Difference between revisions of "Part:BBa K1583111"
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<li> Crystal Violet assay </li> | <li> Crystal Violet assay </li> | ||
<li> Transmission electron microscopy </li></ul> | <li> Transmission electron microscopy </li></ul> | ||
− | As shown in the crystal violet assay in the characterization section of pRha+CsgA & pTet+RFP | + | As shown in the crystal violet assay in the characterization section of pRha+CsgA & pTet+RFP (<a href="https://parts.igem.org/Part:BBa_K1583106"target="_blank">BBa_K1583106</a>), the RFP conding device does not affect the formation of CsgA protein. Therefore the characterization data of <a href="https://parts.igem.org/Part:BBa_K1583105"target="_blank">BBa_K1583105</a> is also valid for this biobrick.</p> |
<h4> Fluorescence assay </h4> | <h4> Fluorescence assay </h4> | ||
<p> | <p> |
Revision as of 21:33, 18 September 2015
pRha + CsgA_Mfp3_His fusion protein & pTET + RFP
This part is meant to express a fusion protein of the csgA and the Mfp3 gene with His-tag under control of L-rhamnose-inducible promoter. Addionally a RFP coding device was added (BBa_I13521).
CsgA is a protein monomer which can aggregate to form amyloid nanowires in natural biofilms taken from E.coli K-12 MG1655. Inspired by mussels, the Mfp3 (mussel foot protein) has high adhesive properties towards wet polar surfaces. CsgA is a protein monomer which can aggregate to form amyloid nanowires in natural biofilms of E.coli. This protein is transported as an unfolded protein out of the cell. Outside the cell CsgA proteins self-assemble into nanowires after nucleation on the membrane protein CsgB. By creating a fusion protein of CsgA and Mfp3, the adhesive properties of the mussel foot protein is combined with the formation of nanowires.
The design was based on the paper "Strong underwater adhesives made by self-assembling multi-protein nanofibres" (Zhong et al, 2014).
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Characterization
Three different experiments were done to characterise the BBa_K1583105 biobrick:
- Fluorescence assay
- Crystal Violet assay
- Transmission electron microscopy
Fluorescence assay
To be able to ensure that CsgA is expressed, we added a gene encoding for GFPmut3 (BBa_I13504) under induction of the same rhamnose promoter (BBa_K1583112) to check that the promoter works. In this experiment, the fluorescence signal of our csgA construct and csgA-GFP (I13504) constructs was recorded in time after induction with no, 0.2% (w/v) or 0.5% (w/v) rhamnose. Besides the fluorescence, the OD600 was measured in order to normalize the fluorescence signal per cell.All conditions were carried out in triplicates to be able to do a statistical analysis on the data. The different experiments were induced in a 96 well plate. The OD600 and fluorescence signal was recorded in a plate reader during a 18 hour period of induction at 30°C.
In Fig. 1, the fluorescent signal was normalized by the number of cells and plotted as a function of time. The red bars denote the error within each ID.
As can be seen from Fig. 1, only the experiments with 0.2% (w/v) and 0.5% (w/v) rhamnose induction with the csgA-GFPmut3 construct gave a clear increase in fluorescence signal in time. All other experiments, gave similar levels of fluorescence, slightly increasing in time. Furthermore, it can be seen that a higher induction level of rhamnose leads to an increase in GFPmut3 and thus fluorescence. Finally, as the fluorescence signal is normalized by the cell density, one can make statements about the activity of the rhamnose promoter. The promoter seems to not be active right after induction, but more after 3 or 4 hours. This is in accordance with data from literature (Wegerer et. al), in which a low amount of fluorescence with a rhamnose promoter was observed after 2 hours of induction.
With this kinetic experiment, we have proven that the rhamnose promoter does indeed induce the expression of the csgA gene.
Crystal violet assay
The assay above showed that the bacteria that we engineered for the project is capable of producing the CsgA proteins after induction with L-rhamnose. However, this did not yet prove that curli are formed. In order to assess whether our bacteria producting the fusion protein CsgA_Mfp3_His can still produce these nanowires, our team adapted the protocol from Zhou et al. (2013) that employs crystal violet (methyl violet 10B) for dying the biofilm-making bacteria that attaches to the surface. In the experiment, our CsgA_Mfp3_His-producing strain of E. coli was induced at a high (0.5% w/v), low (0.2% w/v) and no (0% w/v) concentration of L-rhamnose. Furthermore, csgA deficient bacteria transformed with an empty plasmid (pSB1C3) were used as control. In the end, the wells were diluted with ethanol so all the content can dissolve in the liquid phase. We measured the absorbance at 590 nm of wavelength for all the samples, obtaining the following results (figure 2.).
To confirm that there is a real change between the analysed samples and the empty plasmid control, a significance analysis was performed for α=0.05 (Table 1.).
Sample | p-value | Significant difference (5%) |
---|---|---|
CTRL2 & MFP32 | 0.0127 | Yes |
CTRL5 & MFP35 | 0.0170 | Yes |
The significance analysis shows that cells containing the CsgA_Mfp3_His (BBa_K1583105) biobrick can efficiently create a curli, when compared with an empty plasmid control (i.e. without csgA expression).
Transmission electron microscopy
Using TEM the formation of curli of the biobrick BBa_K1583100 was visualized. Although this is a different biobrick containing only CsgA (compared to the fusion protein of Mfp3_CsgA_His), curli formation can be presumed to be similar for this biobrick suggested by the Crystal Violet assay.
We did not observe formation of curli nanowires in the uninduced cultures of our strain. However, cells from induced cells clearly produced them, as supported by the TEM images.
Reference
,
Angelika Wegerer, Tianqi Sun and Josef Altenbuchner, 2008. Optimization of an E. coli L-rhamnose-inducible expression vector: test of various genetic module combinations”BMC Biotechnology, 8:2
Zhong, C. et al., 2014. Strong underwater adhesives made by self-assembling multi-protein nanofibres. Nature nanotechnology, 9(10), pp.858–66Zhou, Kang, Kangjian Qiao, Steven Edgar, and Gregory Stephanopoulos. 2015. “Distributing a Metabolic Pathway among a Microbial Consortium Enhances Production of Natural Products.” Nature Biotechnology 33(4): 377–83.