Team:Calgary/Project/BsDetector

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<p><center><b>Figure 1: DNA detection via homologous recombination.</b>
<p><center><b>Figure 1: DNA detection via homologous recombination.</b>
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<i><b>a)</b></i> Reporter operon consisting of a constitutive promoter (grey arrow), ribosome-binding site (RBS; semicircle), operator (orange), and coding sequence of a reporter (e.g. GFP; green). Expression of the reporter is repressed in the default state.
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<i><b>A)</b></i> Reporter operon consisting of a constitutive promoter (grey arrow), ribosome-binding site (RBS; semicircle), operator (orange), and coding sequence of a reporter (e.g. GFP; green). Expression of the reporter is repressed in the default state.
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<i><b>b)</b></i> Repressor system for regulation of reporter expression.
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<i><b>B)</b></i> Repressor system for regulation of reporter expression.
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<b>i)</b> Repressor operon consisting of a repressor driven by a constitutive promoter. Expression of the repressor inhibits the expression of the reporter - the repressor specifically targets the operator shown in <i><b>a)</b></i>. Blue regions indicate flanking sequences that are homologous to the amplified target DNA as shown in <i><b>ii)</b></i>. Upon homologous recombination (dotted lines), the disruption of the repressor operon leads to active reporter expression.  
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<i><b>i)</b></i> Repressor operon consisting of a repressor driven by a constitutive promoter. Expression of the repressor inhibits the expression of the reporter - the repressor specifically targets the operator shown in <i><b>a)</b></i>. Blue regions indicate flanking sequences that are homologous to the amplified target DNA as shown in <i><b>ii)</b></i>. Upon homologous recombination (dotted lines), the disruption of the repressor operon leads to active reporter expression.  
<i><b>ii)</b></i> Target DNA from pathogen, amplified via isothermal-PCR (iPCR). Blue regions indicate sequences homologous to the flanking regions of the repressor operon as shown in <i><b>i)</b></i>.</p></center>
<i><b>ii)</b></i> Target DNA from pathogen, amplified via isothermal-PCR (iPCR). Blue regions indicate sequences homologous to the flanking regions of the repressor operon as shown in <i><b>i)</b></i>.</p></center>

Revision as of 07:59, 17 October 2014

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B.s. Detector

The B.s. detector is a diagnostic tool designed to simultaneously identify the presence of several pathogens within a blood sample through the detection of specific sequences within genomic DNA. At the core of our device lies the gram positive - and eponymous - bacteria B. subtilis which has been genetically modified to harbour two specific operons (a cluster of genes intended to be activated together) of our own design working in tandem. The first operon (i.e., the reporter operon) consists of the lacZ gene along with an operator gene which is necessary for the function of lacZ.lacZ, when operational, is designed to produce a blue pigment (5,5'-dibromo-4,4'-dichloro-indigo) in the presence of the organic compound X-gal. The second operon (i.e., the repressor operon) consists of a repressor gene designed to inhibit the function of the first operon and prevent the blue pigment from being synthesized. The repressor gene is surrounded by two flanking sequences on the 5' and 3' ends which will play a crucial role in the diagnostic mechanism of our device. The flanking regions are designed to share a high level of homology with target sequences found within the genome of our pathogens of interest. These sequences will be identified beforehand using public genome data repositories. Upon contact with a pathogen, the flanking regions within our repressor operon will recognize the target sequence and undergo homologous recombination, a process in which nucleotide sequences of a certain size are exchanged between two similar (homologous) DNA molecules. Homologous recombination will result in the flanking regions - and the repressor gene sandwiched in between - "switching places" with the target sequence. With the repressor gene removed, the repressor operon will no longer be able to inhibit the report operon and blue pigment will consequently be produced. Essentially, the presence of a certain pathogen will be indicated by a easily identifiable colorimetric output.

In summary, our genetically engineered B. subtilis will by default be in a negative state and lack blue pigment due to the repression of the reporter operon by the repressor. However, upon contact with a target sequence, the repressor gene will be removed from the repressor operon through homologous recombination and the reporter operon will be free to produce the pigment. This simple negative (no colour) to positive (colour) transition is the basis of presenting the diagnostic assay's results.

Figure 1: DNA detection via homologous recombination. A) Reporter operon consisting of a constitutive promoter (grey arrow), ribosome-binding site (RBS; semicircle), operator (orange), and coding sequence of a reporter (e.g. GFP; green). Expression of the reporter is repressed in the default state. B) Repressor system for regulation of reporter expression. i) Repressor operon consisting of a repressor driven by a constitutive promoter. Expression of the repressor inhibits the expression of the reporter - the repressor specifically targets the operator shown in a). Blue regions indicate flanking sequences that are homologous to the amplified target DNA as shown in ii). Upon homologous recombination (dotted lines), the disruption of the repressor operon leads to active reporter expression. ii) Target DNA from pathogen, amplified via isothermal-PCR (iPCR). Blue regions indicate sequences homologous to the flanking regions of the repressor operon as shown in i).

The genetically engineered B. subtilis and two interacting operons constitute the in vivo detection component of our device. The physical device will consist of a single, self-contained unit made from a combination of lightweight and durable polymers.

general image of device here

The blood or fluid sample given by the patient will be placed into a small outlet located in the body of the device and flow into the main chamber through gravitational force. However, preparation of the sample must be conducted prior to the diagnostic assay as the B. subtilis will be unable to identify the target sequence if it remains integrated into the genome. First, the target sequence will be amplified using a recombinase-based amplification method in order to create multiple DNA replicates and isolate the sequence from the rest of the genome. This will enhance the sensitivity of the device as the B. subtilis will have a much easier time recognizing and absorbing the target sequence if a large number of replicates are present within the sample. Isothermal amplification is a crucial requirement for our device because our objective is to implement it in regions where resources such as electricity and a thermocycler may not always be available. Amplification will be conducted using a recombinase enzyme and Taq DNA Polyermase capable of functioning within human blood (“Blood-Taq”). The presence of Taq DNA Polyermase specially designed to function in blood is essential to our isthoermal amplification method because human blood is heavily concentrated with various enzyme inhibitors. The entire sample preparation process will take approximately 1 hour and occur at a constant temperature between x to x degrees. 37 degrees is the optimum temperature and will yield the greatest concentration of DNA replicates, but isothermal amplification can function at an adequate level within the aforementioned temperature range. Upon completion, the processed sample will be forced into the several adjacent chambers by pressing a plunger located at the top of the device.

The sample will divide and enter each secondary chamber through small tubes lined with a inner Teflon coating. The Teflon coating ensures that no volume of sample adheres to the inside of the tube during transport. Mathematical models and fluid flow analysis were conducted to align the tubes in such a way that each chamber receives an equal volume of sample at an identical rate and pressure. Each chamber will contain a sample of our genetically modified B. subtilis and will be representative of a single pathogen. For example, if we wish to simultaneously test for malaria, typhoid fever, and meningitis, our device would have three secondary chambers corresponding to three separate diseases. Depending on which pathogen is to be identified, the repressor gene will consists of different flanking regions specific to the pathogen's target sequence. Once the blood sample comes into contact with the B. subtilis contained within the chambers, a colourimetric output will be acquired through the repression and homologous recombination mechanism mentioned previously. We decided on colourimetric output as the basis for diagnostic results due to its easily understood binary format. In keeping with the notion of affordability and convenience, our device was designed to be utilized by a broad spectrum of end-users, including the untrained layman if necessary.

3D Device Animation using Autodesk Maya (Click here if video isn't working)

A major feature of our diagnostic tool is its ability to detect a wide variety of pathogens simply by modifying the flanking regions surrounding the repressor gene. As for the target sequences, our experiments have shown that a sequence only needs to be roughly 150bp in length in order to recombine with the flanking regions. In theory, our genetically engineered B. subtilis could be customized to detect any pathogen whose genome has been sequenced to the extent where choosing a 150bp target sequence is possible. With the presence of ever-expanding public genome databases, the number of diseases our device can diagnose will continue to grow. Beyond the field medical diagnostics, our device could be used as part of molecular biology techniques to detect various DNA or RNA sequences, similar to DNA microarrays. If used properly, the applications of our device can be expansive.