Composite

Part:BBa_K639003

Designed by: Eirik Selsaas   Group: iGEM11_NTNU_Trondheim   (2011-08-26)
Revision as of 15:50, 15 September 2011 by Tormunds (Talk | contribs)

rrnB P1-LacI-pLac-mCherry plausible stress sensor

The stringent response in bacteria is caused by amino-acid starvation, fatty acid limitation, iron limitation, heat shock and other stress conditions. As a response under these conditions, in vitro studies have suggested that the alarmone guanosine tetraphosphate (ppGpp) increase to modulate transcription to promote survival. The increase in ppGpp levels causes a redirection of transcription so that genes important for survival are favoured at the expense of those required for growth and proliferation [1].

So, could we use ppGpp as signal molecule to find out when cells are stressed?

The solution

Our system will be based on a promoter that is important for regulating growth and proliferation. At the moment we are trying to use the rrnB-p1 promoter, which has been shown in earlier studies to be highly regulated by the ppGpp molecule. Hopefully the promoter will be down regulated enough by increased levels of ppGpp to turn the repressor lacI it controls completely off. The lacI represses a second promoter pLac that induces the production of red fluorescent protein (mCherry) and turns the cells red.


An overview of the construct is seen in the picture below. Stress-sensor.png

Plasmid map of the complete construct. Promoters are shown in blue, and genes as inside arrows. Only single restriction sites are shown.

The stress sensor is made from these biobricks.

Biobrick Part number
LacI with RBS BBa_J24679
Terminator BBa_B0015
pLac BBa_R0011
mCherry with RBS and terminator BBa_J06702

The promotor is a variant of BBa_K112118, that we have made ourselves using PCR, and the PCR product was directly used as insert and connected with the rest of the construct. The final construct was cut with BstBI to verify that the rrnB P1 had been insertet. The stress sensor has a total length of 2653 bp, and is located inside the plasmid pSB1A2, carrying ampicillin resistance. We have put the stress sensor through several tests.

Stress sensor characterization

To test our [http://2011.igem.org/Team:NTNU_Trondheim/rrnB+LacI+pLac+mCherry stress sensor], pre-cultures of the construct with, and without the rrnB P1 promoter were grown ON, pelleted and resuspended in M9 medium. The cultures were inoculated 1% in LB, LB+IPTG, M9 and M9+IPTG. IPTG will induce pLac, by inhibiting lacI's inhibition. M9 is a minimal medium, lacking amino-acids. M9 was used because ppGpp is mainly produced in the stringent response during amino-acid starvation.


Cultures were grown in flasks in a shaking incubator at 37C for 3,5 hours, and 3 parallels of 100 µL from each flask were sampled to a 96 well fluorometer plate. Fluorescence was measured at ex: 584 em: 620, as well as OD600. Data from the experiment is shown in figure 1, as fluorescence divided by OD600.


Stress-sensorBOTH.jpg


As shown in figure 1, the cells do produce a substantial amount of mCherry even when they are not stressed (LB, and LB+IPTG). This is possibly due to the rrnB P1 promoter not being strong enough to produce sufficient amounts of lacI to inhibit pLac's expression of mCherry.

Looking at the difference between samples with (+P) and without promoter (-P) in LB and LB+IPTG, it is clear that the rrnB P1 promoter does produce lacI. The fluorescence/OD value of +P in LB is lower than -P in LB, indicating production of lacI. When it is induced by IPTG, inhibiting lacI, the level rises to approximately the same as -P, indicating a nullifying effect of the lacI produced.

The fluorescence / OD of the M9 samples is much higher than the LB. This was due to the slow growth rate in M9. The OD600 was unchanged from the inital OD in all M9 parallels after 3,5 hours (data not shown). What is interesting here, is that the difference between +P and -P seems to be gone. This indicates that the rrnB P1 promoter does indeed produce less lacI when the cells are grown in M9, possibly due to amino-acid starvation and ppGpp shutting it down. As the data was quite variable, this is hard to say for sure.


In future work with this construct, one could try to increase rrnB P1's strength by maybe tweaking the UTR, or try to lower pLac's strength, to give less leakage. A combination of both strategies would probably give the best result.

Flow Cytometry

Several measurements were performed using a Flow Cytometer, this allowed us to measure the flouresence from single cells. The resulting plots shows the distributions of the flouresence for the red end of the spectrum (i.e around the wavelength corresponding to mCherry).

380x340px 380x340px 380x340px 380x340px

First of all there is a remarkable difference between the distributions for M9 and LB. The distribution for M9 is relatively sharp compared to LB which means there is little difference in the level of light a emitted from the individual cells. The distribution for LB is much broader showing a greater variance and it is also shifted to the right. A distribution shifted to the right means stronger emission of red light.

380x340px


Reference:

http://www.sciencedirect.com/science/article/pii/S0966842X05000788 1 Magnusson, L. U., A. Farewell, et al. (2005). "ppGpp: a global regulator in Escherichia coli." Trends Microbiol 13(5): 236-242

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 1666
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


[edit]
Categories
Parameters
None