Regulatory

Part:BBa_K1602050

Designed by: Christian Sator,Stefan Zens, Max Zander, Benedikt Spannenkrebs, Sebastian Jaeger   Group: iGEM15_TU_Darmstadt   (2015-09-16)
Revision as of 16:55, 25 September 2015 by CSator (Talk | contribs)

RRlocked

This part is half of a two-part killswitch-system for E.coli utillizing a riboregulator for posttransciptional regulation of hokD. It consists of the fused sequences of a constitutive promoter (BBa_J23100), a cis-repressing sequence (cr), hokD (BBa_K1497008) and a terminator (BBa_B0015).

Figure 1: Design of RRlocked.
When transcribed the cis-repressing sequence forms a hairpin-secondary-structure masking the ribosome binding site (RBS) and therefore prevents translation of the following hokD-sequence. If the corresponding trans-activating RNA-sequence (taRNA) (RRKey-BBa_K1602049) is present the two sequences form a RNA-RNA-complex. This leads to a helix shift and the release of the RBS enabling the expression of hokD resulting in cell death.

Figure 2: Interaction of taRNA and crRNA leads to expression of hokD.

The sequence of the crRNA is based on an existing riboregulator sequence pair published by Isaacs et al[1]. The original sequence contained an EcoRI restriction site which was removed by basepair-exchange. We used the Riboswitch Designer to find out which basepair-exchange is best suited to remove the unwanted EcoRI restriction site while not affecting the folding- and interaction-capabilities of the sequence.

Functional Parameters

In order to assemble the final riboregulator-systems the parts RRL3H (BBa_K1602044) and RRK3 (BBa_K1602046) on two seperate plasmids (pSB1C3 and pSB1A2) were co-transformed into E.coli(Top10) for the first riboregulator. For the second riboregulator containing hokD the part RRlocked (BBa_K1602050) was co-transformed with araC-pBAD-RRkey (BBa_K1602051). Positive transformants were selected by using two antibiotics, Chloramphenicol and Ampicillin, and verified via colony-PCR. A strain of E.coli (TOP10) transformed with araCpBAD-hokD (BBa_K1602043) was used as positive control and as negative control for each riboregulator Top10 transformed with only the cis-repressed part (RRL3H and RRlocked) of each system. All five cultures were grown in LB-medium with the respective antibiotics containing 20mM glucose at 37°C over night. Afterwards 10µl of each culture were inoculated in two seperate flasks of LB-medium (with the respective antibiotics), one containing 20mM Glucose, the other one 2mM arabinose. After 16 hours of incubation at 37°C an aliquot of each culture was diluted several times and different dillutions were spread on LB-agar plates containing 20mM glucose. The plates were incubated at 37°C over night until single colonies were distinquishable. The amount of colonies was counted in order to determine the colony forming units per ml culture (CFU/ml) to compare the amount of living bacteria in the cultures grown with glucose and arabinose.

Figure 3: Results of the spread plate assay used to determine the amount of CFU/ml for the cultures grown with either glucose (red) or arabinose (black)

The positive control (araC-pBAD-hokD) showed a significant reduction of CFU/ml in the culture grown with arabinose compared to the culture grown with glucose indicating that the presence of glucose repressed hokD-expression while the addition of arabinose leads to production of HokD resulting in increased cell death (Fig.3). The results for the riboregulators however did not turn out as expected. There was no significant reduction in the CFU/ml of the culture grown with arabinose compared to the culture grown with glucose observable for both riboregulator-systems (RRK3+RRL3H and araC-pBAD-RRkey+ RRlocked). This might indicate that the interaction between the taRNA and the crRNA das not occure as predicted resulting in a constant repression of hokD even when induced with arabinose.

One possible reason for the malfunction of the riboregulator could be the fact that both parts were located on seperate plasmids which were co-transformed into the cells. It is possible that this results in an unfavorable situation for the bacteria to produce enough of both parts necessary for the riboregulator to work.

To further investigate this hypothesis we cloned both parts of the riboregulator next to each other on one plasmid resulting in the BioBrick RRhoK (BBa_K1602052) but we were not able to repeat the experiment so far due to time constraints.


References

1. Isaacs, F.J., et al., Engineered riboregulators enable post-transcriptional control of gene expression. Nat Biotechnol, 2004. 22(7): p. 841-7.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 7
    Illegal NheI site found at 30
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


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Categories
Parameters
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