Team:Newcastle/Filamentous Cells

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[[Image:yneA_brick2.png]]
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Our ''IPTG-inducible filamentous cell formation part'' puts ''yneA'' under the control of the [http://partsregistry.org/wiki/index.php?title=Part:BBa_K302003 LacI-repressible promoter, hyperspankoid, that we designed]. In the presence of LacI, induction with IPTG will result in a filamentous cell phenotype.  
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Our ''IPTG-inducible filamentous cell formation part'' puts ''yneA'' under the control of the [http://partsregistry.org/wiki/index.php?title=Part:BBa_K302003 strongly LacI-repressible promoter that we designed, hyperspankoid]. In the presence of LacI, induction with IPTG will result in a filamentous cell phenotype.  
The part has no terminator, allowing for transcriptional fusion with ''gfp'' and visualisation under the microscope.
The part has no terminator, allowing for transcriptional fusion with ''gfp'' and visualisation under the microscope.

Revision as of 16:12, 26 October 2010

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Contents

Filamentous cell formation by overexpression of yneA

Bacillus subtilis cell division is dependent on FtsZ. FtsZ forms a 30 subunit ring at the midpoint of the cell and contracts.

YneA indirectly stops the formation of the FtsZ ring. In nature, yneA is expressed during SOS response, allowing the cell to repair DNA damage before continuing with the division cycle.

It is hypothesized that YneA acts through unknown transmembrane proteins to inhibit FtsZ ring formation; we call these unknown components "Blackbox proteins".

By expressing YneA and therefore inhibiting FtsZ ring formation, the cells will grow filamentous.


Part

YneA brick2.png

Our IPTG-inducible filamentous cell formation part puts yneA under the control of the [http://partsregistry.org/wiki/index.php?title=Part:BBa_K302003 strongly LacI-repressible promoter that we designed, hyperspankoid]. In the presence of LacI, induction with IPTG will result in a filamentous cell phenotype.

The part has no terminator, allowing for transcriptional fusion with gfp and visualisation under the microscope.

This is part [http://partsregistry.org/Part:BBa_K302012 BBa_K302012] on the [http://partsregistry.org parts registry].


Biochemical pathway filamentous.png

Computational model

Model1:
Newcastle CellDesigner Filamentous.png This model was written in SBML and simulated in cell designer,it shows the species and compartment involved in our yneA system.
Model2:
Newcastle ModelFilamentous.png We wrote a computational model of our filamentous cell system in SBML and simulated it in COPASI. The graph below shows that FtsZ ring formation is low when yneA is overexpressed.

Cloning strategy

yneA cloning strategy

Characterisation

Testing and Characterisation

Selection for integration

To select for integration of the plasmid into the chromosome, B. subtilis will be tested for the ability to hydrolyse starch. Integration of the BioBrick will be done by homologous recombination at the amyE, therefore destroying endogenous expression of amylase. Colonies that are not able to break down starch on agar plate will be selected and cultured for further test. Colonies that do not contain the integrated BioBrick will be able to hydrolyse starch, therefore forming a white halo around the colony as iodine interacts with starch to form blue colour.

The construct we designed has a GFP transcriptional fusion after the yneA coding sequence, so GFP is co-transcribed and acts as our fluorescent marker for transcription of yneA.

Lab work and Results

We characterised the part first without, and then with, LacI repression (using the integration vector pMutin4 to integrate lacI into the Bacillus subtilis 168 chromosome.

Normal Bacillus subtilis 168
Filamentous cells
Filamentous cells showing GFP signal
Filamentous cells (integrated at amyE)
Filamentous cells showing GFP signal(integrated at amyE)

Graphs

Graph1:
Teamnewcastle yneA168.png
Graph 1 shows that overexpression (no Lac repression) of the yneA gene (ΔamyE:pSpac(hy)-oid::yneA) leads to a longer cell length compared with our control Bacillus subtilis 168.
See below: Bacillus subtilis 168 cells (left),Bacillus subtilis expressing yneA(centre) and Bacillus subtilis overexpressing yneA(right)
Teamnewcastle yneA168BS.jpgTeamnewcastle yneA1.jpgTeamnewcastle yneA.jpg
Graph2:
Newcastle no induction.jpg
Graph 2 shows the percentage of cells at different lengths(μm)uninduced
See below: Bacillus subtilis 168 cells (left) and non-induced cells(right)
Teamnewcastle yneA168BS.jpgTeamnewcastle noindBS.jpg
Graph3:
Newcastle 0.2 induction.jpg
Graph 3 shows the percentage of cells at different lengths(μm)induced at 0.2mM IPTG
See below: Bacillus subtilis 168 cells (left) and cells induced at 0.2mM IPTG(right)
Teamnewcastle yneA168BS.jpgTeamnewcastle 0.2indBS.jpg
Graph4:
Newcastle 1IPTG.jpg
Graph 4 shows the percentage of cells at different lengths(μm)induced at 1mM IPTG
See below: Bacillus subtilis 168 cells (left) and cells induced at 1mM IPTG(right)
Teamnewcastle yneA168BS.jpgTeamnewcastle 1indBS2.jpg

Graphs 2, 3 and 4 show a greater proportion of filamentous cells at a higher concentration of IPTG(1mM IPTG), compared with Bacillus subtilis 168 our control population.

Research

Initial Research

Bacillus subtilis in response to stress such as DNA damage stops the cells from dividing. This is a part of the SOS response initiated by the accumulation of single stranded DNA from DNA damage or stalled replication. Two proteins are vital for this response: RecA and LexA. RecA forms filaments on ssDNA and promotes the autocleavage of LexA. LexA usually represses the SOS operon. dinR is homologous to lexA in E. coli and is transcribed in the opposite direction of yneA.

SOS response is believe to be a universal bacteria phenomenon first studied in E.coli -lexA, recA

In Bacillus subtillis (gram positive) dinR protein is homologous to lexA (Repressor of din-damage inducible genes). din genes include uvrA, uvrB, dinB, dinC dinR and recA. DNA damage inhibits cell division.

Wild type Bacillus subtilis dinRKO Mutant
Wild type Bacillus subtillis.jpg DinR KO.jpg

Figure1: The images above show Bacillus subtilis Wild type and dinRKO mutant, and the change in cell length. dinR KO mutant over expresses the divergent (opposite direction) transcript for YneA, YneB and YnzC. These genes form the SOS regulon (recA independent SOS response).

Coding region.jpg


Figure2:The diagram above shows the Coding region for dinR and yneA showing divergent expression.

Expression of YneA from IPTG controlled promoter in wildtype leads to elongation. Disruption of YneA in SOS response leads to reduced elongation. Altering YneB and YnzC expression does not affect cell morphology.

Double mutant (dinR YneA) !Graph showing yneA expression correlated with FtsZ ring formation and cells length

Figure3(above left): Shows the double mutant dinR overexpression cancels out the filament formation via over expression of yneA.

Figure4(above right):This graph shows the correllation between reduced FtsZ ring formation, increased cell length and overexpression of yneA.

YneA protein required to suppress cell division and not chromosome replication or segregation.

FtsZ is important for bacterial cell division forming a ring structure at the division site by polymerising assembling other proteins necessary for division at the site.

FtsZ localises to the cell division cycle unless dinR is disrupted or YneA is being induced. YneA suppresses FtsZ ring formation which is proven by 2 hybrid protein association test.

YneA expression by the inactivation of dinR by RecA is important.


References

Kawai, Y., Moriya, S., & Ogasawara, N. (2003). "Identification of a protein, YneA, responsible for cell division suppression during the SOS response in Bacillus subtilis". Molecular microbiology, 47(4), 1113-22.

Mo, A.H. & Burkholder, W.F., (2010). "YneA , an SOS-Induced Inhibitor of Cell Division in Bacillus subtilis , Is Regulated Posttranslationally and Requires the Transmembrane Region for Activity" ᰔ †. Society, 192(12), 3159-3173.


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