Difference between revisions of "Team:Dundee/Part Collection"

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<h2>FluID- Blood Detection</h2>
 
<h2>FluID- Blood Detection</h2>
  
             <p>Coding sequence for Human haemoglobin A. Haemoglobin is the tetrameric protein molecule in red blood cells that carries oxygen. It is composed of four polypeptide chains, which in adults consist of two alpha (a) globin chains and two beta (b) globin chains. In blood plasma, haptoglobin binds free haemoglobin released from red blood cells, inhibiting its oxidative activity. The haptoglobin-hemoglobin complex can then be removed by the reticuloendothelial system which is a part of the immune system. Despite this, haemoglobin is still found free in the blood plasma at a concentration of up to 0.1g/l and this is what we hope to detect.</p>
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             <p>A synthetic coding sequence for Human haemoglobin A. The protein forms part of a tetramer consisting of two alpha-chains and two beta-chains (see BBa_K1590001 for haemoglobin B). The sequence was codon optimized for expression in an Escherichia coli chassis.</p>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590000">Registry page for this part</a></div>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590000">Registry page for this part</a></div>
 
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         <div class="col-md-6">
 
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               <figure align="center">
 
               <figure align="center">
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590001.png">
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                 <img class="report-img" src="">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> This figure illustrates the relationship between fingertip, substrate and environmental conditions which collectively form a fingerprint and its constituents.</p>
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                       <p><b>Figure 1 -</b></p>
 
                     </figcaption>
 
                     </figcaption>
 
               </figure>
 
               </figure>
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<h2>FluID- Blood Detection</h2>
 
<h2>FluID- Blood Detection</h2>
  
             <p>Coding sequence for Human haemoglobin A. Haemoglobin is the tetrameric protein molecule in red blood cells that carries oxygen. It is composed of four polypeptide chains, which in adults consist of two alpha (a) globin chains and two beta (b) globin chains. In blood plasma, haptoglobin binds free haemoglobin released from red blood cells, inhibiting its oxidative activity. The haptoglobin-hemoglobin complex can then be removed by the reticuloendothelial system which is a part of the immune system. Despite this, haemoglobin is still found free in the blood plasma at a concentration of up to 0.1g/l and this is what we hope to detect.</p>
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             <p> A synthetic coding sequence for Human haemoglobin A. The protein forms part of a tetramer consisting of two alpha-chains and two beta-chains (see BBa_K1590001 for haemoglobin B). The sequence was codon optimized for expression in an Escherichia coli chassis.</p>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590001">Registry page for this part</a></div>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590001">Registry page for this part</a></div>
 
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                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590001.png">
 
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590001.png">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> Characterisation of haemoglobin beta following SEC (size exclusion chromatography). A) The sample of concentrated fractions containing haemoglobin beta from nickel affinity purification was loaded onto a SEC column and the protein was eluted. B) 10µl of each fraction corresponding to the two observed peaks was mixed with 10µl of laemmli buffer and loaded onto a SDS gel (12.5% acrylamide). The bands observable on the gel are in line with the expected size of haemoglobin beta - 16kDa. C) Western blotting was then carried out against an anti-his antibody to confirm the presence of hHHB- His.</p>
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                       <p><b>Figure. </b> Characterisation of haemoglobin B. A) Concentrated protein fractions eluted during the nickel affinity purification step were then further purified by size exclusion chromatography (SEC). B) 10µl of each fraction corresponding to the two observed peaks were mixed with 10µl of laemmli buffer and loaded onto a SDS gel (12.5% acrylamide) and stained with Coomassie Blue and also C) transferred to nitrocellulose membrane and probed with an anti-His antibody. The bands observable on both the stained gel and western blot were similar to the expected size of haemoglobin B - 16kDa. </p>
 
                     </figcaption>
 
                     </figcaption>
 
               </figure>
 
               </figure>
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<h2>FluID- Blood Detection</h2>
 
<h2>FluID- Blood Detection</h2>
  
             <p>Coding sequence for Human haemoglobin A. Haemoglobin is the tetrameric protein molecule in red blood cells that carries oxygen. It is composed of four polypeptide chains, which in adults consist of two alpha (a) globin chains and two beta (b) globin chains. In blood plasma, haptoglobin binds free haemoglobin released from red blood cells, inhibiting its oxidative activity. The haptoglobin-hemoglobin complex can then be removed by the reticuloendothelial system which is a part of the immune system. Despite this, haemoglobin is still found free in the blood plasma at a concentration of up to 0.1g/l and this is what we hope to detect.</p>
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             <p> Haptoglobin is a human protein with high affinity for haemoglobin. This biobrick is a synthetic gene optimized for expression in E. coli.. In blood plasma, haptoglobin binds free haemoglobin released from red blood cells</p>
 
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         <div class="col-md-6">
 
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               <figure align="center">
 
               <figure align="center">
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590002.png">
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                 <img class="report-img" src=" https://static.igem.org/mediawiki/2015/f/f9/Dundee2015characterisationBBa_K1590002.png ">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> Characterization of Human haptoglobin following nickel affinity FPLC. A) Chromatogram showing the purification profile of the His-tagged Human haptoglobin. The fractions corresponding to the two peaks observed on the chromatograph were further analysed western blotting. B) 10µl of the fractions A8-A10 were mixed with 10µl of laemmli buffer and samples separated by SDS-PAGE (12.5% acrylamide) and transferred to a nitrocellulose membrane and probed with an anti-His antibody. The western blot shows successful production of hHHB – His (expected size 45kDa).p>
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                       <p><b>Figure 1 -</b> Figure 2: Further characterization of human haptoglobin following SEC. A) Chromatogram showing the elution profile of the His-tagged human haptoglobin. The fractions corresponding to the two peaks observed on the chromatograph were further analysed by SDS page gel and western blotted. B) 10µl of the fractions A7-A8 and A8-A9 corresponding to peaks 1 + 2, respectively were mixed with 10µl of Laemmli buffer and loaded onto a 12.5% SDS-PAGE gel. Band A observed on the gel corresponds to the expected size of haptoglobin – 45kDa. However, it is not clear what the bands present at ~37kDa may be, possibly haptoglobin that has lost its His-tag. C) Samples separated by SDS-PAGE were transferred to a nitrocellulose membrane and probed with an anti-his antibody. This Western blot analysis confirmed the presence of human haptoglobin. p>
 
                     </figcaption>
 
                     </figcaption>
 
               </figure>
 
               </figure>
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<h2> Chromate Detection </h2>
 
<h2> Chromate Detection </h2>
  
             <p> Chromate responsive promoter. The promoter P<sub><i>Chr</sub></i> is suspected to be inducible by chromate.</p>
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             <p> This promoter is found upstream of the ChrBACF - operon in Ochrobactrum tritici 5bvl1, located in the transposable element TnOtChr of 7189bp length. Pchr is suspected to be inducible by chromate via the chromate-responsive repressor ChrB. </p>
 
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                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590003">Registry page for this part</a></div>
 
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               <figure align="center">
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590003.png">
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                 <img class="report-img" src=" https://static.igem.org/mediawiki/2015/9/93/Dundee2015characterisationBBa_K1590003.png ">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> >  Single colonies of JM110 + pSB1C3-Pchr-gfp (A) and MC1061 + pSB1C3-Pchr-gfp (B) were prepared for western blotting against GFP.</p>
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                       <p><b>Figure 1 -</b> >  Figure 2: Western analysis of GFP production driven by the chr promoter: Single colonies of JM110 + pSB1C3-Pchr-gfp (A) and MC1061 + pSB1C3-Pchr-gfp (B) were used to inoculate 5 ml of LB broth supplemented with 100 µg/ml chloramphenicol. After 16h of incubation at 37°C with agitation at 200rpm, each sample was subcultured into 5 ml of fresh, equally supplemented LB and cells were grown for 2 hours more. 1 ml of the subculture was then retrieved and pelleted. The pellet was resuspended in 1 ml TBS. 100 µl of the sample was mixed with 100 µl laemmli buffer, and boiled for 10min. 3 µl of each sample was loaded on a SDS gel (12% acrylamide). pSB1C3 was included as a negative control, and PmanA-gfp as a positive control. </p>
 
                     </figcaption>
 
                     </figcaption>
 
               </figure>
 
               </figure>
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<h2>FluID- Chromate Detection</h2>
 
<h2>FluID- Chromate Detection</h2>
  
             <p> Promoter sequence of chromate resistance operon of<i> Ochrobactrum tritici </i>5bvl1. Regulator or Chromate responsive promoter.
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             <p> The protein encoded by this sequence is a putative chromate-responsive repressor of P<i>chr</i> (BBa_K1590003). This sequence is found downstream of P<i>chr</i> in the ChrBACF - operon in Ochrobactrum tritici 5bvl1, located in the transposable element TnOtChr. ChrB is suspected to inhibit the otherwise constitutive promoter Pchr in the absence of Cr(VI) by binding to an imperfect inverted repeat sequence located upstream of the initial ATG codon. Cr(VI) was expected to lift this repression, leading to the expression of the genes downstream of P<i>chr</i>. </p>
The protein encoded by this sequence is a putative chromate responsive repressor of P<sub><i>Chr</sub></i> (BBa_K1590003).</p>
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                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590004">Registry page for this part</a></div>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590004">Registry page for this part</a></div>
 
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         <div class="col-md-6">
 
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               <figure align="center">
 
               <figure align="center">
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590004.png">
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                 <img class="report-img" src=" https://static.igem.org/mediawiki/2015/1/17/Dundee2015characterisationBBa_K1590004.png ">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> Comparison of presence of GFP in MG1655 + BBa_K1058008, MG1655 + pSB1C3-Pchr-gfp (A) + pUniprom-chrB, and MG1655 + pSB1C3-Pchr-gfp (A) + pUniprom-chrB (opt)  It was found that GFP was produced in the absence of chromate for both systems. This reason for these unexpected results could not be discerned, and further experiments are required to understand those. At this stage of the project the results indicate that ChrB might not be a repressor.</p>
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                       <p><b>Figure 1 -</b> Comparison of presence western blot analysis of GFP in pSB1C3-Pchr-gfp (A) + pUniprom-chrB, and pSB1C3-Pchr-gfp (A) + pUniprom-chrB (opt). It was found that GFP was produced in the absence of chromate for both systems. The reason for these unexpected results could not be discerned, and further experiments are required to understand those. At this stage of the project the results indicate that ChrB might not be a repressor.</p>
 
                     </figcaption>
 
                     </figcaption>
 
               </figure>
 
               </figure>
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<h2> Fingerprint Aging </h2>
 
<h2> Fingerprint Aging </h2>
  
             <p> Lanosterol Synthase catalyses the reaction from 2,3-oxido-squalene (squalene epoxide) to Lanosterol. It is one of the enzymes in the enzymatic cascade that converts squalene to cholesterol through stepwise modifications of the substrate.</p>
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             <p> Lanosterol synthase (LSS) an oxidosqualene cyclase (OSC) enzyme that specifically binds to squalene epoxide (2,3- oxidosqualene), which is present in fingerprints. Our modelling showed us that squalene epoxide is the compound with the most distinct degradation pattern in fingerprints, and it was hence selected as an appropriate target for approximating the age of a fingerprint.</p>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590006">Registry page for this part</a></div>
 
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590006">Registry page for this part</a></div>
 
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               <figure align="center">
 
               <figure align="center">
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590006.png">
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                 <img class="report-img" src=" https://static.igem.org/mediawiki/2015/1/10/Dundee2015characterisationBBa_K1590006.png ">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
 
                       <p><b>Figure 1 -</b> Detection of His-tagged LSS in whole cells of E.coli. Single colonies of E.coli strain M15 pREP4 harbouring LSS. Cells were used to inoculate 5ml of LB growth medium supplemented with 100ug/ml ampicillin and 50ug/ml Kanamycin. Once the OD600 reached 0.7 the cells were then induced with IPTG, as indicated. Cells were then grown for a further 4 hours at 37oC, 1ml aliquots were pelleted and cells reuspended in 100ul laemmli buffer and 20ul of samples were separated by SDS-PAGE (12% acrylamide) and transferred to nitrocellulose membrane and probed with anti-His antibody.</p>
 
                       <p><b>Figure 1 -</b> Detection of His-tagged LSS in whole cells of E.coli. Single colonies of E.coli strain M15 pREP4 harbouring LSS. Cells were used to inoculate 5ml of LB growth medium supplemented with 100ug/ml ampicillin and 50ug/ml Kanamycin. Once the OD600 reached 0.7 the cells were then induced with IPTG, as indicated. Cells were then grown for a further 4 hours at 37oC, 1ml aliquots were pelleted and cells reuspended in 100ul laemmli buffer and 20ul of samples were separated by SDS-PAGE (12% acrylamide) and transferred to nitrocellulose membrane and probed with anti-His antibody.</p>
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           <h1>Part: BBa_K1590007  (<i>hHBA</i>) </h1>
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           <h1>Part: BBa_K1590007  (<i>Obp2A</i>) </h1>
 
<h2>FluID- Nasal Mucus Detection</h2>
 
<h2>FluID- Nasal Mucus Detection</h2>
  
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               <figure align="center">
 
               <figure align="center">
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590007.png">
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                 <img class="report-img" src=" https://static.igem.org/mediawiki/2015/8/87/Dundee2015characterisationBBa_K1590007.png ">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
 
                       <p><b>Figure 1 -</b> This figure  illustrates the calculated miller’s activity of each control/sample and suggest that the OBP2A subunits aren’t interacting. This  can be gauged from the sample on the far right of each graph. They suggest that OBP2A has a lower interaction than the negative/regulatory controls.</p>
 
                       <p><b>Figure 1 -</b> This figure  illustrates the calculated miller’s activity of each control/sample and suggest that the OBP2A subunits aren’t interacting. This  can be gauged from the sample on the far right of each graph. They suggest that OBP2A has a lower interaction than the negative/regulatory controls.</p>
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<h2>FluID- Saliva Detection</h2>
 
<h2>FluID- Saliva Detection</h2>
  
             <p> Coding sequence for Lactoferrin Binding Protein A of <i>Neisseria Meningitidis</i>. This protein sequesters Iron for the host from Lactoferrin.</p>
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             <p> Coding sequence for Lactoferrin Binding Protein A of <i>Neisseria Meningitidis</i>. This protein sequesters Iron for the host from Lactoferrin. A majorfound in saliva is a free iron sequestering compound known as lactoferrin, a protein involved in the innate immune system. Neisseria meningitidis is a gram-negative bacterium with an iron-binding outer membrane protein called lactoferrin binding protein A (LbpA). N. meningitidis uses this LbpA to extract iron from the host lactoferrin under pathogenic conditions to allow for the bacterium to perform essential cellular metabolism such as energy generation and DNA replication. </p>
                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590000">Registry page for this part</a></div>
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                 <div class="button-center"><a role="button" class="btn btn-lg btn-primary" href="http://parts.igem.org/Part:BBa_K1590008">Registry page for this part</a></div>
 
         </div>
 
         </div>
  
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                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590008.png">
 
                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590008.png">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> This figure illustrates the relationship between fingertip, substrate and environmental conditions which collectively form a fingerprint and its constituents.</p>
+
                       <p></p>
 
                     </figcaption>
 
                     </figcaption>
 
               </figure>
 
               </figure>
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<h2>FluID- Semen Detection</h2>
 
<h2>FluID- Semen Detection</h2>
  
             <p> Escherichia coli </i>PotD sequence, encoding Spermidine/putrescine-binding periplasmic protein </p>
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             <p> Escherichia coli </i>PotD sequence, encoding Spermidine/putrescine-binding periplasmic protein. For semen detection our main target ligand is the polyamine spermidine which is found in relatively high concentrations in seminal fluid (5-15 mM). Spermidine is made from another polyamine called putrescine and is the precursor of spermine. Regulation of polyamine synthesis, degradation and transport is tightly controlled in bacteria. In E. coli, two of three identified transport systems are ABC transporters composed of a periplasmic binding protein, a pair of transmembrane proteins and a membrane protein possessing ATPase catalytic activity. Out of these three components, we were interested in investigating the periplasmic binding protein PotD which specifically binds spermidine. The fact that this protein is responsible for transportation of spermidine and lacking in enzymatic activity meant that it was an ideal candidate for use in FluID for semen detection </p>
 
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                 <img class="report-img" src="https://static.igem.org/mediawiki/2015/e/ea/Dundee2015characterisationBBa_K1590009.png">
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                 <img class="report-img" src=" https://static.igem.org/mediawiki/2015/3/3c/Dundee2015characterisationBBa_K1590009.png ">
 
                     <figcaption class="report-img">
 
                     <figcaption class="report-img">
                       <p><b>Figure 1 -</b> Characterization of PotD. A) Chromatogram showing the purification profile of the his-tagged Human HBN protein. The fractions corresponding to the two peaks observed on the chromatograph were further analysed on SDS page gel. B) Coomassie Stain of the purified fractions (A12 + B12). 10 µl of each fraction was mixed with 10 µl of 2x Laemmli buffer and loaded onto an SDS gel (12.5% acrylamide). C) Samples from the SEC were then western blotted using an anti-His antibody. The band detected in the blot corresponds to the expected size of PotD of 37kDa.  
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                       <p><b>Figure -</b> Further characterization of PotD following SEC. A) Chromatogram showing the purification profile of His-tagged PotD. The fractions corresponding to the two peaks observed on the chromatograph were further analysed on SDS page gel and western blotted. B) 10ul of the fractions A12 + B12 were mixed with with 10ul of Laemmli buffer and loaded onto a 12.5% SDS-PAGE gel, stained with Coomassie Blue and also C) transferred to nitrocellulose membrane and probed with an anti-His antibody. The bands observable on both the stained gel and western blot were similar to the expected size of PotD - 37kDa.  
 +
 
 
</p>
 
</p>
 
                     </figcaption>
 
                     </figcaption>
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<h2>FluID- Semen Detection</h2>
 
<h2>FluID- Semen Detection</h2>
  
             <p> Murine Spermine Binding Protein
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             <p> Synthetic coding sequence for Murine Spermine Binding Protein
Binds the carbohydrate spermine. </p>
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For semen detection our main target ligand is the polyamine spermidine which is found in relatively high concentrations in seminal fluid (5-15 mM). Spermidine is made from another polyamine called putrescine and is the precursor of spermine. Regulation of polyamine synthesis, degradation and transport is tightly controlled in bacteria. In E. coli, two of three identified transport systems are ABC transporters composed of a periplasmic binding protein, a pair of transmembrane proteins and a membrane protein possessing ATPase catalytic activity. Out of these three components, we were interested in investigating the periplasmic binding protein PotD which specifically binds spermidine. However, we made initial attempts in characterising SBP as well, and submitted the biobrick accordingly. </p>
 
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                       <p><b>Figure 1 -</b> Characterization of PotD. A) Chromatogram showing the purification profile of the his-tagged Human HBN protein. The fractions corresponding to the two peaks observed on the chromatograph were further analysed on SDS page gel. B) Coomassie Stain of the purified fractions (A12 + B12). 10 µl of each fraction was mixed with 10 µl of 2x Laemmli buffer and loaded onto an SDS gel (12.5% acrylamide). C) Samples from the SEC were then western blotted using an anti-His antibody. The band detected in the blot corresponds to the expected size of PotD of 37kDa.
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Revision as of 21:07, 18 September 2015

The Building Blocks of Our Project

Part Collection

Part: BBa_K1590000 (hHBA)

FluID- Blood Detection

A synthetic coding sequence for Human haemoglobin A. The protein forms part of a tetramer consisting of two alpha-chains and two beta-chains (see BBa_K1590001 for haemoglobin B). The sequence was codon optimized for expression in an Escherichia coli chassis.

Figure 1 -

Part: BBa_K1590001 (hHBA)

FluID- Blood Detection

A synthetic coding sequence for Human haemoglobin A. The protein forms part of a tetramer consisting of two alpha-chains and two beta-chains (see BBa_K1590001 for haemoglobin B). The sequence was codon optimized for expression in an Escherichia coli chassis.

Figure. Characterisation of haemoglobin B. A) Concentrated protein fractions eluted during the nickel affinity purification step were then further purified by size exclusion chromatography (SEC). B) 10µl of each fraction corresponding to the two observed peaks were mixed with 10µl of laemmli buffer and loaded onto a SDS gel (12.5% acrylamide) and stained with Coomassie Blue and also C) transferred to nitrocellulose membrane and probed with an anti-His antibody. The bands observable on both the stained gel and western blot were similar to the expected size of haemoglobin B - 16kDa.

Part: BBa_K1590002 (hHBN)

FluID- Blood Detection

Haptoglobin is a human protein with high affinity for haemoglobin. This biobrick is a synthetic gene optimized for expression in E. coli.. In blood plasma, haptoglobin binds free haemoglobin released from red blood cells

Figure 1 - Figure 2: Further characterization of human haptoglobin following SEC. A) Chromatogram showing the elution profile of the His-tagged human haptoglobin. The fractions corresponding to the two peaks observed on the chromatograph were further analysed by SDS page gel and western blotted. B) 10µl of the fractions A7-A8 and A8-A9 corresponding to peaks 1 + 2, respectively were mixed with 10µl of Laemmli buffer and loaded onto a 12.5% SDS-PAGE gel. Band A observed on the gel corresponds to the expected size of haptoglobin – 45kDa. However, it is not clear what the bands present at ~37kDa may be, possibly haptoglobin that has lost its His-tag. C) Samples separated by SDS-PAGE were transferred to a nitrocellulose membrane and probed with an anti-his antibody. This Western blot analysis confirmed the presence of human haptoglobin. p>

Part: BBa_K1590003 (PChr)

Chromate Detection

This promoter is found upstream of the ChrBACF - operon in Ochrobactrum tritici 5bvl1, located in the transposable element TnOtChr of 7189bp length. Pchr is suspected to be inducible by chromate via the chromate-responsive repressor ChrB.

Figure 1 - > Figure 2: Western analysis of GFP production driven by the chr promoter: Single colonies of JM110 + pSB1C3-Pchr-gfp (A) and MC1061 + pSB1C3-Pchr-gfp (B) were used to inoculate 5 ml of LB broth supplemented with 100 µg/ml chloramphenicol. After 16h of incubation at 37°C with agitation at 200rpm, each sample was subcultured into 5 ml of fresh, equally supplemented LB and cells were grown for 2 hours more. 1 ml of the subculture was then retrieved and pelleted. The pellet was resuspended in 1 ml TBS. 100 µl of the sample was mixed with 100 µl laemmli buffer, and boiled for 10min. 3 µl of each sample was loaded on a SDS gel (12% acrylamide). pSB1C3 was included as a negative control, and PmanA-gfp as a positive control.

Part: BBa_K1590004 (ChrB)

FluID- Chromate Detection

The protein encoded by this sequence is a putative chromate-responsive repressor of Pchr (BBa_K1590003). This sequence is found downstream of Pchr in the ChrBACF - operon in Ochrobactrum tritici 5bvl1, located in the transposable element TnOtChr. ChrB is suspected to inhibit the otherwise constitutive promoter Pchr in the absence of Cr(VI) by binding to an imperfect inverted repeat sequence located upstream of the initial ATG codon. Cr(VI) was expected to lift this repression, leading to the expression of the genes downstream of Pchr.

Figure 1 - Comparison of presence western blot analysis of GFP in pSB1C3-Pchr-gfp (A) + pUniprom-chrB, and pSB1C3-Pchr-gfp (A) + pUniprom-chrB (opt). It was found that GFP was produced in the absence of chromate for both systems. The reason for these unexpected results could not be discerned, and further experiments are required to understand those. At this stage of the project the results indicate that ChrB might not be a repressor.

Part: BBa_K1590006 (LSS)

Fingerprint Aging

Lanosterol synthase (LSS) an oxidosqualene cyclase (OSC) enzyme that specifically binds to squalene epoxide (2,3- oxidosqualene), which is present in fingerprints. Our modelling showed us that squalene epoxide is the compound with the most distinct degradation pattern in fingerprints, and it was hence selected as an appropriate target for approximating the age of a fingerprint.

Figure 1 - Detection of His-tagged LSS in whole cells of E.coli. Single colonies of E.coli strain M15 pREP4 harbouring LSS. Cells were used to inoculate 5ml of LB growth medium supplemented with 100ug/ml ampicillin and 50ug/ml Kanamycin. Once the OD600 reached 0.7 the cells were then induced with IPTG, as indicated. Cells were then grown for a further 4 hours at 37oC, 1ml aliquots were pelleted and cells reuspended in 100ul laemmli buffer and 20ul of samples were separated by SDS-PAGE (12% acrylamide) and transferred to nitrocellulose membrane and probed with anti-His antibody.

Part: BBa_K1590007 (Obp2A)

FluID- Nasal Mucus Detection

Human Odorant Binding Protein 2A is a 155 amino acid (excluding the signal peptide) lipocalin of relatively low molecular weight (19318 Daltons). Structurally it forms an 8 sheet beta barrel flanked by a c-terminal alpha helix that together forms an internal hydrophobic pore known as a calix. It is secreted by the olfactory epithelial cells of the nose where it lies in high abundance within nasal mucus. Its primary function in the human body is believed to be in the transport of hydrophobic odorant proteins across the otherwise impenetrable aqueous mucus layer to the olfactory receptors of the nose. Due to its high specificity and abundance within nasal mucus, OBP2A was selected as the protein for use in nasal mucus detection.

Figure 1 - This figure illustrates the calculated miller’s activity of each control/sample and suggest that the OBP2A subunits aren’t interacting. This can be gauged from the sample on the far right of each graph. They suggest that OBP2A has a lower interaction than the negative/regulatory controls.

Part: BBa_K1590008 (LbpA)

FluID- Saliva Detection

Coding sequence for Lactoferrin Binding Protein A of Neisseria Meningitidis. This protein sequesters Iron for the host from Lactoferrin. A majorfound in saliva is a free iron sequestering compound known as lactoferrin, a protein involved in the innate immune system. Neisseria meningitidis is a gram-negative bacterium with an iron-binding outer membrane protein called lactoferrin binding protein A (LbpA). N. meningitidis uses this LbpA to extract iron from the host lactoferrin under pathogenic conditions to allow for the bacterium to perform essential cellular metabolism such as energy generation and DNA replication.

Part: BBa_K1590009 (PotD)

FluID- Semen Detection

Escherichia coli PotD sequence, encoding Spermidine/putrescine-binding periplasmic protein. For semen detection our main target ligand is the polyamine spermidine which is found in relatively high concentrations in seminal fluid (5-15 mM). Spermidine is made from another polyamine called putrescine and is the precursor of spermine. Regulation of polyamine synthesis, degradation and transport is tightly controlled in bacteria. In E. coli, two of three identified transport systems are ABC transporters composed of a periplasmic binding protein, a pair of transmembrane proteins and a membrane protein possessing ATPase catalytic activity. Out of these three components, we were interested in investigating the periplasmic binding protein PotD which specifically binds spermidine. The fact that this protein is responsible for transportation of spermidine and lacking in enzymatic activity meant that it was an ideal candidate for use in FluID for semen detection

Figure - Further characterization of PotD following SEC. A) Chromatogram showing the purification profile of His-tagged PotD. The fractions corresponding to the two peaks observed on the chromatograph were further analysed on SDS page gel and western blotted. B) 10ul of the fractions A12 + B12 were mixed with with 10ul of Laemmli buffer and loaded onto a 12.5% SDS-PAGE gel, stained with Coomassie Blue and also C) transferred to nitrocellulose membrane and probed with an anti-His antibody. The bands observable on both the stained gel and western blot were similar to the expected size of PotD - 37kDa.

Part: BBa_K1590010 (Sbp)

FluID- Semen Detection

Synthetic coding sequence for Murine Spermine Binding Protein For semen detection our main target ligand is the polyamine spermidine which is found in relatively high concentrations in seminal fluid (5-15 mM). Spermidine is made from another polyamine called putrescine and is the precursor of spermine. Regulation of polyamine synthesis, degradation and transport is tightly controlled in bacteria. In E. coli, two of three identified transport systems are ABC transporters composed of a periplasmic binding protein, a pair of transmembrane proteins and a membrane protein possessing ATPase catalytic activity. Out of these three components, we were interested in investigating the periplasmic binding protein PotD which specifically binds spermidine. However, we made initial attempts in characterising SBP as well, and submitted the biobrick accordingly.