Difference between revisions of "Part:BBa K1062004"
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===Prediction=== | ===Prediction=== | ||
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− | Before the experiments, | + | Before the experiments, model proved our ideas. The predication shows the possibilities of different expression levels by different Csy4 mutants. It is not difficult to predict that the cleavage rate has an influence in the expression of sfGFP. |
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[[Image:T--OUC-China--prediction.jpg|center|thumb|500px|'''Fig.4 The predication: The fluorescence intensities by different Csy4 mutants along with time.''']] | [[Image:T--OUC-China--prediction.jpg|center|thumb|500px|'''Fig.4 The predication: The fluorescence intensities by different Csy4 mutants along with time.''']] | ||
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+ | We designed three kinds experiments to test the capabilities of five Csy4 mutants by putting them into miniToe system. So the recombination strains for test both have same pReporter but different Csy4 mutants plasmids in the following. The recombination strains to test the functions of Csy4 are strain-Csy4 (pCsy4&pReporter), strain-Csy4-Q104A (pCsy4-Q104A&pReporter), strain-Csy4-Y176F (pCsy4-Y176F&pReporter), strain-Csy4-F155A (pCsy4-F155A&pReporter), strain-Csy4-H29A (pCsy4-H29A&pReporter). At the same time, we have a control strain named strain-miniToe-only which only has pReporter. | ||
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Revision as of 02:06, 18 October 2018
Csy4
Csy4 is an enzyme that is essential to the creation of gRNAs. Csy4 is a member of CRISPR family.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal NgoMIV site found at 353
- 1000INCOMPATIBLE WITH RFC[1000]Illegal SapI site found at 69
Usage and Biology
Conjugation Project
Synthetic Circuit
2018 OUC-China
Csy4 (Csy6f), a member of CRISPR family.
===Csy4 (Csy6f), a member of CRISPR family.===
<p>
The endoribonuclease Csy4 from CRISPR family is the main role of miniToe system. Csy4 (Cas6f) is a 21.4 kDa protein which recognizes and cleaves a specific 22nt RNA hairpin. In type I and type III CRISPR systems, the specific Cas6 endoribonuclease splits the pre-crRNAs in a sequence-specific way to generate 60-nucleotide (nt) crRNA products in which segments of the repeat sequence flank the spacer (to target "foreign" nucleic acid sequence) [1]. Inactivation of the Cas proteins leads to a total loss of the immune mechanism function.
Background of 2018 OUC-China' project
This year, we designed and achieved a gene regulatory toolbox based on CRISPR RNA endonucleases Csy4 for post-transcriptional regulation. A rational designed modular RNA fragment named miniToe was utilized for precise and efficient translational regulation. The miniToe module was constructed through inserting a 22 nt Csy4 recognition site between RBS and a cis-repressive RNA element, which is able to mask the RBS region and inhibit translation initiation. By up-regulating the level of Csy4 in cell as input, the miniToe module will be cleaved and releases an exposed RBS for output translation. As our innovation, we further designed four Csy4 mutants and five mutated miniToe module in a predictable way by modeling, which aims at enriching our toolkit
for diverse regulation ranges on target genes. The whole toolbox includes ten
combinations of different Csy4 mutants and miniToe modules, which is called
miniToe family.
Proof of functions about Csy4 family
We have done three kinds of experiments to help us confirm the function of the Csy4 family. Our aim is to get some new Csy4 mutants with different cleavage capacity, so we specifically tested this aspect of them. For testing our system, we use the superfold green fluorescent protein (sfGFP) as our target gene. Our expectation is that the fluorescence intensities of sfGFP can vary upon the rates of Csy4s’ cleavage. That means we have improved four new parts which present various expression of target genes.
Prediction
Before the experiments, model proved our ideas. The predication shows the possibilities of different expression levels by different Csy4 mutants. It is not difficult to predict that the cleavage rate has an influence in the expression of sfGFP.
We designed three kinds experiments to test the capabilities of five Csy4 mutants by putting them into miniToe system. So the recombination strains for test both have same pReporter but different Csy4 mutants plasmids in the following. The recombination strains to test the functions of Csy4 are strain-Csy4 (pCsy4&pReporter), strain-Csy4-Q104A (pCsy4-Q104A&pReporter), strain-Csy4-Y176F (pCsy4-Y176F&pReporter), strain-Csy4-F155A (pCsy4-F155A&pReporter), strain-Csy4-H29A (pCsy4-H29A&pReporter). At the same time, we have a control strain named strain-miniToe-only which only has pReporter. The qualitative experiments by fluorescent microscope
First, we have tested five different groups by Fluorescent Stereo Microscope Leica M165 FC. The sfGFP accumulated during the cultivation period so the fluorescence can be observed by microscope after 8 hours. Because the five Csy4 mutants have different capabilities of cleavage, the distinguishing intensities of fluorescent can be seen by naked eyes. The five test strains have same miniToe part but different Csy4 mutant genes. From top to bottom in Fig.5, there are fluorescence images by fluorescent microscope which indicate strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A in sequence. The visible distinctions have shown in these images. The fluorescence intensities decrease one by one from top to bottom which means the Csy4s' capabilities of cleavage decrease one by one. The Csy4-WT has the strongest capability of cleavage when the Csy4-H29A is a kind of dead-Csy4 (dCsy4) which is hardly to find the fluorescence by microscope. The qualitative experiment is a basis of further experiments.
From top to bottom, the images shows the expression of sfGFP by strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A in sequence. The plotting scale is on the right corner of images. The images on the left shows E. coli without fluorescence excitation. The images on the right represent situation when fluorescence excitation. The result by flow cytometer
The qualitative experiment is not enough to analyze the Csy4 mutants. So we tested miniToe family system by flow cytometer. The expression of sfGFP by strain-Csy4, strain-Csy4-Q104A, strain-Csy4-Y176F, strain-Csy4-F155A and strain-Csy4-H29A is showed in Fig.6. We find that 5 groups' fluorescence intensities have an obvious order from Csy4-WT to Csy4-H29A, which means the capabilities decrease one by one. Their order goes from strong to weak is Csy4-WT, Csy4-Q104A, Csy4-Y176F,Csy4-F155A and Csy4-H29A.
The result by microplate reader
Besides all the works before, we also need to know more information about the Csy4 mutants in entire cultivation period. Even though we known that our Csy4 mutants have differentiated expression level in ten-hour-culture, the expression of whole cultivation period is also a reference for us to know if our system can work as expectations.
By all the experiments mentioned before, we proved that Csy4 mutants work as expectations successfully. The results are listed in the order: Csy4-WT>Csy4-Q104A>Csy4-Y176F>Csy4-F155A>Csy4-H29A. And the original sequences of Csy4 part has been submitted by other iGEM teams before, so this year we improved their work by enlarging Csy4 to a Csy4 family. In summary
This year, we used point mutations to redesign four mutants on the basis of Csy4(BBa_K1062004) which are Csy4-Q104A(BBa_K2615004), Csy4-Y176F(BBa_K2615005), Csy4-F155A(BBa_K2615006) and Csy4-H29A(BBa_K2615007). The capabilities of cleavage and recognition are different for each Csy4 mutants, and we name them the Csy4 family. The combination of the Csy4 family members and the miniToe family members constitute a post-transcriptional regulatory toolkit for achieving different expression levels of target genes.
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