Difference between revisions of "Team:Birkbeck/Discussion"

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<h2><u><b>Discussion</b></u></h2>
 
<h2><u><b>Discussion</b></u></h2>
 
<h2>Under construction</h2>
 
<h2>Under construction</h2>
<!--<h3><b><u>Signal Detection</u></b></h3>
+
<h3><b><u>Signal Detection</u></b></h3>
<p><b><u></u></b></p>
+
<!--<p><b><u></u></b></p>
  
where is this going?
+
 
<p>30 cfu/mL of sputum was the detection limit when targeting the 16s rRNA of <i>Mycobacterium</i> by TCR-2 (Drouillon <i>et al</i>., 2009 [they did not show this data]).
+
However, some bacteria (such as <i>Staphylococcus aureus</i>) are resistant to the decontamination kits and therefore appropriate controls need to be set up. A key point to note here is that the decontamination step must not be carried out for <em>longer than 15 minutes</em> due to the reduction in cell viability of <i>Mycobacterium</i> cell (refer to <a href="https://catalog.hardydiagnostics.com/cp_prod/Content/hugo/TBPrepKit.htm">the kit</a>).</p>-->
This is clearly a low detection limit. Considering the components of sputum & localisation of cells, it is unclear the efficiency of transduction our product will have on the samples. <a href="https://catalog.hardydiagnostics.com/cp_prod/Content/hugo/TBPrepKit.htm">Kits</a> are available for decontamination of sputum samples and degrading components of the sputum. Adding this step prior to exposure of the recombinant phage to samples may be a means of improving transduction efficiency and therefore reducing the detection limit. However, some bacteria (such as <i>Staphylococcus aureus</i>) are resistant to the decontamination kits and therefore appropriate controls need to be set up. a key point to note here is that the decontamination step must not be carried out for <em>longer than 15 minutes</em> due to the reduction in cell viability of <i>Mycobacterium</i> cell (refer to <a href="https://catalog.hardydiagnostics.com/cp_prod/Content/hugo/TBPrepKit.htm">the kit</a>).</p>
+
  
 
<p>Considering our results, at time 0 minutes, there is a significant signal for P1-<i>gfp</i> expression device compared to the <i>E. coli</i> DH5α (P=0.005, with reference to <b>Fig. 9</b> in results section). This result cannot be regarded as this is probably carry over fluorescence from sub-culturing.  Photo-bleaching prior to the first reading may yield more accurate readings when considering the expression of <i>gfp</i> from promoters. Also the error bars in each of the expression devices do appear excessive. A means of reducing this may be to sub-culture the cells & grow to an OD<sub>600</sub> of 0.2 and sub-culturing into experimental cultures in order to minimise the error bars.</p>
 
<p>Considering our results, at time 0 minutes, there is a significant signal for P1-<i>gfp</i> expression device compared to the <i>E. coli</i> DH5α (P=0.005, with reference to <b>Fig. 9</b> in results section). This result cannot be regarded as this is probably carry over fluorescence from sub-culturing.  Photo-bleaching prior to the first reading may yield more accurate readings when considering the expression of <i>gfp</i> from promoters. Also the error bars in each of the expression devices do appear excessive. A means of reducing this may be to sub-culture the cells & grow to an OD<sub>600</sub> of 0.2 and sub-culturing into experimental cultures in order to minimise the error bars.</p>
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<br>
 
<br>
  
<p>Considering culture time at 20 minutes, there is a significant signal for P1-<i>gfp</i> (P=0.002) with no difference between the OD<sub>600</sub> growth curves at this point (P=1). This is significantly less than the hours taken for results to be generated by TCR-2 (Drouillon <i>et al</i>., 2009). Cells cannot be quantified at the 20 minutes time point as no viable count was carried out, therefore the detection limit of the <i>E. coli</i> DH5α with regards to fluorescence cannot be determined. With regards to <a href="https://catalog.hardydiagnostics.com/cp_prod/Content/hugo/TBPrepKit.htm">Decontamination Kits</a>, samples would take just under one hour to process. As transduction was not characterised in this study, it is difficult to assess exactly how long this step may take.</p>  
+
<p>One technique which has been developed is transcription-reverse transcription concerted reaction (TCR) (Ishiguro <i>et al</i>., 1996). The TCR protocol was adapted in order to improve sensitivity for detecting <i>M. tuberculosis</i> from clinical sputum samples (Drouillon <i>et al</i>., 2009 [TCR-2]). Considering P1-<i>gfp</i> culture at 20 minutes, there is a significant fluorescent signal (P=0.002) with no difference between the OD<sub>600</sub> growth curves at this point (P=1). This is significantly less than the hours taken for results to be generated by TCR-2 (Drouillon <i>et al</i>., 2009). Cells cannot be quantified at the 20 minutes time point as no viable count was carried out, therefore the detection limit of the <i>E. coli</i> DH5α with regards to fluorescence cannot be determined.</p>
  
<p>Considering the application of D29 <i>Mycobacteriophage</i> could be spotted directly onto soft agar plates giving rise to plaques on both <i>M. smegmatis</i> & <i>M. tuberculosis</i> (Sampson <i>et al</i>., 2009). A <i>Mycobacteriophage</i> assay for detection of live <i>Mycobacterium</i> cells has previously been carried out using a plaque assay (Alcaide <i>et al</i>., 2003). A 1 mL decontaminated sample was washed and grown overnight in the standard <i>Mycobacterium</i> media <b>Middlebrook 7H9</b> supplemented with 10% (vol/vol) oleic acid-albumin-dextrose catalase (OADC) (Alcaide <i>et al</i>., 2003). 100 μL of <i>Mycobacteriophage</i> was added to the overnight cultures and incubated at 37<sup>o</sup>C for 1 hour before adding 100 μL of viricidal solution (Alcaide <i>et al</i>., 2003). A soft agar lawn was poured and incubated for 24 hours before counting plaques.</p>
+
<p>With regards to <a href="https://catalog.hardydiagnostics.com/cp_prod/Content/hugo/TBPrepKit.htm">Decontamination Kits</a>, samples would take just under one hour to process. Of note, some bacteria (such as <i>Staphylococcus aureus</i>) can be resistant to decontamination (refer to the kit previously mentioned). A key point to note here is that the decontamination step must not be carried out for <em>longer than 15 minutes</em> due to the reduction in cell viability of <i>Mycobacterium</i> cells.</p>  
  
<p>Considering the presorption phase of the assay developed by Alcaide <i>et al</i>, this would add an hour onto the protocol. Given that transduction is 100% efficient (unlikely) and that the kinetics of <i>gfp</i> expression behaves the same in <i>E. coli</i> DH5α, we are looking at from sputum sample collection until signal detection at approximately 2 hours & 30 minutes.</p>
+
<p>As transduction was not characterised in this study, it is difficult to assess exactly how long this step may take. Considering the application of D29 mycobacteriophage could be spotted directly onto soft agar plates giving rise to plaques on both <i>M. smegmatis</i> & <i>M. tuberculosis</i> (Sampson <i>et al</i>., 2009). A mycobacteriophage assay for detection of live <i>Mycobacterium</i> cells has previously been carried out using a plaque assay (Alcaide <i>et al</i>., 2003). A 1 mL decontaminated sample was washed and grown overnight in the standard <i>Mycobacterium</i> media <b>Middlebrook 7H9</b> supplemented with 10% (vol/vol) oleic acid-albumin-dextrose catalase (OADC) (Alcaide <i>et al</i>., 2003). 100 μL of mycobacteriophage was added to the overnight cultures and incubated at 37<sup>o</sup>C for 1 hour before adding 100 μL of viricidal solution (Alcaide <i>et al</i>., 2003). A soft agar lawn was poured and incubated for 24 hours before counting plaques.</p> 
 +
 
 +
<p>Considering the presorption phase of the assay developed by Alcaide <i>et al</i>, this would add an hour onto the protocol. Given that transduction is 100% efficient (unlikely) and that the kinetics of <i>gfp</i> expression behaves the same in <i>E. coli</i> DH5α as does a <i>Mycobacterium</i> sp. (another wild assumption), we are looking at from sputum sample collection until signal detection at approximately 2 hours & 30 minutes.</p>
 
   
 
   
 
<br>
 
<br>
  
 
<p>Considering our results, at 1 hour of culturing <i>E. coli</i> DH5α, there is a significant signal observed from the culture expressing the P1-<i>gfp</i> expression device (P<0.001). Considering the growth, there was no significant difference between the OD<sub>600</sub> of the P1-<i>gfp</i> expression device & the <i>E. coli</i> without plasmid (P=1 for both 50 mL cultures & 200 μL, with reference to <b>Fig. 1</b> & <b>Fig. 5</b> respectively). At the 1 hour time point, there is a significant difference between the 50 mL & 200 μL cultures (P=0.017) with the 200 μL cultures showing a higher OD<sub>600</sub>. This entails that the fluorescence of the 200 μL cultures at 1 hour corresponds to a higher culture density than 2.57×10<sup>6</sup> cfu/mL.</p>  
 
<p>Considering our results, at 1 hour of culturing <i>E. coli</i> DH5α, there is a significant signal observed from the culture expressing the P1-<i>gfp</i> expression device (P<0.001). Considering the growth, there was no significant difference between the OD<sub>600</sub> of the P1-<i>gfp</i> expression device & the <i>E. coli</i> without plasmid (P=1 for both 50 mL cultures & 200 μL, with reference to <b>Fig. 1</b> & <b>Fig. 5</b> respectively). At the 1 hour time point, there is a significant difference between the 50 mL & 200 μL cultures (P=0.017) with the 200 μL cultures showing a higher OD<sub>600</sub>. This entails that the fluorescence of the 200 μL cultures at 1 hour corresponds to a higher culture density than 2.57×10<sup>6</sup> cfu/mL.</p>  
<p>Considering the TCR-2 method of detection, 2.57×10<sup>6</sup> cfu/mL is an increase in detection limit by a magnitude of 10^5 (30 cfu of <i>M. tuberculosis</i>/mL of sputum [Drouillon <i>et al</i>., 2009]) which is clearly an undesirable due to the slow growth of <i>M. tuberculosis</i>. The detection of a signal at the 20 minute time point </p>
 
  
<p>As transduction was not characterised in this study, it is difficult to assess the potential limitations of this product might be.</p>-->  
+
<p>Considering the TCR-2 method of detection, 2.57×10<sup>6</sup> cfu/mL is an increase in detection limit by a magnitude of 10<sup>5</sup> (30 cfu of <i>M. tuberculosis</i>/mL of sputum [Drouillon <i>et al</i>., 2009]) which is clearly an undesirable due to the slow growth of <i>M. tuberculosis</i>. There appears to be a reduction in fluorescence from the P1-<i>gfp</i> expression device after 20 minutes which might correspond to the depletion of mRNA/GFP. The increase in fluorescence when comparing the 20 & 40 minute time points may be the expression of <i>gfp</i> from each of the promoter increasing to a detectable level.</p>
 +
 
 +
<br>
 +
 
 +
<p>An interesting observation was made on the growth kinetics of the <i>E. coli</i> DH5α containing P1-<i>gfp</i> expression device & <i>E. coli</i> DH5α not containing any plasmid. Between 100-400 minutes, the <i>E. coli</i> DH5α containing P1-<i>gfp</i> expression device has a significantly lower OD<sub>601</sub> & higher fluorescence when compared to <i>E. coli</i> DH5α. The significant difference is not observed in the positive control or P2-<i>gfp</i> expression device with limited detection of fluorescence. This data suggests that compromising cellular growth with regard to expression of a signal may yield a quicker detection of a signal with the product.</p>
 +
 
 +
<p>It is obvious that the P1 promoter will not be able to drive gene expression in all kinds of bacteria. The proposed T7-RNAP-driven <i>rfp</i> expression was not characterised as the circuit was not constructed due to cloning issues. However, the growth kinetics would be expected to be slower than that of the P1-<i>gfp</i> expression device. </p>
 +
 
 +
<br><hr><br>
 +
 
 +
<h4><u>Reference</u></h4>
 +
<h5><u>Signal Detection</u></h5>
 +
 
 +
<li><b>Alcaide F., Gali N., Dominguez J., Berlanga P., Blanco S., Orus P. & Martin R.</b> (2003). Usefulness of a New Mycobacteriophage-Based Technique for Rapid Diagnosis of Pulmonary Tuberculosis. <i>Journal of Clinical Microbiology</i> Vol. 41, No. 7, p2867-2871.</li>
 +
 
 +
<li><b>Drouillon V., Deloogu G., Dettori G., Lagrange P.H., Benecchi M., Houriez F., Baroli K., Ardito F., Torelli R., Chezzi C., Fadda G. & Herrman J-L.</b> (2009). Multicenter Evaluation of a Transcription-Reverse Transcription Concerted Assay for Rapid Detection of <i>Mycobacterium tuberculosis</i> Complex in Clinical Specimens. <i>Journal of Clinical Microbiology</i>, Vol. 47, p3461-3465.</li>
 +
 
 +
<li><b>Ishiguro T., Saitoh J., Yawata H., Otsuka M., Inoue T. & Sugiura Y.</b> (1996). Fluorescence Detection of Specific Sequence of Nucleic Acids by Oxazole Yellow-Linked Oligonucleotides. Homogeneous Quantitative Monitoring of <i>in-vitro</i> Transcription. <i>Nucleic Acids Research</i>, Vol. 24, No. 24, p4992-4997</li>
 +
 
 +
<li><b>Sampson T., Broussard G.W., Marinelli L.J., Jacobs-Sera D., Ray M., Ko C-C., Russell D., Hendrix R.W. & and Graham F. Hatfull G.F.</b> (2009). Mycobacteriophages BPs, Angel and Halo: Comparative Genomics Reveals a Novel Class of Ultra-Small Mobile Genetic Elements. <i>Microbiology</i>, Vol. 155, p2962-2977</li>
 +
 
 +
 
  
  

Revision as of 19:52, 16 September 2015

Discussion

Under construction

Signal Detection

Considering our results, at time 0 minutes, there is a significant signal for P1-gfp expression device compared to the E. coli DH5α (P=0.005, with reference to Fig. 9 in results section). This result cannot be regarded as this is probably carry over fluorescence from sub-culturing. Photo-bleaching prior to the first reading may yield more accurate readings when considering the expression of gfp from promoters. Also the error bars in each of the expression devices do appear excessive. A means of reducing this may be to sub-culture the cells & grow to an OD600 of 0.2 and sub-culturing into experimental cultures in order to minimise the error bars.


One technique which has been developed is transcription-reverse transcription concerted reaction (TCR) (Ishiguro et al., 1996). The TCR protocol was adapted in order to improve sensitivity for detecting M. tuberculosis from clinical sputum samples (Drouillon et al., 2009 [TCR-2]). Considering P1-gfp culture at 20 minutes, there is a significant fluorescent signal (P=0.002) with no difference between the OD600 growth curves at this point (P=1). This is significantly less than the hours taken for results to be generated by TCR-2 (Drouillon et al., 2009). Cells cannot be quantified at the 20 minutes time point as no viable count was carried out, therefore the detection limit of the E. coli DH5α with regards to fluorescence cannot be determined.

With regards to Decontamination Kits, samples would take just under one hour to process. Of note, some bacteria (such as Staphylococcus aureus) can be resistant to decontamination (refer to the kit previously mentioned). A key point to note here is that the decontamination step must not be carried out for longer than 15 minutes due to the reduction in cell viability of Mycobacterium cells.

As transduction was not characterised in this study, it is difficult to assess exactly how long this step may take. Considering the application of D29 mycobacteriophage could be spotted directly onto soft agar plates giving rise to plaques on both M. smegmatis & M. tuberculosis (Sampson et al., 2009). A mycobacteriophage assay for detection of live Mycobacterium cells has previously been carried out using a plaque assay (Alcaide et al., 2003). A 1 mL decontaminated sample was washed and grown overnight in the standard Mycobacterium media Middlebrook 7H9 supplemented with 10% (vol/vol) oleic acid-albumin-dextrose catalase (OADC) (Alcaide et al., 2003). 100 μL of mycobacteriophage was added to the overnight cultures and incubated at 37oC for 1 hour before adding 100 μL of viricidal solution (Alcaide et al., 2003). A soft agar lawn was poured and incubated for 24 hours before counting plaques.

Considering the presorption phase of the assay developed by Alcaide et al, this would add an hour onto the protocol. Given that transduction is 100% efficient (unlikely) and that the kinetics of gfp expression behaves the same in E. coli DH5α as does a Mycobacterium sp. (another wild assumption), we are looking at from sputum sample collection until signal detection at approximately 2 hours & 30 minutes.


Considering our results, at 1 hour of culturing E. coli DH5α, there is a significant signal observed from the culture expressing the P1-gfp expression device (P<0.001). Considering the growth, there was no significant difference between the OD600 of the P1-gfp expression device & the E. coli without plasmid (P=1 for both 50 mL cultures & 200 μL, with reference to Fig. 1 & Fig. 5 respectively). At the 1 hour time point, there is a significant difference between the 50 mL & 200 μL cultures (P=0.017) with the 200 μL cultures showing a higher OD600. This entails that the fluorescence of the 200 μL cultures at 1 hour corresponds to a higher culture density than 2.57×106 cfu/mL.

Considering the TCR-2 method of detection, 2.57×106 cfu/mL is an increase in detection limit by a magnitude of 105 (30 cfu of M. tuberculosis/mL of sputum [Drouillon et al., 2009]) which is clearly an undesirable due to the slow growth of M. tuberculosis. There appears to be a reduction in fluorescence from the P1-gfp expression device after 20 minutes which might correspond to the depletion of mRNA/GFP. The increase in fluorescence when comparing the 20 & 40 minute time points may be the expression of gfp from each of the promoter increasing to a detectable level.


An interesting observation was made on the growth kinetics of the E. coli DH5α containing P1-gfp expression device & E. coli DH5α not containing any plasmid. Between 100-400 minutes, the E. coli DH5α containing P1-gfp expression device has a significantly lower OD601 & higher fluorescence when compared to E. coli DH5α. The significant difference is not observed in the positive control or P2-gfp expression device with limited detection of fluorescence. This data suggests that compromising cellular growth with regard to expression of a signal may yield a quicker detection of a signal with the product.

It is obvious that the P1 promoter will not be able to drive gene expression in all kinds of bacteria. The proposed T7-RNAP-driven rfp expression was not characterised as the circuit was not constructed due to cloning issues. However, the growth kinetics would be expected to be slower than that of the P1-gfp expression device.



Reference

Signal Detection
  • Alcaide F., Gali N., Dominguez J., Berlanga P., Blanco S., Orus P. & Martin R. (2003). Usefulness of a New Mycobacteriophage-Based Technique for Rapid Diagnosis of Pulmonary Tuberculosis. Journal of Clinical Microbiology Vol. 41, No. 7, p2867-2871.
  • Drouillon V., Deloogu G., Dettori G., Lagrange P.H., Benecchi M., Houriez F., Baroli K., Ardito F., Torelli R., Chezzi C., Fadda G. & Herrman J-L. (2009). Multicenter Evaluation of a Transcription-Reverse Transcription Concerted Assay for Rapid Detection of Mycobacterium tuberculosis Complex in Clinical Specimens. Journal of Clinical Microbiology, Vol. 47, p3461-3465.
  • Ishiguro T., Saitoh J., Yawata H., Otsuka M., Inoue T. & Sugiura Y. (1996). Fluorescence Detection of Specific Sequence of Nucleic Acids by Oxazole Yellow-Linked Oligonucleotides. Homogeneous Quantitative Monitoring of in-vitro Transcription. Nucleic Acids Research, Vol. 24, No. 24, p4992-4997
  • Sampson T., Broussard G.W., Marinelli L.J., Jacobs-Sera D., Ray M., Ko C-C., Russell D., Hendrix R.W. & and Graham F. Hatfull G.F. (2009). Mycobacteriophages BPs, Angel and Halo: Comparative Genomics Reveals a Novel Class of Ultra-Small Mobile Genetic Elements. Microbiology, Vol. 155, p2962-2977


    • Sean Ross Craig (data analysis, cloning, restriction diagnostics, measurements & uploading content to the wiki), Elliott Parris (measurements & restriction diagnostics), Rachel Wellman (restriction diagnostics & measurements) & Ariana Mirzarafie-Ahi (cloning).


    With thanks to Dr. Vitor Pinheiro, Dr. Jane Nicklin, Bilkis Kazi, Barbara "Babz" Steijl, Luba "Aunty" Prout.