/Wiki/Team:Warsaw/vectors/pACYC177%2BompA-Z-omega>OmpA_Z_omega</a></td></tr>

Revision as of 21:40, 28 October 2008

Gallery Bricks Notebook Team Project Home

Bacterial device for creating and production of interactors for any given bait protein


Contents

Our goal was to create system of biological machines which would allow to investigate protein interactions and simultaneously change sequence of one of them in order to achieve the strongest possible interaction. To make it work we planned to put the DNA sequence of tested protein on low-copy plasmid and transform it to bacterial strain in which it would be mutated (let's call the strain "one-armed bandit"). Parts present on this plasmid would cause the protein to be attached to outer bacterial membrane, where the selection would occur. Such selection system would allow us to search for antibodies with new specificities or screen protein libraries.


1. The "hunter" protein


We developed a method of selecting the most interacting protein (let's call the protein "hunter"). It may seem similar to the two-hybrid system, except that it doesn't require putting both "hunter" and "prey" in the same cell of "one-armed bandit" and therefore only "hunter" protein is mutated. Moreover, cells expressing different variants of "hunter" protein compete for the same bait. Interaction between "hunter" and "prey" is the basis of selection.

This forces "hunter" protein to be attached to cell surface, so all hunter constructs are fused with fragment of OmpA (outer membrane protein). In this way "hunter" is presented on E. coli outer membrane, which allows it to interact with "prey" added to liquid culture medium.

Fig. 1. Variants of the selection system using two parts of TEM-1 β-lactamase (alpha and omega).

Selection pressure is needed to let survive only cells with the best interacting proteins. We have used TEM-1 β-lactamase (protein responsible for resistance to β-lactam antibiotics such as ampicillin) split into two complementing fragments: alpha and omega. Those fragments do not form active complexes spontaneously. Antibiotic resistance is achieved only when alpha and omega are in close proximity – i.e. when they are connected to two strongly interacting proteins. So "hunter" protein connected with one β-lactamase fragment will catch "prey" protein connected to another and will allow survival of the cell in ampicillin containing medium. Cell line carrying the best hunter protein will have selection advantage over others.

Fig. 2. The selection system at work: 1. "One-armed bandit" mutates hunter protein; 2. Expression of mutated hunters on the surface of bacteria; 3. Adding prey; 4. The best hunters survive.

In order to confirm that this system works we have chosen two small strongly interacting proteins B domain of Staphylococcal protein A and ZSPA1 (formerly denoted as A and Z respectively). The A protein is the famous protein from Staphylococcus aureus which binds to constant fragments of IgG antibodies and has many uses in molecular biology. The Z protein is its artificially created close relative [PMID:15238637]. Apart from interacting with the A protein the Z protein tends to aggregate (this interaction is much weaker than with A though). We have created many variants of construct based on pACYC177 vector (low copy – 10 copies per cell) with IPTG-induced promoter. They contain OmpA fragment, A and Z proteins and β-lactamase fragments in various combinations. Most of our constructs contain duplicated B domain (we call it A), but for some purposes we used single A protein (A delta). Lists of pACYC177 constructs:

Preparation of constructs: OmpA_alpha and OmpA_omega #2">OmpA_alphaOmpA_omega
OmpA_A_alphaOmpA_Z_alpha
OmpA_A_omegaOmpA_Z_omega
OmpA_omega_Adelta_alphaOmpA_omega_Adelta
OmpA_Adelta_alphaOmpA_Adelta_omega

Expresion of fusion protein Omp_omega_deltaA_alpha in TOP10 strain was confirmed by Western blotting using anti-A antibody [LINK]. It reacted with bands of different molecular weights, probably due to degradation of fusion protein by intrinsic E. coli proteases. Therefore we used the same construct to transform Rosetta strain, which lacks a set of proteases and repeated Western blot [link]. There weren't any important differences. We tested also for presence of Omp_omega_deltaA_alpha on bacterial surface.

2. Selection


2.1. "Prey"

We developed a group of constructs used for overexpression and purification of "prey". For this purpose we used pET15b vector with N-terminally His-tagged prey proteins. We have created:

His+Z+omega
His+OmpA-omega
His+A-alpha

The first two constructs were successfully used for overexpression and purification of prey proteins. In case of fusion with A protein we used His-tag and NiNTA beads for purification and in case of fusion with Z protein it wasn't necessary because of Z protein aggregation resulting in the fact that 90% of the post-sonication debris constituted this protein.


2.2. "Hunter" and "prey" interaction

  1. We tried to find out in what conditions expression of OmpA under lactose promotor on pACYC177 is most efficient. We created OmpA_omega_Adelta_alpha construct to check if omega fragment of β-lactamase can be placed in the middle of a protein fusion and still interact with its alpha half. We supposed that ampicillin resistance should increase proportionally to the amount of construct, with the restriction that inductor overdose can decrease expression efficiency due to excess protein synthesis or due to toxicity of Ompa fragment.
    Fig. 3. Evaluation of optimal conditions for expression of the "hunter" protein fusion with OmpA
    Conclusion: conditions of most efficient expression: for IPTG 0.25-0.50 mmol/mL and for ampicillin: 50-75 μg/mL.

  2. We tested what is the minimum amount of protein added to the medium, necessary for survival of cells expressing interacting "hunter" proteins (fig. 4).
    Z_omega was added to bacterial culture expressing pACYC177+OmpA_A_alpha
    Z_alpha was added to bacterial culture expressing pACYC177+OmpA_A_omega.
    A_alpha was added to bacterial culture expressing pACYC177+OmpA_Z_omega. Fig. 4. Bacterial growth depending on the amount of prey protein added to the medium. The amount is expressed in picomoles per mL of medium.

  3. We tested which of the produced "prey" proteins allow the survival of which "hunter" strains in presence of ampicillin (tab. 1). We concluded that interaction of any "hunter" stain expressing alpha protein with "prey" omega, as well as interaction of any "hunter" expressing omega protein with "prey" alpha provides resistance to the antibiotic. Yet, in case when the amount of prey is minimal (fig. 4), growth of bacteria lacking its interactor decreases twofold.

Table 1. Results of testing various hunter/prey combinations
(ampicillin concentration 50-75 μg/mL).


Prey:Hunter:
OmpA_AlphaOmpA_omegaOmpa_A_
Alpha
Ompa_A_
Omega
OmpA_Z_
Alpha
OmpA_Z_
omega
OmpA_
omega_A
His_Z_alphaCell deathCell survival1)Cell deathCell survivalCell deathCell survival1)Cell survival
His_Z_omegaCell survival1)Cell deathCell survivalCell deathCell survival1)Cell deathCell death
His_A_alphaCell deathCell survival1)Cell deathCell survival1)Cell deathCell survivalCell survival1)
No prey
Cell death
1) Growth decreased twofold at the lowest concentration of protein (see Fig. 4)



  1. We tested competition between strains expressing interacting "hunter" proteins and those lacking interactors. In one test probe we placed the following combinations:
    • hunter OmpA_omega, OmpA_A_omega and OmpA_Z_omega with prey A_alpha
    • hunter OmpA_omega, OmpA_A_omega and OmpA_Z_omega with prey Z_alpha
    • hunter OmpA_alpha, OmpA_A_alpha and OmpA_Z_alpha with prey Z_omega
    We cultured these combinations overnight and the following day we isolated plasmids from these strains, performed restriction digest and checked which of the "hunter" won the competition. In each of these combinations "hunter" strain expressing interactor was represented by only one band on a gen, meaning that this strain dominated over the remaining strains.


3. The "one-armed bandit"

3.1 The idea

We intended to create "one-armed bandit" strain, which would randomize target protein sequence – nucleotides would be shuffled randomly in the same way it happens in popular hazard game. The simplest "one-armed bandit" strain is one of standard mutator E. coli strains without polymerase error correction activity or strain without DNA repair systems. It’s not optimal though - high mutation frequency in the whole bacterial genome would introduce some variance into our sequence, but would also cause problems with selection. Instead of screening for protein interactions we would most likely obtain selection-resistant strain. So we wanted to narrow scope of mutations to a small well defined DNA fragment preferably carried on plasmid. Since at the beginning of our project we focused on antibodies, the idea of using AID (Activation Induced Deaminase) protein came right away.

The AID protein is active in mammal lymphocytes, where it causes somatic hypermutation – an increase of mutation level in antibody coding sequences. Moreover there is a publication [PMID:12097915] demonstrating AID activity in E. coli cells. But that wasn’t yet what we wanted because AID mutated all highly-transcribed E. coli genes. We needed to find a way to target it to a specific DNA region. AID prefers single-stranded DNA that appears in highly-transcribed loci. So we needed to make our DNA sequence a highly transcribed one (preferably achieve the highest transcription level in the cell). For this purpose we wanted to test mutation rate in a sequence transcribed from T7 promoter using transcriptional fusion between AID and T7 RNA polymerase. We went a step forward and created translational fusion between AID and T7 RNA polymerase. T7 polymerase traverses the DNA fragment containing T7 promoter and carries AID, which introduces mutations.

AID is a small protein and its closest homologues form oligomers. So we needed to consider such possibility and we created molecular device containing both free AID and AID-T7 fusion. We hoped that AID-T7 fusion would recruit free AID to DNA sequence containing T7 promoter.

To sum up we have created following molecular devices on pMPMT5 plasmid under arabinose promoter:

  1. AID

  2. AID in translational fusion with T7 RNA polymerase

  3. AID in transcriptional fusion with T7 RNA polymerase

  4. AID in transcriptional fusion with AID-T7 translational fusion

To test various variants of AID we needed proper reporter system. We have used alpha-complementing β-galactosidase fragment under control of T7 promoter. We used one-copy plasmid pZC320 (minireplicon of plasmid F), which contained this fragment. After obtaining and induction of cotransformants carrying one of AID devices and reporter plasmid, we hoped to get some white colonies on X-gal plates, indicating mutated clones.

Fig. 1. Our reporter system for checking site-specificity of AID-induced mutations
pBAD - arabinose promoter; pT7 - T7 promoter; L - linker; RBS - sequence coding Ribosomal Binding Site; TAXI=LB+Tetracycline+Ampicillin+IPTG+X-gal

Simultaneously we carried out the rifampicin test (plated liquid cultures of tested strains on plates containing 300 μg/mL rifampicin) to check mutation level in whole genome of tested strains.

Fig. 4. Rifampicin test to check mutation level in bacteria expressing variants of AID.

3.2 Results

We have obtained various numbers of white clones using different AID encoding devices but sequencing of β-galactosidase gene from those clones revealed no mutations. It has to be a flaw in our reporter system. It seems that expressed β-galactosidase fragment encoded on pZC320 plasmid is somehow switched off. We have sequenced large fragments of many white clones of pZC320 – no mutations, no clues. We experimented with GFP and RFP reporter system but this turned out to be ineffective . The test was carried out in two E. coli strains: Top10 and GM2163. The latter has damaged Dam and Dcm methyltransferases so DNA repair systems relying on their activity are unable to repair mismatches created by AID. The results obtained so far are presented in table below:

Table 2. Results of rifampicin test evaluating mutation level in E. coli TOP10 and GM2163 strains.

  TOP10 GM2163
Strain Conditions Mean number of cfu
on rifampicin
Experiments OD Experiments Number of cfu
on rifampicin
wt none 9.20 5 2.77 3 1
pMPM-AID none 9.80 5 2.49 3 4
pMPM-AID 0.1% Arabinose 77.00 5 2.33 3 47
pTRC-AID none 12.33 3 2.41 1 -
pTRC-AID 0.5 mM IPTG 49.00 3 1.98 1 -
pMPM-AID+T7 0.1% Arabinose 137.50 2 1.80 2 99
pMPM-AID+T7 none 6.50 2 2.40 2 2
pMPM-AIDT7 0.1% Arabinose 18.50 2 2.64 2 12
pMPM-AIDT7 none 17.50 2 2.39 2 9

Conclusion: AID increases mutation rate, generating strains resistant to rifampicin. AID in transcriptional fusion with T7 RNA polymerase has the same efficiency as AID alone, which is what we expected. On the contrary, translational fusion apparently doesn't increase mutation rate.

Interesting that although results of β-galactosidase activity test (blue and white colonies) didn't give any information on mutation rate, they differed between strains bearing various AID variants and these results were almost identical between TOP10 and GM2163.

4. Conclusions and future plans

Our long-term plan is to replace A and Z proteins with antibody fragments and antigen but for now we need to check if it's working. To sequence the A protein we will introduce mutations which will make interaction with Z impossible. We will introduce constructs carrying mutated A sequences to "one-armed bandit" strain – we want to check if and when reversion to wild type A will occur in mutant mixture. We didn't manage to obtain desired mutants . The simplest version of this experiment – mixing of two existing strains, isolating plasmid DNA and assessing strain proportions using restriction digests gave very promising results. After mixing equal amounts of OmpA_alpha and OmpA_A_alpha and using our selection system we have isolated only plasmid carrying OmpA_A_alpha (this experiment was also successful for mixture of OmpA_omega and OmpA_A_omega). We also tested whether the whole system running in a mutator strain under selection can generate mutations improving interaction between A and Z proteins or causing fragments of β-lactamase to interact spontaneously .