Difference between revisions of "Team:EPFL/Design"

Line 340: Line 340:
 
<div class="card-body">
 
<div class="card-body">
 
<div class="card">
 
<div class="card">
 +
<a data-toggle="collapse" data-parent="#collapseOne" href="#ProbeAnalysis">
 
<div class="card-header">
 
<div class="card-header">
 
<h4 class="card-link">
 
<h4 class="card-link">
<a data-toggle="collapse" data-parent="#collapseOne" href="#ProbeAnalysis">
+
Analysis of given probes
Analysis of given probes</a>
+
 
</h4>
 
</h4>
 
</div>
 
</div>
 +
</a>
 
<div id="ProbeAnalysis" class="collapse" data-parent="#DetailedDesign">
 
<div id="ProbeAnalysis" class="collapse" data-parent="#DetailedDesign">
 
<div class="card-body">
 
<div class="card-body">
Line 415: Line 416:
 
<figure>
 
<figure>
 
<img alt="Image" src="https://static.igem.org/mediawiki/2018/f/f7/T--EPFL--cas12.png" class="img-fluid rounded" width="450">
 
<img alt="Image" src="https://static.igem.org/mediawiki/2018/f/f7/T--EPFL--cas12.png" class="img-fluid rounded" width="450">
<figcaption class="mt-3 text-muted">Reproduced from <a href="#NebCas12a"><span style="color:blue">New England BioLabs</span></a>.</figcaption>
+
<figcaption class="mt-3 text-muted">"Schematic representation of Lba Cas12a nuclease sequence recognition and DNA cleavage". [Reproduced from <a href="#NebCas12a"><span style="color:blue">New England BioLabs</span></a>].</figcaption>
 
</figure>
 
</figure>
 
</center>
 
</center>
Line 425: Line 426:
 
<figure>
 
<figure>
 
<img alt="Image" src="https://static.igem.org/mediawiki/2018/b/bd/T--EPFL--Cas9Cas12aForMiRNA.png" class="img-fluid rounded" width="800">
 
<img alt="Image" src="https://static.igem.org/mediawiki/2018/b/bd/T--EPFL--Cas9Cas12aForMiRNA.png" class="img-fluid rounded" width="800">
 +
<figcaption class="mt-3 text-muted">Comparison of the interaction between target amplicon and gRNA for Cas 9 (<i>on the left</i>) and Cas 12a (<i>on the right</i>).</figcaption>
 
</figure>
 
</figure>
 
</center>
 
</center>
+
<br>
 +
<p class="lead">We therefore conclude that the template for our guide RNA for Cas 12a should be:</p>
 +
<p class="lead">5’-(UAAUUUCUACUAAGUGUAGAU)NNNNNN<span style="color:red">|</span>NNNNNNNNN<i>NNNNNNN</i>-3’  [<b><i>gRNA template</i></b>] </p>
 +
<p class="lead">where the sequence in parentheses indicates the scaffold of the gRNA for LbCas12a. The sequence out of the brackets is the spacer, binding to the amplicon, and in particular the sequence in <i>italic</i> corresponds to the part binding on the loop of the amplicon.</p>
 +
<br>
 +
<p class="lead">The spacer is therefore 22 bases long (as let-7a-5p), 15 of which bind to the stem part of the amplicon and the remaining 7 bind to the small loop of the amplicon. Note that the gRNA for Cas9 from <a href="#Qiu"><span style="color:blue">Qiu <i>et al.</i></span></a> was instead 21 bases long (15 and 6): we decided to add one more base at the end to completely match the length of the miRNA.
 +
<br>
 +
<p class="lead">We can notice that also in this design the spacer has to coincide with the reverse complement of let-7a (as for Cas 9) . The template of the gRNA for Cas12a would therefore be: </p>
 +
<p class="lead">5'-[scaffold]-[reverse complement of miRNA]-3'</p>
 
</div>
 
</div>
 
</div>
 
</div>
Line 435: Line 445:
 
<h4 class="card-link">
 
<h4 class="card-link">
 
<a data-toggle="collapse" data-parent="#collapseOne" href="#Sequences">
 
<a data-toggle="collapse" data-parent="#collapseOne" href="#Sequences">
Sequences and actual probes</a>
+
Probes for Cas12a</a>
 
</h4>
 
</h4>
 
</div>
 
</div>
 
<div id="Sequences" class="collapse">
 
<div id="Sequences" class="collapse">
<div class="card-body">Lorem ipsum dolor sit amet, consectetur adipisicing elit,
+
<div class="card-body">
sed do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut enim ad
+
<p class="lead">From the template above we can therefore conclude that the gRNA for our Cas 12a system, designed as the one for Cas 9 from <a href="#Deng"><span style="color:blue">Deng <i>et al.</i></span></a>, has to be: </p>
minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea
+
<p class="lead">5’-(UAAUUUCUACUAAGUGUAGAU)AACUAU<span style="color:red">|</span>ACAACCUAC<i>UACCUCA</i>-3’  [<b><i>gRNA sequence</i></b>]</p>
commodo consequat.</div>
+
<br>
 +
<p class="lead">From the specifications for the probe above (10 bases small loop, 16 bases large loop) and from the gRNA sequence, the template amplicon therefore needs to have the following structure:</p>
 +
<h5>5’-<span class="thicker"><span style="color:orange">ATAGTT</span></span><span class="lead"><i>NNNNNNNNNNNN<span style="color:red">TTTN</span></i><span style="color:green">AACTATACAACCTAC</span><i>NNN</span><span class="thicker">TGAGGTA</i><span style="color:orange">GTAGGTTGT</span></span><span class="lead">-3’  [amplicon template]</span></h5>
 +
<p class="lead">We then proceeded to define the bases for the Ns, aiming not to have unwanted minor secondary structures (e.g. smaller loops) in the loops. This was done mostly by considering pairing principles, e.g. avoiding non-Watson-Crick interaction (e.g. T-G) which might be thermodynamically favoured or trying not to have complementary bases with more than 1 base in between (which might lead to hairpin loops). In all cases, the minimum free energy structure (MFE) was plotted by means of the available software (NUPACK, Mfold), both for the amplicon and the probe - i.e. its reverse complement-, to check that the intended dumbbell shape was indeed achieved.</p>
 +
<p class="lead">This lead us to the sequence of Probe 1 and Probe 6 (Probes from 2 to 5 were the probes for Cas 9 from <a href="#Deng"><span style="color:blue">Deng <i>et al.</i></span></a> and <a href="#Qiu"><span style="color:blue">Qiu <i>et al.</i></span></a>).</p>
 +
<p class="lead">-----</p>
 +
<br>
 +
<p class="lead">We also wanted to test the case of probes having the PAM sequence not on the large loop, but on the stem instead (i.e. a double-stranded PAM, as usually required in Cas systems, and not single-stranded). We considered in this case three different alternatives:</p>
 +
<ol>
 +
<li></li>
 +
<li></li>
 +
<li></li>
 +
</ol>
 +
 +
</div>
 
</div>
 
</div>
 
</div>
 
</div>

Revision as of 17:28, 13 October 2018

iGEM EPFL 2018

Design

Raw denim you probably haven't heard of them jean shorts Austin. Nesciunt tofu stumptown aliqua, retro synth master cleanse. Mustache cliche tempor, williamsburg carles vegan helvetica. Reprehenderit butcher retro keffiyeh dreamcatcher synth.

Index
Introduction
Blood Biomarkers
Cas12a
Sample preparation
Amplification
Fluorescence readout

Introduction

The aim of the follow-up part is to provide a proof of concept for detecting disease recurrence, as well as to monitor our treatment efficacy in melanoma patients by detecting specific biomarkers present in the blood. This is particularly important for our project since it constitutes a non-invasive way of validating our vaccine efficacy: tumor biopsies are indeed very invasive, time consuming, and often difficult to perform. Here, we envision a new generation of diagnostic approach, by which a simple liquid biopsy could give us an accurate prognosis regarding the genetic evolution of the tumor in response to our immunotherapy treatment, and would also enable us to detect relapses. This requires a detection system that is both highly sensitive and highly specific, since these biomarkers yield a very precise sequence and are often present in extremely low concentrations in the blood. Our idea to solve this problem is to combine RCA or PCR amplification with a Cas12a-protein based system for a rapid and specific detection. We divided this part in two separate modules, designed to tackle the two different biomarkers we are using: circulating tumor DNA and microRNAs.

Blood Biomarkers

Blood Biomarkers


Cas12a

To answer the need for a fast and robust detection method we chose to work with the newly characterized Cas12a (Cpf1) protein.

CRISPR-Cas (clustered regularly interspaced short palindromic repeats–CRISPR-associated) system are originally inspired by an antiviral defense mechanism used by prokaryotes which essentially works by recognizing and cleaving the foreign DNA/RNA. It has in the recent years widely been used as a gene editing tool for its ability to find and cut a specific target sequence (the activator).

This activator is composed of two different strands: the target strand (TS) and the non-targeted strand (NTS). The NTS requires a T-rich protospacer adjacent motif (PAM) sequence to be recognized by Cas12a whereas the TS contains the complement sequence of the guide RNA (gRNA), the gRNA being part of the crRNA.

With both these requirements completed, the interchangeable CRISPR RNA (crRNA) will successfully guide the protein to the target.

As a result of cleaving its double stranded DNA (dsDNA) target, Cas12a will undergo a conformational change which will unleash the protein’s endonuclease activity with a single active site in the RuvC catalytic region against any single stranded DNA (ssDNA). This unspecific collateral cleavage is what makes this system so suitable for detection as it greatly amplifies the signal.

In our assays we decided to work with the purified Lba Cas12a (type V-A CRISPR) extracted from Lachnospiraceae bacterium ND2006 and provided by New England BioLabs.

Design of the crRNA

Blablabla

Cas12a detection assay using a fluorescent readout

Blablabla


Sample preparation

Sample preparation


Amplification

ctDNA amplification

One disadvantage of a classic CRISPR-Cas based assay is the need to have a PAM sequence near the region that we want to detect, for efficient RNA-guided DNA binding. To eliminate this need, we designed PCR primers that would specifically introduce the PAM sequence, for efficient and sequence-independent detection of any given junction or mutation

miRNA amplification

Rolling Circle Amplification and Dumbbell Probes

Our probes

The first miRNA we decided to target is let-7a-5p: this miRNA is not among the ones found to be relevant as melanoma biomarkers (as instead are other miRNAs of the let-7 family) (Larrea et al.; Mirzaei et al.); nonetheless, we thought it might be the best option to start from it as a proof of concept, because it was already well characterized for Rolling Circle Amplification (RCA) by Deng et al. and Qiu et al.

Qiu et al., as well as our colleagues from the related 2016 iGEM team of NUDT China, had designed their probes in order for the amplicons to be recognized by a CRISPR-Cas 9 system. Since our project deals instead with CRISPR-Cas 12a, despite the miRNA sequence being the same, we therefore had to modify the sequences of our probes accordingly. More specifically, we had to adapt the PAM sequence (placed on the amplicon of the probe) in order to match our Cas protein (we worked with LbCpf1): while the requirement for Cas9 was NGG on the 3' of the amplicon, in our case we needed to have TTTN on the 5'. More details on the design are described in the section "Detailed design".

We wanted to test different designs of probes: some were conceived to have the PAM at the beginning of the larger loop of the amplicon (as in the probes from NUDT China), but we also investigated the case where the PAM was placed on the double-stranded part (the stem) instead; the sequence on the uncostrained large loop was also changed among the probes.

We ordered 10 different probes; the sequence and related notes are described in the Table below.


Name Sequence (5'->3') Description
Probe 1 pACAACCTACTACCTCAAACGTAGGTTGTAT
AGTTTAAAGGGAGTCGGCGGAACTAT		 Probe designed by our team for Cas 12a. PAM on the large loop of the amplicon.

Probe 2		 pACCTCATTGTATAGCCCCCCCCTGAGGTAG
TAGGTTGCCCAACTATACAACCTACT		 Probe from Deng et al. and Qiu et al. (respectively referred to as "SP-let-7a" and "let-7a probe 1"), designed for Cas9. Used as a control for the efficiency of the amplification.
Probe 3 pACCTCACCCCCCCCCCCCCCCCTGAGGTAG
TAGGTTGCCCAACTATACAACCTACT		 Probe from Qiu et al. ("let-7a probe 2"), designed for Cas9. Used as a control for the efficiency of the amplification.
Probe 4 pACCTCAAAAAAAAAAAAAACCCTGAGGTAG
TAGGTTGCCCAACTATACAACCTACT		 Probe from Qiu et al. ("let-7a probe 3"), designed for Cas9. Used as a control for the efficiency of the amplification.
Probe 5 pACCTCATTTTTTTTTTTTTCCCTGAGGTAG
TAGGTTGCCCAACTATACAACCTACT		 Probe from Qiu et al. ("let-7a probe 4"), designed for Cas9. Used as a control for the efficiency of the amplification.
Probe 6 pACAACCTACTACCTCAAACGTAGGTTGTAT
AGTTTAAAGGGGGGGGGGCGAACTAT		 Probe designed by our team for Cas 12a. PAM on the large loop of the amplicon. Large loop with repetitive sequence of Gs.
Probe 7 pACAACCTACTACCTCAAACGTAGGTTGTAT
AGTTTAAAGGGAGTGGTTTAAACTAT		 Probe designed by our team for Cas 12a. PAM on the stem. Large loop made of 8 bases.
Probe 8 pACAACCTACTACCTCAAACGTAGGTTGTAT
AGTTTAAAGGGAGTCGGCGGTTTAAACTAT		 Probe designed by our team for Cas 12a. PAM on the stem. Large loop made of 12 bases.
Probe 9 pACAACCTACTACCTCAAACGTAGGTTGTATAG
TTTAAAGGGGGGGGGGGGGGCGTTTAAACTAT		 Probe designed by our team for Cas 12a. PAM on the stem. Large loop made of 16 bases.

Probe 10		 pACAACCTACTACCTCAAACGTAGGTTGTAG
AGTTTAAAGGGAGTCGGCGGAACTCT		 Probe designed by our team for Cas 12a. PAM on the large loop of the amplicon. Single base mismatch on the stem with respect to the target miRNA sequence.

Note: The sequences of the probes include a phosphate group at the 5' end (in order to ligate the probes). We nonetheless always ordered the oligonucleotides without the phosphate (because the cost was significantly lower) and then performed phosphorylation by means of T4 Polynucleotide Kinase prior to ligation.

For each probe we ran an analysis of the secondary structure by means of available servers online (NUPACK, MFold): in all cases the structure of the probe, of its amplicon and of the series of 4-5 copies of the amplicon were tested in order to check the absence of unwanted secondary structures. We also used RNAstructure DuplexFold to test the secondary structure of the dimer probe/miRNA: we were not able to find a more suitable tool for the analysis of the duplex; nonetheless we believe that this server, despite its limitations with respect to our analysis (no possibility of having a circular probe, no possibility to have a DNA/RNA dimer), was enough to show qualitatively the interaction between our probe and let-7a.

Detailed design

Analysis of given probes

We started our design from the analysis of one probe from Qiu et al., namely "let-7a probe 1" (Probe 2 for us). The sequence was the following one:

5’-pACCTCATTGTATAGCCCCCCCCTGAGGTAGTAGGTTGCCCAACTATACAACCTACT-3’

where:

  • the regions in italic are those belonging to the loops of the hairpin
  • the regions in orange and green are those belonging to the stem of the hairpin (and which are complementary with each other)
  • the underlined region is the one complementary to the miRNA (let-7a-5p: UGAGGUAGUAGGUUGUAUAGUU)
Image
Secondary structure of "let-7a probe 1" (Probe 2 for us). dG=-10.40.

Such probe consists of a double-stranded stem part, a 10 bases-long loop (which from now on we will refer to as "small loop" - on the right in the figure above) and a 16 bases-long loop ("large loop" - on the left). As we can observe, the toehold region of the probe (i.e. the part on the small loop where the miRNA binds) is 7 bases long, in accordance with Deng et al., who proved it to be the optimal length to achieve both sensitivity and specificity.

The amplicon of such probe is therefore*:

5'-AGTAGGTTGTATAGTTGGGCAACCTACTACCTCAGGGGGGGGCTATACAATGAGGT-3’

where:

the sequence in bold is the one which is complementary to the gRNA (except for two mismatches, which are highlighted) and the region in red is the PAM sequence (in this case single stranded).

We emphasize here that the PAM sequence is on a single-stranded part of the amplicon (the one complementary to the large loop of the probe): therefore, such single-stranded PAM can only be present on the amplicon, and not on the probe itself (as would have been instead if the PAM was on a double stranded part).


The gRNA sequence (as indicated by Qiu et al.) is:

5’-ACUGUACAAACUACU|ACCUCA(GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCG) -3’

with the scaffold region indicated in parentheses. The region out of the brackets is the spacer, binding to the amplicon, and the sequence in italic corresponds in particular to the part of the spacer binding on the loop of the amplicon (with the rest of the spacer binding to the stem). The sign | indicates the position where the gRNA binds to the point on the amplicon where each new "copy" of the amplicon is considered to start (i.e. the point where the 3' of a "subunit" of the amplicon and the 5' of the successive subunit are linked together).


More specifically, we can notice that in this design the spacer coincides with the reverse complement of let-7a, with the exception of the two mismatches and of a missing A at the beginning. The template of the gRNA for Cas9 would therefore be:

5'-[reverse complement of miRNA]-[scaffold]-3'


The expected interaction between amplicon and gRNA is outlined in the figure below:

Image Image
On the left: Generic interaction between a target and a gRNA for Cas9 [Reproduced from Xie and Yang (Figure 1A)]. On the right: Predicted interaction of one subunit of the amplicon of Probe 2 with the gRNA.

We can observe how the PAM sequence (in red in the figure) is located at the very beginning of the large loop in the amplicon, whereas the gRNA binds to the whole stem part and partially to the small loop.

*Here and after, when referring to the "amplicon sequence", we only show one single copy of the reverse transcript of the probe. The actual amplicon, by definition of Rolling Circle Amplification, is of course made instead of sequential copies of this "unitary" sequence.

Comparison Cas9/Cas12a

We then tried to design our own probes for Cas 12a, working backwards from the gRNA.

Contrarily to Cas 9, for which the PAM must be on the 3' side of the target, for Cas12a the PAM must be on the 5’ side of the target instead. This implies that the scaffold part of the gRNA must be on the 5’ side (instead of the 3’) as well (Figure below).

Image
"Schematic representation of Lba Cas12a nuclease sequence recognition and DNA cleavage". [Reproduced from New England BioLabs].

Below is shown a direct comparison of the interaction between target amplicon and gRNA for Cas 9 and Cas 12a.

Image
Comparison of the interaction between target amplicon and gRNA for Cas 9 (on the left) and Cas 12a (on the right).

We therefore conclude that the template for our guide RNA for Cas 12a should be:

5’-(UAAUUUCUACUAAGUGUAGAU)NNNNNN|NNNNNNNNNNNNNNNN-3’ [gRNA template]

where the sequence in parentheses indicates the scaffold of the gRNA for LbCas12a. The sequence out of the brackets is the spacer, binding to the amplicon, and in particular the sequence in italic corresponds to the part binding on the loop of the amplicon.


The spacer is therefore 22 bases long (as let-7a-5p), 15 of which bind to the stem part of the amplicon and the remaining 7 bind to the small loop of the amplicon. Note that the gRNA for Cas9 from Qiu et al. was instead 21 bases long (15 and 6): we decided to add one more base at the end to completely match the length of the miRNA.

We can notice that also in this design the spacer has to coincide with the reverse complement of let-7a (as for Cas 9) . The template of the gRNA for Cas12a would therefore be:

5'-[scaffold]-[reverse complement of miRNA]-3'

Probes for Cas12a

From the template above we can therefore conclude that the gRNA for our Cas 12a system, designed as the one for Cas 9 from Deng et al., has to be:

5’-(UAAUUUCUACUAAGUGUAGAU)AACUAU|ACAACCUACUACCUCA-3’ [gRNA sequence]


From the specifications for the probe above (10 bases small loop, 16 bases large loop) and from the gRNA sequence, the template amplicon therefore needs to have the following structure:

5’-ATAGTTNNNNNNNNNNNNTTTNAACTATACAACCTACNNNTGAGGTAGTAGGTTGT-3’ [amplicon template]

We then proceeded to define the bases for the Ns, aiming not to have unwanted minor secondary structures (e.g. smaller loops) in the loops. This was done mostly by considering pairing principles, e.g. avoiding non-Watson-Crick interaction (e.g. T-G) which might be thermodynamically favoured or trying not to have complementary bases with more than 1 base in between (which might lead to hairpin loops). In all cases, the minimum free energy structure (MFE) was plotted by means of the available software (NUPACK, Mfold), both for the amplicon and the probe - i.e. its reverse complement-, to check that the intended dumbbell shape was indeed achieved.

This lead us to the sequence of Probe 1 and Probe 6 (Probes from 2 to 5 were the probes for Cas 9 from Deng et al. and Qiu et al.).

-----


We also wanted to test the case of probes having the PAM sequence not on the large loop, but on the stem instead (i.e. a double-stranded PAM, as usually required in Cas systems, and not single-stranded). We considered in this case three different alternatives:

Design of gRNAs after new theory

Lorem ipsum dolor sit amet, consectetur adipisicing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut enim ad minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo consequat.


Fluorescence readout

ctDNA Cas assay

One disadvantage of a classic CRISPR-Cas based assay is the need to have a PAM sequence near the region that we want to detect, for efficient RNA-guided DNA binding. To eliminate this need, we designed PCR primers that would specifically introduce the PAM sequence, for efficient and sequence-independent detection of any given junction or mutation

miRNA Cas assay

References

  1. "EnGen Lba Cas12a (Cpf1)" - New England BioLabs website. URL: https://international.neb.com/products/m0653-engen-lba-cas12a-cpf1#Product%20Information_Notes (Accessed 24/09/2018)
  2. Larrea, Erika, et al. "New concepts in cancer biomarkers: circulating miRNAs in liquid biopsies." International journal of molecular sciences, 17.5 (2016): 627.
  3. Mirzaei, Hamed, et al. "MicroRNAs as potential diagnostic and prognostic biomarkers in melanoma." European journal of cancer, 53 (2016): 25-32.
  4. Deng, Ruijie, et al. "Toehold-initiated rolling circle amplification for visualizing individual microRNAs in situ in single cells." Angewandte Chemie, 126.9 (2014): 2421-2425.
  5. Qiu, Xin-Yuan, et al. "Highly Effective and Low-Cost MicroRNA Detection with CRISPR-Cas9." ACS synthetic biology, 7.3 (2018): 807-813.
  6. Zadeh, Joseph N., et al. "NUPACK: analysis and design of nucleic acid systems." Journal of computational chemistry, 32.1 (2011): 170-173.
  7. Zuker, Michael. "Mfold web server for nucleic acid folding and hybridization prediction." Nucleic acids research, 31.13 (2003): 3406-3415.
  8. Reuter, Jessica S., and David H. Mathews. "RNAstructure: software for RNA secondary structure prediction and analysis." BMC bioinformatics, 11.1 (2010): 129.
  9. Xie, Kabin, and Yinong Yang. "RNA-guided genome editing in plants using a CRISPR–Cas system." Molecular plant, 6.6 (2013): 1975-1983.