RNA

Part:BBa_K4811024

Designed by: Kasper Krunderup Jakobsen   Group: iGEM23_DTU-Denmark   (2023-10-02)


TMS(PFOA1)

This is a tRNA Mimicking Structure (TMS). It is a novel piece of synthetically designed RNA, which folds in the same manner as tRNA, developed by Paul et al. It is a trans-encoded genetic switch, which binds to the Ribosome Binding Site (RBS), BBa_K4811000, repressing translation. The binding regions are flanking the RBS, and no binding happens in the RBS consensus sequence. This means that there are very few limitations on both the possible TMSs and repressible RBSs which could be engineered.

In this particular part, the D-loop of BBa_K4811002 has been exchanged for a PFOA-sensitive aptamer, in this case with the sequence: GGACGACGGCGTGGGGTGGTAGGCTGTAAAGGGGGTCGTCGTCCC

This is the full aptamer, JYP_2, from J. Park, but only including a small part of the stem region (see Design).

tms-pfoa1.png

Figure 1. Prediction of folding of the RNA using ViennaRNA. The figure is colored by base-pairing probabilities. For paired regions, the color denotes the probability of being paired. For unpaired regions, the color denotes the probability of being unpaired. The following parameters were used: minimum free energy (MFE) and partition function, avoid isolated base pairs, Incorporate G–Quadruplex formation into the structure prediction algorithm, dangling energies on both sides of a helix in any case, RNA parameters (Andronescu model, 2007)

Lorenz, R. and Bernhart, S.H. and Höner zu Siederdissen, C. and Tafer, H. and Flamm, C. and Stadler, P.F. and Hofacker, I.L. "ViennaRNA Package 2.0", Algorithms for Molecular Biology, 6:1 page(s): 26, 2011.

Characterization

The part was tested as the composite part BBa_K4811027 in E. coli BL21(DE3), where the TMS is induced by IPTG. This construct was USER cloned into the high copy number pUC19 backbone for testing. A reporter, consisting of BBa_K4811003 was USER cloned into the low copy number pACYC184 backbone. This has mCherry, under control of the pBAD promoter, meaning L-arabinose will induce mCherry transcription. The mCherry transcript has the RBS BBa_K4811000 incorporated, meaning that translation of mCherry should be inhibited by the TMS, if the inhibiting capabilities are conserved upon changing the D-loop.

A general schematic of the system to be tested can be seen below: pu01-pu0x.png

Figure 2. mCherry is induced by L-ara, and the TMS is induced by IPTG. The hypothesis is, that the TMS is able to repress translation of mCherry, by binding to the RBS, and that a ligand, in this case PFOA is able to bind to the TMS, releasing the mCherry RBS of the TMS, allowing translation to begin.

The two plasmids were co-transformed into the same BL21(DE3) and transformants were verified by PCR and named BL21(DE3).pU01.pU12. The culture was grown overnight in LB + Cam + Amp. In the morning, the culture was reinoculated to an OD600 of 0.05, and set to incubate for 2 h, to achieve an OD600 of 0.4-0.6. Induction was done in quadruplicates. For each PFOA concentration to be tested, 100 ul E. coli culture was added 1 mM IPTG and 0.1 % w/v L-ara, PFOA in varying concentrations, and then MQ water for a total volume of 200 ul, to try to make the PFOA concentration the only variable. As control there was a uninduced culture, which was just 100 ul E. coli and 100 ul MQ (uninduced), as well as a culture only induced by 1 mM IPTG, with no L-arabinose (IPTG), and one only induced by 0.1 % w/v L-arabinose, with no IPTG (L-ara).

Induction was allowed for 5 h at 37 degrees Celcius, however, the OD had not changed much. Therefore, the cultures were allowed to be induced for an additional 13 h overnight, for a total induction time of 18 h.

OD660 was measured for 100 ul of each culture in a see-through microtiter plate, and mCherry fluorescence was measured using 561 nm excitation and 617 nm emission in black UV microtiter plates. Measurements were done using a SpectraMax iD3.

The following graph shows the data obtained:

Figure 3. OD normalized relative mCherry fluorescence, 561 nm excitation/617 nm emission, as a function of PFOA concentration. All measurements were with 1 mM IPTG and 0.1 % w/v L-arabinose, except the controls. As controls there is a culture induced with only 1 mM IPTG (IPTG), one only induced by 0.1 % w/v L-arabinose (L-ara), and one with no inducers present (uninduced)

The observed results are the opposite of what is reported by A. Paul with the GFP aptamer tested by them. Here, GFP was reported to stabilize the TMS, releasing it from the RBS, allowing translation to happen. What we showed with this data is, that for the TMS(PFOA1), it seems that addition of PFOA leads to a decrease in mCherry fluorescence.

One model explaining this could be, that PFOA changes the conformation of the TMS to one where it is able to bind to the RBS, and therefore an increase in PFOA concentration leads to a lower mCherry fluorescence.

Figure 4. The results showed PFOA concentration leading to a lower fluorescence, possibly by TMS binding to the RBS BBa_K4811000. The model show here would explain these results.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal XhoI site found at 93
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


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