Difference between revisions of "Team:Tsinghua/Description"

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          <h1 class="contentPage" id="tag_design">design</h1>
 
          <br>This project aims to establish a well-controlled gene mutation surveillance system to monitor
 
          <br> possible harmful gene mutations. When mutations occur, the surveillance system will detect and
 
          <br> trigger the suicidal system. The surveillance system can be further quantitatively optimized to
 
          <br>maximize its sensitivity and minimize potential side effects.
 
          <br>
 
 
          <h2 class="contentPage"><br>RNA targeting by CRISPR/Cas9 system</h2>
 
          To achieve the surveilling functions of the whole circuit, a suvCas9 is facilitated by an sgRNA
 
          <br> and a deoxynucleotide oligonucleotide (PAMmer) that hybridizes to the target RNA, providing
 
          <br> the PAM sequence<sup>[12]</sup>. suvCas9 plays an indispensable part in the coupling of mRNA recognition
 
          <br> system and the suicidal gene expression. suvCas9 performs high-fidelity mRNA binding activity,
 
          <br>of which the specificity is double-determined by sgRNA and PAMmer. This surveillance system is
 
          <br> composed of the dCas9 protein, sgRNA and PAMmer, forming a complex that can stably exist in the
 
          <br> cytoplasm and tightly bind to its targeted mRNA. When a mutation of the genes under surveillance
 
          <br> is detected by suvCas9, it can immediately trigger the suicidal system to eliminate the mutated
 
          <br> cell, avoiding further catastrophic consequences.
 
          <br>
 
          <h2 class="contentPage"><br><i>In vivo</i> generation of ssDNA by SCRIBE system</h2>
 
          In order to target mRNA in the cytoplasm, several concerns should be noticed<sup>[7]</sup>. First, the PAM
 
          <br> motif, essentially an ssDNA in our project, should be provided together with sgRNA pairs, the
 
          <br> presence of which are prerequisites for suvCas9 to acquire its activity. Second, the genomic
 
          <br> counterpart of transcripts should be prevented from being recognized and disrupted by suvCas9,
 
          <br>otherwise the surveillance system will contradict the purpose of maintaining high genomic fidelity.
 
          <br>The newly developed RNA targeting system<sup>[7]</sup> meets both criteria mentioned above: it creates the PAM motif
 
          <br> by introducing a special PAMmer sequence which is a mixed DNA and 2’-O-methyl RNA oligonucleotide,
 
          <br> and it avoids any unwanted targeting in the nucleus. However, the synthesis of such sequence is not
 
          <br> convenient, and the application in yeasts has not been tested before, not to mention such single-stranded
 
          <br> nucleotides are hard to be generated and replicated <i>in vivo</i>.
 
          <br>
 
          <br>The limitations of direct introduction of PAMmer sequence into yeast create a niche for us to find
 
          <br> alternative solutions: can we instead generate ssDNA within yeasts, as an integrated part of their
 
          <br> metabolic activities? It turns out that generating ssDNA in yeast cells is viable. SCRIBE (Synthetic
 
          <br> Cellular Recorders Integrating Biological Events)<sup>[8]</sup>, intrinsically an <i>in vivo</i> reverse transcription
 
          <br> system, can reversely transcribe ssDNA with plasmids as the template<sup>[9]</sup>. More importantly, the RNA
 
          <br> templates for reverse transcription are highly modularized, enabling effortless ssDNA switching and
 
          <br> thus the flexibility of mRNA targeting. In practice, the design of molecular cloning is relatively
 
          <br> convenient as well: a retron and an RNA template of the wanted ssDNA sequence can be assembled on the
 
          <br> same plasmid, enabling a one-step transformation in yeasts.
 
          <br>
 
          <h2 class="contentPage"><br>Coupling with cellular suicidal system</h2>
 
          Mutations in the targeted gene will cause instant translocation of suvCas9 complex, switching on the
 
          <br> suicidal gene expression to kill the mutated cell. Here we design to fuse dCas9 with the GAL4 binding
 
          <br> domain and its activation domain on the foundation of yeast one-hybrid system<sup>[13]</sup> that allows
 
          <br>the interaction of DNA-binding domain and the isolation of the targeted promoter and the downstream
 
          <br> gene. With the engineered <i>Saccharomyces cerevisiae</i> background strain<sup>[13]</sup> for one-hybrid system, the
 
          <br> interaction between the DNA-binding domain and the promoter containing recognition site will drive the
 
          <br> transcription of Thymine Kinase (TK) and RFP. Thymine Kinase<sup>[14]</sup> is a novel selection marker in yeast,
 
          <br>which is analogous to the widely used URA3 auxotrophy marker<sup>[15]</sup>, allowing both selection and
 
          <br> counter-selection in respective media. In the selection media, which is YP-glycerol with antifolates,
 
          <br> only yeast populations that produce thymine kinase can survive, while on the counter-selection media,
 
          <br> which is SC media with FUdR, only the absence of TK can ensure the viability of yeast. Mutations
 
          <br> in targeted genes will cause sequence changes in mRNA, which significantly decrease the binding
 
          <br> activity of suvCas9 onto mRNA. The previously sequestered suvCas9 complex will be transported into
 
          <br> nuclear immediately in the guidance of GAL4 binding domain and the exogenous Nuclear Localization
 
          <br> Sequence (NLS), and turn on the transcription of TK and RFP gene, which in turn cause the death of
 
          <br> cell on the counter-selection media and the fluorescence expression that can be quantitatively detected
 
          <br>by FACS for further optimization of our surveillance system.<br><br>
 
          <div style="margin-left:350px"><img src="https://static.igem.org/mediawiki/2016/b/b2/T--Tsinghua--figure1A.png"></div>
 
          <br>Figure 1A. A schematic overview of the targeting mechanism of suvCas9. suvCas9 can bind to a correct
 
          <br> mRNA in complex with sgRNA and PAMmer (illustrated above), which can then be translocated into the
 
          <br> nucleus and initiate a suicidal program whenever the mRNA is mutated (not shown). Specially designed
 
          <br> PAMmers will not disrupt the genomic sequence.
 
          <br>
 
          <br>
 
          <div style="margin-left:250px"><img src="https://static.igem.org/mediawiki/2016/3/3f/T--Tsinghua--figure1B.png"></div>
 
          <br>Figure 1B. Mechanism of the generation of ssDNA <i>in vivo</i>. A single strand DNA can be derived
 
          <br> from the reversely transcribed product by the retron (RT). Figures are adapted from (7) and (8).
 
          <br>
 
 
           <h2 class="contentPage"><br>Reference<img id="referenceButton" onclick="hideRef()" src="https://static.igem.org/mediawiki/2016/0/06/T--Tsinghua--details_open.png" style="align:center;"></h2>
 
           <h2 class="contentPage"><br>Reference<img id="referenceButton" onclick="hideRef()" src="https://static.igem.org/mediawiki/2016/0/06/T--Tsinghua--details_open.png" style="align:center;"></h2>
 
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Revision as of 15:13, 19 October 2016

Project

description


Background

The fidelity of genomic sequence is the underpinning aspect of normal cellular activities. Even a minor
disruption to DNA, the storage center of genetic information, can lead to detrimental consequences,
including excessive cell death, abnormal proliferation, untimely cell senescence, etc. For example,
genomic instability and mutation is considered as one of the ten hallmarks of cancer, the occurrence
of which generally leads to over-activation of signaling pathways, in turn triggering malignant
proliferation of cells[1]. Recurrent hot-spot DNA mutations and chromosomal rearrangements are
commonly observed in cancer samples. Genomic mutation is therefore a primary concern in terms of both
basic research and clinical treatment, demanding multi-disciplinary efforts.

In order to address this imperative issue, a gene mutation surveillance system that can sensitively and
efficiently detect and remove such aberrations to achieve real-time monitoring in vivo is required.
Essentially by designing such a system, a tool that can recognize aberrant mutation on mRNA sequences,
or more generally at the transcriptomics level, is desired, because transcripts are derived from
genomic sequences and hence are representatives of genomic instability and mutations. More importantly,
their availability and abundance in the cytoplasm allow them to be targeted. Nonetheless, few such
satisfying molecular tools have been developed yet. Consequently, to design such a surveillance
system is not only important but also necessary.

To serve such purpose, an RNA binding factor with high efficiency and sensitivity is a must, which
is able to distinguish RNA transcripts produced by mutated genes and switch on the suicidal gene
expression afterwards. There are three major RNA targeting methods currently: PUF proteins[2][3][4],
molecular beacons[5] and RNA aptamers[6]. Due to lack of specificity or stability in vivo, those existing
methods are not suitable for the potential application in our gene mutation surveillance system.
However, it is newly reported that dCas9[7], capable of recognizing specific endogenous mRNA
sequences, turns out to be an ideal candidate. Surveillance Cas9 (suvCas9), termed for the first time
by our team, is a variant of Cas9 without DNA cleavage activity and can target specific mRNA sequences
by manually designed sgRNA and PAM sequences. With this remarkable ability to target mRNA, suvCas9
can hopefully be adopted into our surveillance system as the monitor as well as the executor

We propose to construct suvCas9 system in Saccharomyces cerevisiae to function as the monitor
of genomic sequence. Saccharomyces cerevisiae is one of the most commonly used model organisms,
representing a simple eukaryote with a highly manipulatable genome. Apart from many physical properties
and technical advantages, such as rapid growth, minimal pathogenicity, the ease of phenotype identification,
a well-defined genetic system, and most importantly, a highly versatile DNA transformation system[11],
the yeast has been reported to share a similar characteristics of in vivo ssDNA generation by reverse
transcriptase with prokaryotes[9], which will guide suvCas9 to the targeted mRNA.

Project Overview

Genomic stability and DNA sequence fidelity are critical for normal cellular activities. If such storage
center of genetic information is disrupted, detrimental consequences will take place, including but not
limited to excessive cell death, abnormal proliferation, untimely cell senescence, etc. Therefore, a gene
mutation surveillance system that can sensitively and efficiently detect and remove such aberrations
in vivois required.


Saccharomyces cerevisiae is chosen as the model organism for designing such a gene surveillance system.
As one of the most commonly used tools, it not only has a highly manipulatable genome, rapid growth
speed, minimal pathogenicity, an ensemble of selectable markers, a well-defined genetic system, and most
importantly, a highly versatile DNA transformation system.

Essentially by designing such a system, a tool that can recognize aberrant mutation on mRNA sequences, or
more generally at the transcriptomics level, is desired, because transcripts are derived from genomic
sequences and hence are representatives of genomic instability and mutations. Surveillance Cas9 (suvCas9),
termed for the first time by our team, is a variant of Cas9 without DNA cleavage activity and can target
specific mRNA sequences by manually designed sgRNA and PAM sequences.

That being said, after mutation is detected on mRNAs, how can our system respond? In a nutshell, when
mutations occur, the surveillance system will detect and trigger the suicidal system. The surveillance
system can be further quantitatively optimized to maximize its sensitivity and minimize potential side
effects.


Reference