Difference between revisions of "Team:British Columbia/Growing"

Line 57: Line 57:
 
         <div style="height: 0px;" aria-expanded="false" id="collapseTwo" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingTwo">
 
         <div style="height: 0px;" aria-expanded="false" id="collapseTwo" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingTwo">
 
           <div class="panel-body">
 
           <div class="panel-body">
             <p>As no liquid growth medium for <i>S. alvi</i> or <i>G. apicola</i> have been reported in literature, a variety of liquid media growth conditions were tested (see Table 1). All liquid cultures were incubated at 37°C for 72 hours, or until turbidity could be visually detected. <i>G. apicola</i> grew in anaerobic TSB. During growth in liquid media, it was noted that <i>G. apicola</i> aggregated into dense snowflake-like colonies (Figure 3). <i>S. alvi</i> did not grow in any liquid media tested. Colony PCR and plating on oxytetracycline plates under microaerophilic conditions were used to confirm growth was <i>G. apicola</i> or <i>S. alvi</i>.  
+
             <p>As no liquid growth medium for <i>S. alvi</i> or <i>G. apicola</i> have been reported in literature, a variety of liquid media growth conditions were tested (see Table 1). All liquid cultures were incubated at 37°C for 72 hours, or until turbidity could be visually detected. <i>G. apicola</i> grew in anaerobic TSB. During growth in liquid media, it was noted that <i>G. apicola</i> aggregated into dense snowflake-like colonies (Figure 3). <i>S. alvi</i> did not grow in any liquid media tested. Colony PCR and plating on oxytetracycline plates under microaerophilic conditions were used to confirm growth as <i>G. apicola</i> or <i>S. alvi</i>.  
 
<div style="clear:both;"></div>
 
<div style="clear:both;"></div>
 
<div style="width:1000px;float:left;">
 
<div style="width:1000px;float:left;">
Line 104: Line 104:
 
         <div style="height: 0px;" aria-expanded="false" id="collapseEight" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingEight">
 
         <div style="height: 0px;" aria-expanded="false" id="collapseEight" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingEight">
 
           <div class="panel-body">
 
           <div class="panel-body">
             <p>The growth curve of G. apicola in a TSB culture was monitored on a plate reader that took OD values at 600nm. As displayed in figure 5, <i>G. apicola</i>’s lag phase lasts 15 hours. Moreover, due to it’s slow growth, it takes approximately 24 hours to reach a stationary-like growth phase.</p>  
+
             <p>The growth curve of G. apicola in a TSB culture was monitored on a plate reader that took OD values at 600nm. As displayed in figure 5, <i>G. apicola</i>’s lag phase lasts 15 hours. Moreover, due to its slow growth, it takes approximately 24 hours to reach a stationary-like growth phase.</p>  
  
 
<div style="width:900px; margin:auto;"> <img src="https://static.igem.org/mediawiki/2015/2/27/British_ColumbiaGillyCurve.jpg" width="900"><small> Figure 5: <i>G. apicola</i> growth curve. </small></div>
 
<div style="width:900px; margin:auto;"> <img src="https://static.igem.org/mediawiki/2015/2/27/British_ColumbiaGillyCurve.jpg" width="900"><small> Figure 5: <i>G. apicola</i> growth curve. </small></div>
Line 125: Line 125:
 
         <div style="height: 0px;" aria-expanded="false" id="collapseThree" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingThree">
 
         <div style="height: 0px;" aria-expanded="false" id="collapseThree" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingThree">
 
           <div class="panel-body">
 
           <div class="panel-body">
             <p>Three protocols were attempted for the creation of electrocompetent cells (<a href="https://static.igem.org/mediawiki/2015/3/3b/UBC_compcellsprotocol.pdf">protocols</a>): one designed for <i>Campylobacter jejuni</i> (similar to <i>G. apicola</i> due to it's microaerophilicity), one designed for <i>Salmonella</i> (similar to <i>G. apicola</i>, a γ-proteobacterium), and the last one designed as a general procedure for inducing electrocompetence. </p>
+
             <p>Three protocols were attempted for the creation of electrocompetent cells (<a href="https://static.igem.org/mediawiki/2015/3/3b/UBC_compcellsprotocol.pdf">protocols</a>): one designed for <i>Campylobacter jejuni</i> (similar to <i>G. apicola</i> due to its microaerophilicity), one designed for <i>Salmonella</i> (similar to <i>G. apicola</i>, a γ-proteobacterium), and the last one designed as a general procedure for inducing electrocompetence. </p>
  
 
<p>Following the protocol from Methods in Microbiology: Bacterial Pathogenesis for <i>Campylobacter jejuni</i> by Williams, P., Ketley, J., & Salmond, G. <a href="#ref">(2)</a>, <i>G. apicola</i> was grown on TSA for 48 hours at 37°C, after which the biomass was removed. Cells were washed with ice cold wash buffer of sucrose and glycerol. Competent cells were then stored at -80°C, or transformed immediately by electroporation.  </p>
 
<p>Following the protocol from Methods in Microbiology: Bacterial Pathogenesis for <i>Campylobacter jejuni</i> by Williams, P., Ketley, J., & Salmond, G. <a href="#ref">(2)</a>, <i>G. apicola</i> was grown on TSA for 48 hours at 37°C, after which the biomass was removed. Cells were washed with ice cold wash buffer of sucrose and glycerol. Competent cells were then stored at -80°C, or transformed immediately by electroporation.  </p>
Line 132: Line 132:
 
</p>  
 
</p>  
  
<p>For the last method, a general electrocompetence procedure was used to induce electrocompetence in <i>G. apicola</i> after 24-30 hours of growth in liquid TSB at 37°C. Bacteria was pelleted with a microcentrifuge and re-suspended in decreasing volumes of sterile deionized water several times, with the last re-suspension being in sterile deionized water + 20% glycerol. The bacteria were then aliquoted (60 μL) into 1.7 mL Eppendorf tubes and subjected to snap freezing with liquid nitrogen. The now competent cells were either stored at -80°C or transformed immediately by electroporation. </p>
+
<p>For the last method, a general electrocompetence procedure was used to induce electrocompetence in <i>G. apicola</i> after 24-30 hours of growth in liquid TSB at 37°C. Bacteria was pelleted with a microcentrifuge and re-suspended in decreasing volumes of sterile deionized water several times, with the last re-suspension being in sterile deionized water + 20% glycerol. The bacteria were then aliquoted (60 μL) into 1.7 mL Eppendorf tubes and subjected to snap freezing with liquid nitrogen. The now-competent cells were either stored at -80°C or transformed immediately by electroporation. </p>
  
 
           </div>
 
           </div>
Line 149: Line 149:
 
         <div style="height: 0px;" aria-expanded="false" id="collapseFour" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingFour">
 
         <div style="height: 0px;" aria-expanded="false" id="collapseFour" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingFour">
 
           <div class="panel-body">
 
           <div class="panel-body">
             <p> One protocol designed to create chemically competent cells of <i>E. coli</i> was attempted (<a href="https://static.igem.org/mediawiki/2015/3/3b/UBC_compcellsprotocol.pdf">protocol</a>), due to it's cladistic similarity to <i>G. apicola</i>. <i>G. apicola</i> was grown on TSA for 48 hours at 37C, after which the biomass was removed. Cells were then washed with a CaCl<sub>2</sub> buffer. Competent cells were stored at -80C, or transformed immediately by heat shock.
+
             <p> One protocol designed to create chemically competent cells of <i>E. coli</i> was attempted (<a href="https://static.igem.org/mediawiki/2015/3/3b/UBC_compcellsprotocol.pdf">protocol</a>), due to its cladistic similarity to <i>G. apicola</i>. <i>G. apicola</i> was grown on TSA for 48 hours at 37°C, after which the biomass was removed. Cells were then washed with a CaCl<sub>2</sub> buffer. Competent cells were stored at -80°C, or transformed immediately by heat shock.
 
</p>  
 
</p>  
 
           </div>
 
           </div>
Line 200: Line 200:
 
         <div style="height: 0px;" aria-expanded="false" id="collapseSeven" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingSeven">
 
         <div style="height: 0px;" aria-expanded="false" id="collapseSeven" class="panel-collapse collapse" role="tabpanel" aria-labelledby="headingSeven">
 
           <div class="panel-body">
 
           <div class="panel-body">
             <p>Following a modified protocol that can be viewed <a href="https://static.igem.org/mediawiki/2015/b/b6/UBC_conjugationprotocol.pdf">here</a>, <i>G. apicola</i> was grown on a TSA plate for 48 hrs. Concurrently, a conjugative <i>E.coli</i> strain (SM10 or S17) harbouring the desired plasmid to be mobilized was grown in 5 mL LB and antibiotic for 24 hrs. <i>G. apicola</i> (scraped off a TSA plate) and E. coli were combined and pelleted together, resuspended in 100 μL of LB, plated on TSA, and incubated in a microaerophilic environment for 24 hrs at 37C. Colonies were then replated on selective plates containing antibiotic specific to the plasmid used and oxytetracycline (30μg/mL) to select for <i>G. apicola</i>. <i>G. apicola</i> is naturally resistant to oxytetracycline<a href="#ref">(1)</a>.  
+
             <p>Following a modified protocol that can be viewed <a href="https://static.igem.org/mediawiki/2015/b/b6/UBC_conjugationprotocol.pdf">here</a>, <i>G. apicola</i> was grown on a TSA plate for 48 hrs. Concurrently, a conjugative <i>E.coli</i> strain (SM10 or S17) harbouring the desired plasmid to be mobilized was grown in 5 mL LB and antibiotic for 24 hrs. <i>G. apicola</i> (scraped off a TSA plate) and E. coli were combined and pelleted together, resuspended in 100 μL of LB, plated on TSA, and incubated in a microaerophilic environment for 24 hours at 37°C. Colonies were then replated on selective plates containing antibiotic specific to the plasmid used and oxytetracycline (30μg/mL) to select for <i>G. apicola</i>. <i>G. apicola</i> is naturally resistant to oxytetracycline<a href="#ref">(1)</a>.  
 
</p>  
 
</p>  
 
           </div>
 
           </div>
Line 259: Line 259:
 
<p>We would like to thank the following people greatly for their assistance, suggestions, and providing the plasmids/materials for us to experiment with.</p>
 
<p>We would like to thank the following people greatly for their assistance, suggestions, and providing the plasmids/materials for us to experiment with.</p>
  
<p> Walden Kwong for providing the strains of G. apicola and S. alvi. </p>
+
<p> Waldan Kwong for providing the strains of <i>G. apicola</i> and <i>S. alvi</i>. </p>
 
<p> Dr. Julian Davies for providing the RP1 plasmid.</p>
 
<p> Dr. Julian Davies for providing the RP1 plasmid.</p>
<p> Dr. John Smit and Dr. John Nomellini for providing the E.coli S17, and SM-10 strains. As well for providing the plasmids PBBR3, PBBR4, PKT210, and PRK293.</p>
+
<p> Dr. John Smit and Dr. John Nomellini for providing the <i>E.coli</i> S17, and SM-10 strains. As well for providing the plasmids PBBR3, PBBR4, PKT210, and PRK293.</p>
 
<p> Dr. Rachel Fernandez for providing the PBBRMCS1-2 plasmid.</p>
 
<p> Dr. Rachel Fernandez for providing the PBBRMCS1-2 plasmid.</p>
 
<p> Dr. J. Thomas Beatty for providing the PIND4 plasmid.</p>
 
<p> Dr. J. Thomas Beatty for providing the PIND4 plasmid.</p>

Revision as of 22:35, 18 September 2015

UBC iGEM 2015

 

Genetic Tool Development

 

The β-proteobacteria, Snodgrassella alvi, and the γ-proteobacteria, Gilliamella apicola, were chosen as candidates for our probeeotic due to their endogenous nature in relation to the midgut of the European honey bee, Apis mellifera (1). Native and unique to the honey bee gut, the introduction of imidacloprid and 6-CNA degradation genes into these candidate bacteria would minimize the chance of resistance genes spreading to other insects. Due to the limited amount of existing literature on G. apicola and S. alvi, the project focused on discovering methods to make these bacteria genetically tractable. This included culturing the bacteria on different growth media, testing methods of competence induction, and transformation techniques with a variety of plasmids.

Culturing

Due to the novelty of using G. apicola and S. alvi for the project (vs. E. coli), the first step was to identify the optimal method of culturing either bacteria.

Growth Curve

The growth of G. apicola was monitored on a plate reader that measured the OD value at 600nm over 36 hours, and plotted to a curve at fixed time points. For this, G. apicola was inoculated into a TSB culture that was previously flushed with 5% CO2 balanced with N2. Additionally, 5% CO2 balanced with N2 was blown onto the plate whilst sealing to ensure the presence of a minimal amount of oxygen in the plate.

Inducing Competence in G.apicola and S.alvi

After identifying the optimal method to culture G. apicola, we moved on to attempting various ways of inducing competence in the bacteria. Due to the lack of existing literature on methods of inserting a plasmid into G. apicola, we tried various protocols known to work on other gram-negative gammaproteobacteria, and a protocol for microaerophilic bacteria were attempted. View our protocols here, under Genetic Tool Development.

Transformation

After creating the competent cells, a variety of transformation protocols were attempted. View our protocols here, under Genetic Tool Development.

Acknowledgements

We would like to thank the following people greatly for their assistance, suggestions, and providing the plasmids/materials for us to experiment with.

Waldan Kwong for providing the strains of G. apicola and S. alvi.

Dr. Julian Davies for providing the RP1 plasmid.

Dr. John Smit and Dr. John Nomellini for providing the E.coli S17, and SM-10 strains. As well for providing the plasmids PBBR3, PBBR4, PKT210, and PRK293.

Dr. Rachel Fernandez for providing the PBBRMCS1-2 plasmid.

Dr. J. Thomas Beatty for providing the PIND4 plasmid.

Dr. Bob Hancock and Dr. Mangeet Bains for providing PBBR1MCS-3, PBBR1MCS-5, and PBSPIISK(-).

Dr. Michael Murphy and everyone in the Murphy Lab for being amazing hosts.

References

  1. Kwong, W., Engel, P., Koch, H., and Moran, N. (2014). Genomics and host specialization of honey bee and bumble bee gut symbionts. Proceedings of the National Academy of Sciences, 111, 11509-11514.
  2. Williams, P., Ketley, J., & Salmond, G. (Eds.). (1998). Bacterial Pathogenesis. London, UK: Academic Press.
  3. Nickoloff, J. A. (Ed.). (1995). Electroporation Protocol for Microorganisms. Totowa, NJ: Humana Press Inc.
  4. Van der Geize, R. et al. (2002). Molecular and functional characterization of kshA and kshB, encoding two components of 3-ketosteroid 9α-hydroxylase, a class IA monooxygenase, in Rhodococcus erythropolis strain SQ1. Molecular Microbiology, 45(4). doi:0.1046/j.1365-2958.2002.03069
  5. Koch, H. et al. (2013). Diversity and evolutionary patterns of bacterial gut associates of corbiculate bees. Molecular Ecology, 22(7). doi: 10.1111/mec.12209
  6. Cho, J. et al. (2003). The Effects of Altering Autoinducer-2 Concentration on Transfer Efficiencies of the F and RPI plasmids to the Quorum Sensing Recicpient Escherichia coli Strain AB1157. Journal of Experimental Microbiology and Immunology (JEMI), 3, pp. 8-14.
  7. Chan, V. et al. (2002). The Effect of Increasing Plasmid Size on Transformation Efficiency in Escherichia coli. Journal of Experimental Microbiology and Immunology (JEMI), 2, pp. 207-223.
  8. Rodriguez, R. L, & Denhardt, D. T. (1988). Vectors: A Survey of Molecular Cloning Vectors and Their Uses. Stoneham, MA: Butterworth Publishers.
  9. Plasmid map of pIND4 for Rhodobacter sphaeroides. (2005). Retrieved August 5, 2015.
  10. Schweizer, H. P. (2001). Vectors to express foreign genes and techniques to monitor gene expression in Pseudomonads. Curr. Opin. Biotechnol. 12:439–445.
  11. Kovach, M.E., Elzer, P.H., Steven Hill, D., Robertson, G.T., Farris, M.A., Roop, R.M., and Peterson, K.M. (1995). Four New Derivatives of the Broad-Host-Range Cloning Vector pBBR1MCS, Carrying Different Antibiotic-Resistance Cassettes. Gene, 166(1). 175-176.