Part:BBa_K3380500

iSpinach fluorescent RNA aptamer construct under T7 RNA polymerase promoter (BBa_z0251)

The Edinburgh iGEM team 2020 designed a construct comprising a fluorescent RNA aptamer (iSpinach BBa_K3380150) flanked by a tRNA scaffold (F30 BBa_K3380101 and BBa_K3380102) under a strong class III T7 RNA polymerase promoter (BBa_z0251). It was designed to test the fluorescence intensity of the iSpinach aptamer flanked by F30 tRNA scaffold when binding to the DFHBI fluorophore. The construct is capable of exhibiting fluorescence being a transcription only construct. Simultaneously we tested the efficiency of transcription in the absence of a terminator. The T7 RNA polymerase is capable of synthesizing transcripts via run-off transcription in the absence of a terminator. Figure 1 illustrates a schematic design of the construct.

Figure 1: Construct BBa_K3380500 design. The iSpinach fluorescent RNA aptamer (shown in green) was flanked by the F30 upstream and downstream scaffolds (shown in blue) to protect it from the RNAse degradation (from the cell free extract), it was expressed under the Class III strong T7 RNA polymerase promoter BBA_z0251 (shown in black).

Usage and Biology

It can be used in cell-free extracts or buffers containing T7 RNA polymerase, chemical energy (ATP), NTPs, fluorophore and adequate cofactors and pH to test the fluorescence intensity of the iSpinach aptamer (BBa_K3380150) when bound to fluorophores under the T7 promoter. It might exhibit lower fluorescence, due to degradation by the RNAses, depending on the cell extract it is used in. However, the absence of the scaffold can also improve the fluorescence, as in the example of Broccoli fluorescent RNA aptamer.

The construct functioning solely on transcription and having a small length of only 195 nucleotides has multiple advantages over the conventional fluorescent proteins. The time required for the fluorescence formation is much shorter than compared to the time needed for the synthesis of the fluorescent proteins. Moreover, there is less burden exhibited on the cell (if expressed in cells) or it requires less resources (NTPs, energy if expressed in cell free extract) when expressing the transcription only construct. Also, individual parts can be "de novo" synthesized and ligated rather than expressing them in cells using plasmids, which is more expensive and requires more time.

Figure 2 shows the effects of the DHBI fluorophore addition to the construct BBa_K3380500 over time.

Figure 2. Impact of DFHBI fluorophore addition to the construct BBa_K3380500 over time. Each time point has 3 PCR tubes: the first one containing the construct + DFHBI fluorophore, second once having the fluorophore and no construct and the 3rd one having no T7 RNA polymerase added. The fluorescence was imaged under a Safe Imager™ Blue-Light Transilluminator (Invitrogen) with an amber filter unit and a phone camera. The details regarding the assembling process can be found in the Experience page of this construct[1].

iGEM team Edinburgh 2020 tried to test and see if the fluorescence of the construct can be observed with the naked eye for easier identification. Figure 3 shows the results of the fluorophore addition after 19 hours with and without a filter.

Figure 3 Impact of DFHBI fluorophore addition to the construct BBa_K3380500 after 19h with and without a filter. Each photo has 3 PCR tubes: the first one containing the construct + DFHBI fluorophore, second once having the fluorophore and no construct and the 3rd one having no T7 RNA polymerase added. The fluorescence (image on the left) was imaged under a Safe Imager™ Blue-Light Transilluminator (Invitrogen) with an amber filter unit and a phone camera. The fluorescence (image on the right) was imaged with a phone camra. The details regarding the assembling process can be found in the Experience page of this construct[2].

Sequence and Features