Difference between revisions of "Part:BBa K1614019"
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===Usage and Biology=== | ===Usage and Biology=== | ||
− | In 2011 Jaffrey selected the famous Spinach RNA aptamer | + | In 2011 Jaffrey selected the famous Spinach RNA aptamer. It binds a small molecule that resembles the fluorophore of the green fluorescent protein (GFP)(Jaffrey, 2011). Upon binding of the small molecule to the Spinach a green fluorescence comparable to that of the GFP is emitted. In our project we use variants of these fluorescent aptamers and engineer them to be dependent on small molecules of our interest. |
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This BioBrick is cloned into the RFC and contains a improved Spinach2.1 which was generated by the iGEM Team DTU Danemark in 2014.This ATP Aptamer JAWS1 Spinach 2.1 is a fusion of the BBa_K1330000 generated by DTU Danemark. According to our results, this fusion should contain the same properties as BBa_K1614014. Yet, this Spinach2.1 is ligand dependend to ATP and should find its use in the detection of the small molecule ATP. Applications such as nucleotide sensing during in vitro transcription are possible. For more information check BBa_K1614014. | This BioBrick is cloned into the RFC and contains a improved Spinach2.1 which was generated by the iGEM Team DTU Danemark in 2014.This ATP Aptamer JAWS1 Spinach 2.1 is a fusion of the BBa_K1330000 generated by DTU Danemark. According to our results, this fusion should contain the same properties as BBa_K1614014. Yet, this Spinach2.1 is ligand dependend to ATP and should find its use in the detection of the small molecule ATP. Applications such as nucleotide sensing during in vitro transcription are possible. For more information check BBa_K1614014. |
Revision as of 19:33, 20 September 2015
ATP Aptamer JAWS1 Spinach 2.1
This part was developed as a tool to sense ATP consumption within biochemical reactions. This part is cloned into the RFC 110 and can be transcribed using the T7 RNA Polymerase.
Usage and Biology
In 2011 Jaffrey selected the famous Spinach RNA aptamer. It binds a small molecule that resembles the fluorophore of the green fluorescent protein (GFP)(Jaffrey, 2011). Upon binding of the small molecule to the Spinach a green fluorescence comparable to that of the GFP is emitted. In our project we use variants of these fluorescent aptamers and engineer them to be dependent on small molecules of our interest.
This BioBrick is cloned into the RFC and contains a improved Spinach2.1 which was generated by the iGEM Team DTU Danemark in 2014.This ATP Aptamer JAWS1 Spinach 2.1 is a fusion of the BBa_K1330000 generated by DTU Danemark. According to our results, this fusion should contain the same properties as BBa_K1614014. Yet, this Spinach2.1 is ligand dependend to ATP and should find its use in the detection of the small molecule ATP. Applications such as nucleotide sensing during in vitro transcription are possible. For more information check BBa_K1614014.
Proporties of the ATP Aptamer JAWS1 Spinach2
ATP Aptamer JAWS1 Spinach 2.1 is a fusion of the BBa_K1330000 generated by DTU Danemark. According to our results, this fusion should contain the same properties as BBa_K1614014. Yet, this Spinach 2.1 is ligand dependend to ATP and should find its use in the detection of the small molecule ATP. Applications such as nucleotide sensing during in vitro transcription are possible. For more information check BBa_K1614014. Another biobrick, the ATP Aptamer JAWS1 Spinach2 (BBa_K1614014) was designed in this project as well. Similar to the biobrick BBa_K1614012, we performed in vitro transcriptions to sense ATP in real-time. The construct is a fusion of an ATP aptamer (Sassanfar 1993) and Spinach2 (Strack 2013), which we will call Spinach2-ATP-Aptamer system . To improve the binding of the ATP aptamer to ATP we apply our own implemented JAWS software (Fig. 1). Using our software, nucleotides which form the stem region of the ATP aptamer can be predicted, which will improve binding properties of this RNA to ATP advanced the stemming behavior of the ATP Aptamer which was then fused to the Spinach2. Measurements with the spectro fluorometer show that the ATP Aptamer JAWS1 Spinach2 (BBa_K1614014) has a lower fluorescence than ATP Aptamer JAWS2 Spinach2 (BBa_K1614015)(Fig.2) which is caused by a weaker steming behavior. Therefore ATP Aptamer JAWS1 Spinach2 is a better candidate for sensing ATP changes during biochemical reactions such as the in vitro transcription. For the in vitro transcription assay the RNA was renatured in 1x Renaturing buffer at 95 °C. 500 nM of the RNA was used for the in vitro transcription for measuring the ATP consumption during transcription. The construct was excited at 460 nm. Emission was measured at 500 nm. Experiments have shown that the detection range of this ATP sensor which correlates to the transcribed RNA is much more sensitive than traditional techniques that require UV-shadowing. The real time fluorescent readout system even allows the study of enzyme kinetics that depends on ATP (Fig.3).
References:
1.Sassanfar, M. and J.W. Szostak, An Rna Motif That Binds Atp. Nature, 1993. 364(6437): p. 550-553. 2.Strack, R.L. and S.R. Jaffrey, Live-cell imaging of mammalian RNAs with Spinach2. Methods Enzymol, 2015. 550: p. 129-46. 3. Strack, R.L., M.D. Disney, and S.R. Jaffrey, A superfolding Spinach2 reveals the dynamic nature of trinucleotide repeat-containing RNA. Nat Methods, 2013. 10(12): p. 1219-24.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21INCOMPATIBLE WITH RFC[21]Illegal BglII site found at 47
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]