Team:Calgary/Project/Controls

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Testing our system

Once constructed, we needed a way to test the cytoplasm and periplasmic stress promoters in order to characterize them. We did this in three different ways.

  1. Testing with known folding and misfolding proteins
  2. Testing with NlpE, an outer membrane lipoprotein known to activate the Cpx regulon
  3. Testing with varying temperature conditions

Testing with known folding and misfolding proteins

First, it was necessary to identify proteins that are known successful folders and known non-folders in E. coli. Maltose binding protein was selected for this purpose. Wild type maltose binding protein (MalE) is transporter protein that is shuttled to the periplasmic space of E.coli and known to fold extremely well there. We chose a mutant form of maltose binding protein, MalE31, that does not fold in the periplasm due to two amino acid substitutions in positions 33 and 34. In addition to this periplasmic mutant, another mutant form of MalE was found, with the signal sequence required for transport to the periplasmic space deleted. The MalEΔSS folds extremely well in the cytoplasm regardless of the deletion. MalE31 with its signal sequence removed is a non folder in the cytoplasm. Thus, we have four proteins covering folding and non-folding in both the periplasm and the cytoplasm.

maltose binding chart place holder


The wild type MalE as well as the mutant versions were received from the Betton lab in France. These parts were Biobricked, but prior to testing the selected stress reporter circuits with these parts, it was necessary to test these MalE variations to ensure that they were functional and matched literature data. To do this, we transformed them into strains of cells containing cpxR and degP promoters upstream of a lacZ rpeorter (Raivio labs). We would expect malE31, if it misfolded, to activate the cpxR and degP stress promoters, thus providing a blue output from lacZ. MalE, on the other hand, is expected to fold properly, thus not activating these promoters, and produce any lacZ activity. These assays allowed us to conclude that MalE and MalE31 work the way that we expected them to. See results on our characterization page.

Once malE and malE31 were shown to be functional, we then used them to test out the stress promoters. We did this by making competent cells containing our reporter circuits. We then transformed in inducible constructs containing our MalE and mutant MalE proteins. Fluorescent output was measured from these assays and the results can be seen on our characterization page.


Testing with NlpE

NlpE is an outer membrane lipoprotein that literature has shown to activate the Cpx pathway. We transformed expression constructs for this protein (obtained from Dr. Tracy Raivio's lab) into Top10 competent cells containing our CpxR reporter and looked for fluorescent output. Results for this experiment can be viewed on our characterization page.

One of the proteins that are used to characterize Cpx system in the literature is new lipoprotein E (NlpE). NlpE is present on the outer membrane of E. coli membrane. NlpE is hypothesized to be involved in cellular adhesion and copper homeostasis in the cell (Otto and Silhavy, 2001). NlpE has an N and an identical C terminus motif which consists of cystine-X-X-cystine (CXXC) (Hirano et al, 2007).

nlpE Figure 1: NlpE CXXC motifs are present at C31, 34 and C211, 145. These residues interact with each other forming disulfide bridges which are necessary for formation of the functional lipoprotein. (Hirano et al, 2007)

Testing with Varying Temperature Conditions

Finally we tested the CpxR promoter activity in the presence of varying temperature conditions. Literature data has shown that the Cpx pathway is also activated due to heat stresses. To establish a baseline that could be used to determine whether heat misfolded protein was activating the pathway, we exposed cells containing the CpxR promoter to heat stresses of 30°C, 37 °C, 42 °C, and 47 °C. The results can be seen on our characterization page under Experiment 2.