Difference between revisions of "Team:Cardiff Wales/Description"

 
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              <h1>Cas-Find</h1><hr>
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     <div><h2>'Cas-Find' is a novel bioluminescent system for point-of-care diagnostic testing.</h2><hr></div>  
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     <img style=width:100%; src="https://static.igem.org/mediawiki/2016/f/fd/T--Cardiff_Wales--CasFind.png"/>
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<div><h2>'Cas-Find' is a novel bioluminescent system for point-of-care diagnostic testing.</h2><hr></div>
  
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<p>Laboratory-based tests, such as nucleic acid amplification (NAA) or culture, require special methods of specimen transport, alongside specalised equipment and procedures for optimal performance <sup><a href="">[2]</a></sup>. As such the utilisation of laboratory-based tests is generally expensive in terms of equipment, reagents, infrastructure and maintenance. This limits the availability of results for immediate use in management decisions, potentially impacting on patient prognosis. In addition the majority of STI testing is conducted in resource-constrained environments, where such laboratory facilities are unavailable <sup><a href="">[3]</a></sup>.
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<div id=text> <p>Sexually transmitted infections (STI) represent an important issue for global Public health, due to their high-morbidity and prevalence. Laboratory-based tests for STI require specalised infrastructure, equipment and procedures for optimal performance <sup><a href="">[1]</a></sup>. As such the utilisation of these tests is generally expensive and time consuming, limiting the availability of results for immediate use in management decisions and potentially impacting on patient prognosis. In addition the majority of STI testing is conducted in resource-constrained environments, where such infrastructure and facilities are unavailable <sup><a href="">[2]</a></sup>.'Cas-Find' exploits CRISPR/Cas9 to potentially achieve point-of-care diagnosis alleviating some of the global health burden associated with these diseases.</p><br>
  
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<p><b>CRISPR/Cas9 achieves sequence specific interrogation.</b><br>Most bacteria and archaea possess RNA-mediated adaptive defence mechanisms composed of clustered regularly interspaced short palindromic repeats (CRIPSR) and CRISPR-associated proteins (Cas). Initially exogenous DNA sequences are recognised and incorporated into the bacterial or archaeal genome at the CRISPR loci, transcription through which produces CRISPR RNA (crRNA). An additional trans-activating RNA (tracrRNA) is required for interference, and is partially complementary to this crRNA. In <i>Streptococcus pyogenes</i> this forms a crRNA:tracrRNA <sup><a href="">[4]</a></sup> duplex which recruits the endonuclease Cas9, and collectively these molecules achieve sequence specific DNA interrogation and cleavage. This is summarised in Figure 1, demonstrating the sequential acquisition of exogenous DNA, RNA processing and interference. In synthetic applications a single guide RNA (sgRNA) construct fulfills the role of the crRNA:tracrRNA duplex. This sgRNA consists of a 20 nucleotide sequence complementary to the target, a 42 nucleotide Cas9 binding RNA structure, and a 40 nucleotide transcription terminator <sup><a href="">[5]</a></sup>. 'Cas-Find' utilises the capability of CRISPR/Cas9 to achieve sequence specific interrogation.</p><br>
                    <img id=content src="https://static.igem.org/mediawiki/2016/8/87/T--Cardiff_Wales--Cas-Find_Summary.svg" />
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                    <p><b>Fig 1. Summary of Cas-Find project</b></p>  
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<p><b>The reconstitution of luciferase activity constitutes a positive signal.</b><br>Luciferases catalyse bioluminescent reactions using ATP in the presence of molecular oxygen (O<sub>2</sub>) and luciferin (LH<sub>2</sub>), with <i>in vivo</i> and <i>in vitro</i> applications in imaging and detection. Wild-type luciferases are highly sensitive to pH and are thermolabile, undergoing inactivation and bathochromic shift at 25<sup>o</sup>C <sup><a href="">[7]</a></sup>. We fused the C- and N- terminal fragments of a thermostable pH-tolerant <i>Photinus pyralis</i> luciferase mutant to a dCas9 isoform optimized for expression in <i>E. coli</i>. dCas9 lacks catalytic activity, and as such targeted sequences do not undergo cleavage. sgRNA constructs target these chimeric proteins to adjacent sequences, resulting in the reconstitution of luciferase activity and bioluminescence in the prescence of luciferin. The reconstitution of bioluminesce significantly greater than background activity constitutes the positive signal for pathogen detection. The mechanism of this 'Cas-Find' system is demonstrated in Fig 2.</p><br>
  
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<p><b>'Cas-Find' could provide adaptable, specific point-of-care diagnosis.</b><br>All constructs were expressed under the T7 promoter and the control of the <i>lac</i> operator. dCas9 chimeric constructs were expressed in both pET16b and pCOLADuet expression vectors (see Fig 2). sgRNA constructs targeted to the 16S rRNA locus of <i>E. coli</i> were expressed in MSCS2 of pCOLADuet, in addition to the pSBC13 expression vector. The design of sgRNA constructs is discussed in more detail below. With further characterisation 'Cas-Find' thus presents a potential novel solution to STI diagnosis, especially where resources are constrained. The adaptable design of sgRNA constructs ensures that the 'Cas-Find' system can be designed to detect specific pathogens, and the requirement for the binding of two sgRNA constructs with a defined distance between them imparts high specificity. Bioluminescence can be detected using low cost and minimal equipment, and could be conducted rapidly at the point-of-care, potentially alleviating some of the global health burden associated with STI.</p><br>
  
    <div><h2>Proof of concept <i>in vitro</i> system targeted to <i>Escherichia coli</i> 16S rRNA.</h2><hr></div>
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<div><img src="https://static.igem.org/mediawiki/2016/6/6d/T--Cardiff_Wales--CRISPR.svg" /><p><b>Fig 1. <i>S.pyogenes</i> CRISPR/Cas9.</b></p><br><br><br><br><br></div>
  
              <div style=order:2; id=text>
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<div><img src="https://static.igem.org/mediawiki/2016/8/87/T--Cardiff_Wales--Cas-Find_Summary.svg" /><p><b>Fig 2. 'Cas-Find'</b></p><br><br></div>
 
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<p>Dr. Daniel Pass designed sgRNA constructs targeted to the <i>E. coli</i> 16S rRNA locus in order to facilitate proof-of-concept testing of our <i>in vitro</i> system. The design of these constructs was achieved using a Python <a href="http://github.com/passdan/scriptdrop/blob/master/cas9_targeter.py">script</a> developed by Dr. Pass to test FASTA formatted genomic DNA for paired target sequences using <a href="http://www.clontech.com/GB/Products/Genome_Editing/CRISPR_Cas9/Resources/Designing_sgRNA"> guidelines</a> from Takara Bio USA alongside additional sources. This script initially identifies a proto-spacer adjacent motif (PAM) sequence (5'-NGG-3') in this FASTA sequence. The sgRNA sequence is complementary to the 20 nucleotides upstream of the PAM sequence. This is passed to BLASTn to test for simple alignment against the reference dataset, which could include the remainder of the species genome, or multiple cross-reactive species. The output is a FASTA table of potential probes, and a table.txt file of the same information in a graphical representation.</p>
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<div><video width=400px controls> <source src="https://static.igem.org/mediawiki/2016/c/c6/T--Cardiff_Wales--vid1.mp4" type="video/mp4"> Your browser does not support HTML5 video.</video><p><b>Westminster Presentation.</b></p></div>
  
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                    <img id=content src="https://static.igem.org/mediawiki/2016/f/f0/T--Cardiff_Wales--Cas-Find_sgRNA.svg"/>
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                    <p><b>Fig 2. Summary of sgRNA design</b></p>
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<h2>Proof of concept <i>in vitro</i> system targeted to the <i>Escherichia coli</i> 16S rRNA locus.</h2><hr>
          <h2>Title</h2><hr>
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                    <img id=content src="https://static.igem.org/mediawiki/2016/8/86/T--Cardiff_Wales--Cas-Find_Characterisation.svg"/>
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                    <p><b>Fig 3. Summary of Characterisation</b></p>
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              </div>
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          <h2>Results</h2><hr>
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<div style=order:2; id=text><p>Dr. Daniel Pass developed a program to assist in designing sgRNA constructs for non-standard genomic regions and species, to the specifications required for this system. Here, we targeted the  <i>E. coli</i> 16S rRNA locus in order to facilitate proof-of-concept testing of our in vitro system. The design of these constructs was achieved using a <a href="http://github.com/passdan/scriptdrop/blob/master/cas9_targeter.py">Python script</a> developed to find appropriate paired regions from a FASTA formatted genomic DNA region for paired target sequences using <a href="http://www.clontech.com/GB/Products/Genome_Editing/CRISPR_Cas9/Resources/Designing_sgRNA">guidelines</a> from Takara Bio USA alongside additional sources.The script initially identifies proto-spacer adjacent motif (PAM) sequences (5'-NGG-3') in this FASTA sequence in forward and reverse. The sgRNA sequence is complementary to the 20 nucleotides upstream of the PAM sequence, after accounting for other enhancement features. Viable pairs within a defined range of each other are selected and passed to BLASTn to test for simple alignment against a reference dataset. This would include the remainder of the species genome, and also multiple cross-reactive species. The output is a FASTA file of potential probe pairs, a table.txt file of the same information in a graphical representation, and the results of the blast search, to aid in choosing probes which do not demonstrate cross-reactivity </p>
  
 +
<p>We designed one forward (F1) and three reverse (R1, R2 and R3) sgRNA constructs targeted to the <i>E. Coli</i> 16S rRNA locus using this program. Differing coexpression conditions could thus facilitate the characterization of background reconstitution at differing genomic distances. This builds on similar experimentation by <a href="https://2013.igem.org/Team:MIT/Venus">MIT</a> in 2013, and could contribute to future work with similar split reporter systems. This locus was selected due to its high copy number, promoting a strong signal during initial testing.</div>
  
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<div><img id=image; src="https://static.igem.org/mediawiki/2016/f/f0/T--Cardiff_Wales--Cas-Find_sgRNA.svg"/><p><b>Fig 3. sgRNA distance characterisation. </b></p></div></div></div>
  
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    <p><i>Westminster Presentation, by Andrew Brimer & Christian Donohoe</i></p>
 
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<a name="FUEL"></a>
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<div style=width:100%;> <h2>Bibliography</h2><hr>
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<h1>FUEL Project</h1>
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<img width=90%  src="https://static.igem.org/mediawiki/2016/8/89/T--Cardiff_Wales--Cardiff_FUEL.png">
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<br>
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<h1>Overview</h1>
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<hr>
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<p>As a link to our use of luciferases in the <a href="https://2016.igem.org/Team:Cardiff_Wales/Cas-Find">Cas-Find</a> project we developed an interest in biological imaging. This was largely influenced by the research of our Secondary PI, Amit Jathoul in this general area. <p>One challenge in the field of biological imaging is in the use of fluorescent and bioluminescent proteins that emit light with longer wavelengths. The mKeima RFP variant has been previously used as a long stoke shifted fluorophore and was the subject of the <a href="https://2013.igem.org/Team:UCL_PG"> SPECTRA project of the 2013 UCL iGEM team </a>.
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<hr>
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<p>Therefore as a side project we planned to alter the potential usage of the Lux Operon biobrick (Cambridge iGEM 2010 <a href="http://parts.igem.org/Part:BBa_K325909">BBa_K325909</a>) by inducing a red-shift in its bioluminescence via an interaction with the mKeima protein.
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<p>We hoped to show that blue light produced by <i>E.coli</i> expressing the native LUXoperon would excite the mKeima protein resulting in the emission of red light. 
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<p>We aimed to analyse the interaction between LUXoperon and mKeima in two ways:
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<li><b>1. Co-expression:</b> Express the LUXoperon and mKeima in different bacterial cells and assess whether the <a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4207116/">Fluorescence by Unbound Excitation from Luminescence (FUEL) reaction</a> was able to cause a change in the wavelength of the light output. The gene expression in both bacteria is controlled by the arabinose inducible promotor pBAD.<p>
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<li>2. <b>Co-regulation:</b> Addition of a rbs-mKeima sequence to the 3’ end of the native <a href="http://parts.igem.org/Part:BBa_K325909">pBAD::LUXoperon</a>. We aimed to assess whether there was an alteration in wavelength of the light output in these bacteria compared to bacteria contained an unaltered LUXoperon.
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<img width=100% src=https://static.igem.org/mediawiki/parts/a/ad/T--Cardiff_Wales--biobrick_mk_lux.png>
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<br>
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<hr>
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<h2>Experimental Design</h2>
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<p>The mKeima protein has been added to the registry by the UCL_PG team of 2013 (<a href="http://parts.igem.org/Part:BBa_K1135001">BBa_K1135001</a>). However as part of this side project we have submitted two unique parts to the registry that contain this protein:
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<p><li> 1. pBAD::LUXoperon:mKeima fusion (<a href="http://parts.igem.org/Part:BBa_K2060002">BB_K2060002</a>)</p>
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<p><li> 2. pBAD::mKeima (<a href="http://parts.igem.org/Part:BBa_K2060001">BB_K2060001</a>).</p>
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<p>We aimed to grow these biobrick-containing bacteria in the presence of arabinose to induce expression of each construct and then measure the fluorescence and bioluminescence of the bacteria to assess:
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<p><li>1. Whether the proteins were correctly expressed by analysis of the appropriate spectra</li></P/
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<p><li>2. Whether there is a change in light output when different bacterial cultures were mixed prior to analysis of appropriate spectra</li>
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<p>Initially we sub-cultured overnight bacterial cultures (1/10) and grew for 3hours prior to induction of gene expression by addition of arabinose at various concentrations for approximately 6hours.</P>
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<p>Following induction we used a Cary XXXX to measure fluorescence and bioluminescence across appropriate spectra. The LUXoperon has been previously shown to <a href=" https://2012.igem.org/Team:Tokyo-NoKoGen/Project/lux_operon "> emit light at 488nm </a> whilst the emission wavelength of mKeima is 620nm. We also used a non-biobrick construct expressing pBAD::sfGFP as a control, for which  the emission wavelength is 510nm.
+
  
<hr>
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<div><p><a name="1"> <sup>1</sup> </a> - Peeling, R.W., Holmes, K.K., Mabey, D. (2006) Rapid tests for sexually transmitted infections (STI's): the way forward.<i>Sexually Transmitted Infections</i>.<b>82:</b>1-6.</p></div>
<h2>Results</h2>
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<p>Firstly we grew biobrick-containing E.coli overnight and after sub-culturing (1/10) grew for 2hr before induction with mM concentrations of arabinose.
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<img width=100% src=https://static.igem.org/mediawiki/2016/f/f1/T--Cardiff_Wales--FUEL_Image1.png>
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<p>Figure 1 shows that at these concentrations (5-20mM) of arabinose, bacteria containing the native LUXoperon showed a predicted bioluminescence spectra. However none of the other bacteria were bioluminescent.
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<p>Figure 2 shows that at these concentrations (5-20mM) of arabinose, bacteria containing sfGFP showed a predicted fluorescent spectra. However none of the other bacteria showed any fluorescence across the range of tested wavelengths.
+
  
 +
<div><p><a name="2"> <sup>2</sup></a> - Santrach, P.J. (2007) Current and Future Applications of Point of Care Testing. Mayo Clinic. [Online] Available at: http://wwwn.cdc.gov/cliac/pdf/addenda/cliac0207/addendumf.pdf [Accessed: 18 October 2016] </p></div>
  
<hr>
+
<div><p><a name="3"> <sup>3</sup></a> - Unemo M. (2013) Laboratory diagnosis of sexually transmitted infections, including human immunodeficiency virus. <em>WHO. &nbsp;</em></p></div>
<p><a href="http://www.pnas.org/content/suppl/2010/03/03/0914365107.DCSupplemental/pnas.0914365107_SI.pdf">Previous work</a> has demonstrated that mKeima expression under the pBAD promotor was best at lower concentrations of arabinose. Therefore we grew bacterial sub-cultures for 6hr in 100uM and 250uM Arabinose (Figure 3 and 4). Unfortunately this did also not show bioluminescence or fluorescence that was suggestive of mKeima expression. </p>
+
  
<img width=100% src=https://static.igem.org/mediawiki/2016/4/49/T--Cardiff_Wales--FUEL_Image2.png>
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<div><p><a name="4"> <sup>4</sup></a> - Jinek, M., Chylinsji, K., Fonfara, I., Hauer, M. Doudna, J., Charpentier, E. (2012) A Programmable Dual-RNA_Guided DNA Endonuclease in Adaptive Bacterial Immunitity. <i>Science.</i><b>337:</b>816-821.</p></div>
  
<hr>
+
<div><p><a name="5"><sup>5</sup></a> - Larson, M., Gilbert, L.,Wang, X., Lim, W., Weissman, J., Qi, L. (2013) 
<p>Finally we attempted to stimulate expression of the mKeima-containing biobricks <a href="http://parts.igem.org/Part:BBa_K2060001">BB_K2060001</a> and <a href="http://parts.igem.org/Part:BBa_K2060002">BB_K2060002</a> by growing bacterial cultures overnight and spiking in arabinose at 10mM for 2hr before measurement. </p>
+
CRISPR interference (CRISPRi) for sequence-specific control of gene expression. <i>Nature Protocols.</i><b>8:</b>2180-2196.</p></div>
  
<img width=80% src=https://static.igem.org/mediawiki/2016/4/4a/T--Cardiff_Wales--FUEL_Image3a.png>
+
<div><p><a name="6"><sup>6</sup></a> - Jathoul, A., Law, E., Gandelman, O., Pule, M., Tisi, L., Murray, J. (2012) Development of a pH-tolerant Thermostable <i>Photinus pyralis</i> Luciferase for Brighter <i>In Vivo</i> Imaging. <i>Bioluminescence - Recent Advances in Oceanic Measurements and Laboratory Applications.</p></div>
  
<p>Figure 5 demonstrates that the <a href="http://parts.igem.org/Part:BBa_K2060002">LUXoperon-mKeima </a> gave a bioluminescent blue-light output, indicating that the LUXoperon is working correctly. However figure 6 shows that there is no inducible fluorescence generated by these bacteria. This indicates that further work is necessary to stimulate effective expression of both the LUX components and mKeima from the same operon. </P>
 
 
 
<h2>Future plans</h2>
 
 
<p> iGEM headquarters recently published a paper demonstrating the challenges in expression of fluorescent proteins,
 
<a href=" http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0150182”> http://dx.doi.org/10.1371/journal.pone.0150182 </a>. We had clear difficulties expressing mKeima in bacteria containing either biobricks <a href="http://parts.igem.org/Part:BBa_K2060001">BB_K2060001</a> or <a href="http://parts.igem.org/Part:BBa_K2060002">BB_K2060002</a>. Sadly we ran out of time to conduct further analysis but might would recommend the following experiments:</p>
 
<li>1. Induce expression at lower temperatures (18C or 22C) at varying concentrations of Arabinose (nM-mM range)</li>
 
<li>2. Addition of arabinose at different times in the bacterial growth cycle.</li>
 
<li>3. Vary timings post growth to allow for protein maturation</li>
 
 
<p>We hope that future iGEM teams will take advantage of the availability of these biobricks as potentially very useful tool for the analysis of gene expression. With increased time the development of these tools will be of benefit for the entire iGEM community.</p>
 
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Latest revision as of 02:45, 20 October 2016

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'Cas-Find' is a novel bioluminescent system for point-of-care diagnostic testing.

Sexually transmitted infections (STI) represent an important issue for global Public health, due to their high-morbidity and prevalence. Laboratory-based tests for STI require specalised infrastructure, equipment and procedures for optimal performance [1]. As such the utilisation of these tests is generally expensive and time consuming, limiting the availability of results for immediate use in management decisions and potentially impacting on patient prognosis. In addition the majority of STI testing is conducted in resource-constrained environments, where such infrastructure and facilities are unavailable [2].'Cas-Find' exploits CRISPR/Cas9 to potentially achieve point-of-care diagnosis alleviating some of the global health burden associated with these diseases.


CRISPR/Cas9 achieves sequence specific interrogation.
Most bacteria and archaea possess RNA-mediated adaptive defence mechanisms composed of clustered regularly interspaced short palindromic repeats (CRIPSR) and CRISPR-associated proteins (Cas). Initially exogenous DNA sequences are recognised and incorporated into the bacterial or archaeal genome at the CRISPR loci, transcription through which produces CRISPR RNA (crRNA). An additional trans-activating RNA (tracrRNA) is required for interference, and is partially complementary to this crRNA. In Streptococcus pyogenes this forms a crRNA:tracrRNA [4] duplex which recruits the endonuclease Cas9, and collectively these molecules achieve sequence specific DNA interrogation and cleavage. This is summarised in Figure 1, demonstrating the sequential acquisition of exogenous DNA, RNA processing and interference. In synthetic applications a single guide RNA (sgRNA) construct fulfills the role of the crRNA:tracrRNA duplex. This sgRNA consists of a 20 nucleotide sequence complementary to the target, a 42 nucleotide Cas9 binding RNA structure, and a 40 nucleotide transcription terminator [5]. 'Cas-Find' utilises the capability of CRISPR/Cas9 to achieve sequence specific interrogation.


The reconstitution of luciferase activity constitutes a positive signal.
Luciferases catalyse bioluminescent reactions using ATP in the presence of molecular oxygen (O2) and luciferin (LH2), with in vivo and in vitro applications in imaging and detection. Wild-type luciferases are highly sensitive to pH and are thermolabile, undergoing inactivation and bathochromic shift at 25oC [7]. We fused the C- and N- terminal fragments of a thermostable pH-tolerant Photinus pyralis luciferase mutant to a dCas9 isoform optimized for expression in E. coli. dCas9 lacks catalytic activity, and as such targeted sequences do not undergo cleavage. sgRNA constructs target these chimeric proteins to adjacent sequences, resulting in the reconstitution of luciferase activity and bioluminescence in the prescence of luciferin. The reconstitution of bioluminesce significantly greater than background activity constitutes the positive signal for pathogen detection. The mechanism of this 'Cas-Find' system is demonstrated in Fig 2.


'Cas-Find' could provide adaptable, specific point-of-care diagnosis.
All constructs were expressed under the T7 promoter and the control of the lac operator. dCas9 chimeric constructs were expressed in both pET16b and pCOLADuet expression vectors (see Fig 2). sgRNA constructs targeted to the 16S rRNA locus of E. coli were expressed in MSCS2 of pCOLADuet, in addition to the pSBC13 expression vector. The design of sgRNA constructs is discussed in more detail below. With further characterisation 'Cas-Find' thus presents a potential novel solution to STI diagnosis, especially where resources are constrained. The adaptable design of sgRNA constructs ensures that the 'Cas-Find' system can be designed to detect specific pathogens, and the requirement for the binding of two sgRNA constructs with a defined distance between them imparts high specificity. Bioluminescence can be detected using low cost and minimal equipment, and could be conducted rapidly at the point-of-care, potentially alleviating some of the global health burden associated with STI.


Fig 1. S.pyogenes CRISPR/Cas9.






Fig 2. 'Cas-Find'



Westminster Presentation.

Proof of concept in vitro system targeted to the Escherichia coli 16S rRNA locus.

Dr. Daniel Pass developed a program to assist in designing sgRNA constructs for non-standard genomic regions and species, to the specifications required for this system. Here, we targeted the  E. coli 16S rRNA locus in order to facilitate proof-of-concept testing of our in vitro system. The design of these constructs was achieved using a Python script developed to find appropriate paired regions from a FASTA formatted genomic DNA region for paired target sequences using guidelines from Takara Bio USA alongside additional sources.The script initially identifies proto-spacer adjacent motif (PAM) sequences (5'-NGG-3') in this FASTA sequence in forward and reverse. The sgRNA sequence is complementary to the 20 nucleotides upstream of the PAM sequence, after accounting for other enhancement features. Viable pairs within a defined range of each other are selected and passed to BLASTn to test for simple alignment against a reference dataset. This would include the remainder of the species genome, and also multiple cross-reactive species. The output is a FASTA file of potential probe pairs, a table.txt file of the same information in a graphical representation, and the results of the blast search, to aid in choosing probes which do not demonstrate cross-reactivity

We designed one forward (F1) and three reverse (R1, R2 and R3) sgRNA constructs targeted to the E. Coli 16S rRNA locus using this program. Differing coexpression conditions could thus facilitate the characterization of background reconstitution at differing genomic distances. This builds on similar experimentation by MIT in 2013, and could contribute to future work with similar split reporter systems. This locus was selected due to its high copy number, promoting a strong signal during initial testing.

Fig 3. sgRNA distance characterisation.

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