Difference between revisions of "Part:BBa K4765129"
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| − | | '''Figure 4. The 96 well plate of bacterial cultures.''' | + | | '''Figure 4. The bottom view of the 96 well plate of bacterial overnight cultures.''' Some wells are very red, comparing with surrounding, suggest high leaky expression from T7 promoter. |
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Revision as of 13:28, 12 October 2023
stem-loop test
Contents
Introduction
In synthetic biology, it's common to integrate multiple heterologous genes into genetic circuits. Conventional approaches often utilize a polycistron system, where several genes are regulated under a single promoter. However, this can lead to reduced expression of downstream genes[1].
In ribozyme-assisted polycistronic co-expression system (pRAP)[2], the RNA sequence of ribozyme between coding sequences (CDSs) can conduct self-cleavage and convert polycistron into mono-cistrons in vivo. Self-interaction of the polycistron can be avoided and each mono-cistron can initiate translation with efficiency.
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| Figure 1. Principle of pRAP system. |
In the pRAP system, stem-loop is a key regulatory element that affects protein concentration by regulating the rate of mRNA degradation [3]. By regulating the intensity of stem-loop, we can control the expression of proteins.
This year, we developed a quantitive pRAP system design software, and we also construct this composite part BBa_K4765129 (stem-loop test) to verify that we can control protein expression by changing stem-loop.
This composite includes T7 promoter, lac promoter, stayGold, Twister P1 (self-cleaving ribozyme), mScarlet, and T7 terminator, which is a stem-loop-deleted version of BBa_K4765120. We inserted different stem-loops between stayGold and Twister P1, and compared the red-green fluorescence intensity ratio to assess the stem-loop's ability to prevent mRNA degradation.
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| Figure 2. Biobricks in BBa_K4765129. |
Usage and Biology
Using our [http://54.169.242.254:5000/ software], we designed and tested different stem-loops' ability to prevent mRNA degradation, using this composite part.
nsl: no stem-loop
liu2023: natural occurred, described previously
new2/6/10 & old6/10: stem-loops designed by our software with different free energy change of reaction
nsl: 5-AAACACCCACCACAAUUUCCACCGUUU UUUGU-3 liu2023: 5-AAACACCCACCACAAUUUCCACCGUUU CCCGACGCUUCGGCGUCGGG UUUGU-3 new2: 5-AAACACCCACCACAAUUUCCACCGUUU CCCCGUCGGCUGCU UUUGU-3 new6: 5-AAACACCCACCACAAUUUCCACCGUUU AGACGCUCGGCGUCCU UUUGU-3 new10: 5-AAACACCCACCACAAUUUCCACCGUUU ACUGGGGGGAUCGAGGUCUUU UUUGU-3 old6: 5-AAACACCCACCACAAUUUCCACCGUUU AGACGCUCGGCGUCCU UUUGU-3 old10: 5-AAACACCCACCACAAUUUCCACCGUUU GGCGGCGCUACAGCGUCGU UUUGU-3
Characterization
Sequencing Map
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| Figure 3. Sequencing result of nsl (no stem-loop before Twister ribozyme cleavage site). Sanger sequencing verified that we have removed the stem-loop before ribozyme sequence, from BBa_K4765120. We also construct plasmids with stem-loop new2, new6, new10, old6, old10, all of which were designed by our Software RAP, and fully characterized using functional assays. |
Microplate Reader Assay
1. Bacterial Culture: Following plasmid transformation and plating, use pipette tip to select monoclonal colony and culture for 24 hrs in a 96-well plate within incubator with gentle aggitation set at 37℃.
2. Sample Preparation: Transfer 25 μL of the bacterial culture from each well into another 96-well plate and dilute them with 75 μL of PBS.
3. Fluorescence Measurement: Use the microplate reader to measure GFP/RFP fluorescence. Set the excitation wavelength at 485/540 nm and the emmison wavelength at 528/620 nm.
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| Figure 4. The bottom view of the 96 well plate of bacterial overnight cultures. Some wells are very red, comparing with surrounding, suggest high leaky expression from T7 promoter. |
Experimental Results
Our experimental findings unveiled a clear connection: as the change in free energy (ΔG) within the reaction decreases, mRNA stability increases, resulting in a higher GFP/RFP ratio. In summary, designing stem-loops with lower ΔG values enhances their ability to shield mRNA from degradation.
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| Figure 5. The relationship between the free enegy of stem-loop and GFP/OD and RFP/OD. |
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| Figure 6. The relationship between the free enegy of stem-loop and mRNA degradation rate. |
Summary
In conclusion, this composite part represents a novel attempt to employ 3' stem-loops for regulating mRNA stability. It can to be a better strategy to regulate the protein ratios than changing 5' RBS since it minimizes the likelihood of interfering with the coding sequence (CDS).
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12INCOMPATIBLE WITH RFC[12]Illegal NotI site found at 1389
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000INCOMPATIBLE WITH RFC[1000]Illegal BsaI.rc site found at 700
Illegal BsaI.rc site found at 720
Reference
- ↑ Kim, K.-J., Kim, H.-E., Lee, K.-H., Han, W., Yi, M.-J., Jeong, J., & Oh, B.-H. (2004). Two-promoter vector is highly efficient for overproduction of protein complexes. Protein Science: A Publication of the Protein Society, 13(6), 1698–1703. https://doi.org/10.1110/ps.04644504
- ↑ Liu, Y., Wu, Z., Wu, D., Gao, N., & Lin, J. (2022). Reconstitution of Multi-Protein Complexes through Ribozyme-Assisted Polycistronic Co-Expression. ACS Synthetic Biology, 12(1), 136–143. https://doi.org/10.1021/acssynbio.2c00416
- ↑ Newbury, S. F., Smith, N. H., & Higgins, C. F. (1987). Differential mRNA stability controls relative gene expression within a polycistronic operon. Cell, 51(6), 1131–1143. https://doi.org/10.1016/0092-8674(87)90599-x