Difference between revisions of "Team:Waterloo/InDepthDesign/Crispr"

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       <h3 class="header-text"><span style="color: white; background-color: #000;opacity: 0.8;">CRISPR</span></h3>
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       <h3 class="header-text"><span style="color: white; background-color: #000;opacity: 0.8;">CRISPRi</span></h3>
 
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     <p>CRISPR (clustered regularly interspaced short palindromic repeats) is a system used for targeting specific sites of a genome. The system is comprised of a Cas protein and an sgRNA which is a short guide RNA, usually about 20nt, which specifies the target site on the genome. CRISPR is a very popular tool in genome editing because of its ability to cut specific sites, however it was originally discovered as an adaptive immune system in bacteria. This function of the CRISPR system allows for a targeted knockout of a protein in question.
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      <p>Figure 1: CRISPR action, demonstrating how Cas9 binds to sgRNA to cleave target DNA.</p>
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     <p>CRISPR (clustered regularly interspaced short palindromic repeats) is a system used for targeting specific sites of a genome (Cong, 2013; Jinek, 2012). The system is comprised of a Cas protein and an sgRNA which is a short guide RNA, usually about 20nt, which specifies the target site on the genome(Cong, 2013; Jinek, 2012). CRISPR is a very popular tool in genome editing because of its ability to cut specific sites, however it was originally discovered as an adaptive immune system in bacteria (Doudna, 2014). This function of the CRISPR system allows for a targeted knockout of a protein in question.
 
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     Application for our System
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     Application for PriON to PriOFF
 
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     <p>Our system allows for an automatic upregulation of a protein which enables researchers to see if a protein can cure a Psi+ response. It would also be useful to be able to see if supressing the expression of a protein can cure the Psi+ response. For instance, upregulating HSP104 can cure the response by refolding misfolded SUP35 but downregulating HSP104 can also cure the response because the SUP35 aggregates need HSP104 in order to replicate. Adding a CRISPR system behind a stop codon, which targets a protein can cause downregulation of that protein during a Psi+ state.</p>
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     <p>Our system is a tool that allows the overexpression a protein of interest, which could be used to determine if the protein can slow the [PSI+] response or even cure it. It would also be useful to see if the opposite (a decrease in the expression of a protein of interest) could have similar effects. For instance, overexpressing hsp104 can cure the response by breaking down and refolding misfolded sup35, but knocking down hsp104 expression can also cure the response because the sup35 aggregates need hsp104 in order to replicate. The addition of a CRISPR interference system using dCas9 allows the targeting a protein of interest to cause this knockdown of expression. If we use our system to insert a premature stop codon in front of the CRISPR gene, then it will only be expressed during a [PSI+] state.</p>
 
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     dCas9
 
     dCas9
 
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      <p>Figure 2: CRISPRi knockdown action, demonstrating how dCas9 binds to sgRNA to prevent expression.</p>
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     <p>Most CRISPR systems use a Cas protein called Cas9 which makes a cut after binding to the DNA. Our system would use dCas9 which is a Cas protein that binds to a site and prevents transcription of that protein. This acts as a more reliable method for knocking out a protein, since cuts can sometimes be repaired effectively through non-homologous end joining. </p>
 
     <p>Most CRISPR systems use a Cas protein called Cas9 which makes a cut after binding to the DNA. Our system would use dCas9 which is a Cas protein that binds to a site and prevents transcription of that protein. This acts as a more reliable method for knocking out a protein, since cuts can sometimes be repaired effectively through non-homologous end joining. </p>
 
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     PAM Sites
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     sgRNAs
 
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     <p>All sgRNAs must start with a certain sequence of nucleotides called a PAM site. This is so that the Cas protein can bind to the DNA before reading the specific sequence. The most common PAM site is NGG... something something, yeast.</p>
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     <p>All sgRNAs must start with a certain sequence of nucleotides called a PAM site, or protospacer adjacent motif. This sequence is recognised by the Cas protein and is thus necessary for it to bind to the sgRNA. The sgRNA recognises the target DNA, thereby acting as an intermediate between the Cas protein and the target. The most common PAM site is NGG where N is any nucleotide.</p>
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    <p>The target DNA must be carefully chosen in order to avoid accidentally targeting genes important to the host organism, in this case <i>Saccharomyces cerevisiae</i>. CRISPR-Cas systems have been effectively employed in yeast hosts on a number of occasions, indicating that our intentions to do the same have a good chance of success (DiCarlo, 2013; 2015; Smith 2016).</p>
 
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    References
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  References
 
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     <p>Cong, L., Ran, F.A., Cox, D., Lin, S., Barretto, R., Habib, N., Hsu, P.D., Wu, X., Jiang, W., Marraffini, L.A., & Zhang, F., 2013. Multiplex genome engineering using CRISPR/Cas systems. <i>Science</i> Feb 15;339(6121):819-23.</p>
     <li>Weinhandl, K., Winkler, M., Glieder, A., and Camattari, A. (2014). Carbon source dependent promoters in yeasts. <i>Microbial Cell Factories, 13:5.</i>
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     <p>DiCarlo, J.E. et al., 2013. Genome engineering in Saccharomyces cerevisiae using CRISPR-Cas systems. <i>Nucleic acids research</i>, 41(7), pp.4336–43.</p>
    </li>
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     <p>DiCarlo, J.E. et al., 2015. Safeguarding CRISPR-Cas9 gene drives in yeast. <i>Nature Biotechnology</i>, 33(12), pp.1250–1255.</p>
    <li> Mumberg, D., Müller, R., and Funk, M. (1994). Regulatable promoters of Saccharomyces cerevisiae: comparison of transcriptional activity and their use for heterologous expression. <i>Nucleic Acids Research, 22:25.</i> 5767-5768.
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     <p>Doudna, J.A. & Charpentier, E., 2014. The new frontier of genome engineering with CRISPR-Cas9. <i>Science</i>, 346(6213), pp.1258096–1258096.</p>
    </li>
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     <p> Jinek, M. et al., 2012. A Programmable Dual-RNA–Guided DNA Endonuclease in Adaptive Bacterial Immunity. <i>Science</i>, 337(6096), p.816 LP-821.</p>
    <li>Solow, S. P., Sengbusch, J., and Laird, M. W. (2005). Heterologous protein production from the inducible MET25 promoter in Saccharomyces cerevisiae. <i>Biotechnology Progress, 21:2.</i> 617-620.
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     <p>Smith, J.D. et al., 2016. Quantitative CRISPR interference screens in yeast identify chemical-genetic interactions and new rules for guide RNA design. <i>Genome Biology</i>, 17(1), p.45.</p>
    </li>
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    <li>Thomas, D., Cherest, H., and Surdin-Kerjan, Y. (1989). Elements Involved in S-Adenosylmethionine-Mediated Regulation of the Saccharomyces cerevisiae MET25 Gene. <i>Molecular and Cellular Biology, 9:8.</i> 3292-3298.
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     <li>Flick, J. S., and Johnston, M. (1990). Two Systems of Glucose Repression of the GAL] Promoter in Saccharomyces cerevisiae. <i>Molecular and Cellular Biology, 10:9.</i> 4747-4769.
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    </li>
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    <li>Mumberg, D., Müller, R., and Funk, M. (1994). Regulatable promoters of Saccharomyces cerevisiae: comparison of transcriptional activity and their use for heterologous expression. <i>Oxford University Press 22:25.</i> 5767-5768.
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     </li>
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    <li>Mascorro-Gallardo, J.O., Covarrubias, A. A., and Gaxiola, R. (1996). Construction of a CUP1 promoter-based vector to modulate gene expression in Saccharomyces cerevisiae. <i>Gene, 172:1.</i> 169-170.  
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    </li>
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     <li>Koller, A., Valesco, J., and Subramani, S. (2000). The CUP1 promoter of Saccharomyces cerevisiae is inducible by copper in Pichia pastoris. <i>Yeast, 16.</i> 651-656.
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    </li>
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     <li>Weinhandl, K, Winkler, M., Glieder, A., Camattari, A. (2014). Carbon source dependent promoters in yeasts. <i>Microbial Cell Factories, 13:5.</i>  
+
    </li>
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    <li>Ruohonen, L., Aalto, M. K., Keänen, S. (1995). Modifications to the ADH1 promoter of Saccharomyces cerevisiae for efficient production of heterologous proteins. <i>Journal of biotechnology, 39:3.</i> 193-20.
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    </li>
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     <li>Partow, S., Siewers, V., Bjøm, S., Nielsen, J., Jérôme, M. (2010). Characterization of different promoters for designing a new expression vector in Saccharomyces cerevisiae. <i>Yeast, 27.</i> 955-964.
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Latest revision as of 02:52, 20 October 2016

Lab and Design
Math Modelling

CRISPRi

Summary

Figure 1: CRISPR action, demonstrating how Cas9 binds to sgRNA to cleave target DNA.

CRISPR (clustered regularly interspaced short palindromic repeats) is a system used for targeting specific sites of a genome (Cong, 2013; Jinek, 2012). The system is comprised of a Cas protein and an sgRNA which is a short guide RNA, usually about 20nt, which specifies the target site on the genome(Cong, 2013; Jinek, 2012). CRISPR is a very popular tool in genome editing because of its ability to cut specific sites, however it was originally discovered as an adaptive immune system in bacteria (Doudna, 2014). This function of the CRISPR system allows for a targeted knockout of a protein in question.

Application for PriON to PriOFF

Our system is a tool that allows the overexpression a protein of interest, which could be used to determine if the protein can slow the [PSI+] response or even cure it. It would also be useful to see if the opposite (a decrease in the expression of a protein of interest) could have similar effects. For instance, overexpressing hsp104 can cure the response by breaking down and refolding misfolded sup35, but knocking down hsp104 expression can also cure the response because the sup35 aggregates need hsp104 in order to replicate. The addition of a CRISPR interference system using dCas9 allows the targeting a protein of interest to cause this knockdown of expression. If we use our system to insert a premature stop codon in front of the CRISPR gene, then it will only be expressed during a [PSI+] state.

dCas9

Figure 2: CRISPRi knockdown action, demonstrating how dCas9 binds to sgRNA to prevent expression.

Most CRISPR systems use a Cas protein called Cas9 which makes a cut after binding to the DNA. Our system would use dCas9 which is a Cas protein that binds to a site and prevents transcription of that protein. This acts as a more reliable method for knocking out a protein, since cuts can sometimes be repaired effectively through non-homologous end joining.

sgRNAs

All sgRNAs must start with a certain sequence of nucleotides called a PAM site, or protospacer adjacent motif. This sequence is recognised by the Cas protein and is thus necessary for it to bind to the sgRNA. The sgRNA recognises the target DNA, thereby acting as an intermediate between the Cas protein and the target. The most common PAM site is NGG where N is any nucleotide.

The target DNA must be carefully chosen in order to avoid accidentally targeting genes important to the host organism, in this case Saccharomyces cerevisiae. CRISPR-Cas systems have been effectively employed in yeast hosts on a number of occasions, indicating that our intentions to do the same have a good chance of success (DiCarlo, 2013; 2015; Smith 2016).

References

Cong, L., Ran, F.A., Cox, D., Lin, S., Barretto, R., Habib, N., Hsu, P.D., Wu, X., Jiang, W., Marraffini, L.A., & Zhang, F., 2013. Multiplex genome engineering using CRISPR/Cas systems. Science Feb 15;339(6121):819-23.

DiCarlo, J.E. et al., 2013. Genome engineering in Saccharomyces cerevisiae using CRISPR-Cas systems. Nucleic acids research, 41(7), pp.4336–43.

DiCarlo, J.E. et al., 2015. Safeguarding CRISPR-Cas9 gene drives in yeast. Nature Biotechnology, 33(12), pp.1250–1255.

Doudna, J.A. & Charpentier, E., 2014. The new frontier of genome engineering with CRISPR-Cas9. Science, 346(6213), pp.1258096–1258096.

Jinek, M. et al., 2012. A Programmable Dual-RNA–Guided DNA Endonuclease in Adaptive Bacterial Immunity. Science, 337(6096), p.816 LP-821.

Smith, J.D. et al., 2016. Quantitative CRISPR interference screens in yeast identify chemical-genetic interactions and new rules for guide RNA design. Genome Biology, 17(1), p.45.