Difference between revisions of "Team:Sheffield/project/science/growthcurves"

 
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<p>INTRO</p>
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<p>Introduction & Aims</p>
 
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<p>Iron-Rich</p>
 
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<p>M9</p>
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<p>Iron-Limiting 1</p>
 
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<p>DEFINED</p>
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<p>Iron-Limiting 2</p>
 
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                         <h2>Introduction and Aims</h2>
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                         <h2>Introduction & Aims</h2>
<p>We set out to form an understanding of the growth model of both the wildtype – W3110 – and mutant – JC28 E. coli strains. The JC28 mutant has an entC knockout mutation meaning that it is unable to produce siderophores.
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<p>Our proposed reporter systems required an <i>E. coli</i> strain that allows the manipulation of intracellular iron levels via <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="Siderophores" data-content="Small organic molecules produced by some bacteria and fungi capable of binding iron with extremely high affinity, these can then be taken up by the organism where they release their bound iron.">siderophore</button> uptake. We chose to use the <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="JC28" data-content="A mutant <i>E. coli</i> strain with the genotype: W3110 <i>∆fecABCDE ∆zupT ∆mntH ∆entC ∆feoABC</i>. Deficient in siderophore production.">JC28</button> strain that has an <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="<i>entC</i>" data-content="An <i>E. coli</i> gene coding for Isochorismate synthase, a key enzyme in the siderophore synthesis pathway. Knocked out in the JC28 mutant strain."><i>entC</i></button> knockout mutation, meaning that it is unable
JC28 genotype: W3110 ∆fecABCDE ∆zupT ∆mntH ∆entC ∆feoABC
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to produce enterobactin. In order to keep intracellular iron-levels of JC28 low while the strain still grows, we needed to test a range of media and varying iron concentrations. </p>
In order to do this we cultured the wildtype and mutant strains and measured the growth of the cultures both indirectly, by measuring optical density, and directly, by counting the number of colony forming units (CFU).  
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</p>
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                        <p>We carried out growth curve experiments to determine the growth model of both the <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="W3110" data-content="A common lab strain of <i>E. coli</i> K12. Parent strain of the JC28 mutant type.">W3110</button>
<p>It was important to understand the growth rate of the two strains for a number of reasons:</p>
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(<button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="Wild Type" data-content="A strain, gene, or characteristic which prevails among individuals in natural conditions, as distinct from an atypical mutant type">Wild Type</button>) and JC28 (<button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="Mutant" data-content="A strain, gene, or characteristic that is distinct from the typical “wild type”
<ol>
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">mutant</button>) <i>E. coli</i> strains. As part of this, we cultured the wild type  and mutant strains and measured the growth of the cultures both indirectly, by measuring optical density (fig. 1), and directly, by counting the number of colony forming units (<button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="CFU" data-content="Colony Forming Units, a single viable cell forming a colony on an agar plate.
<li>When carrying out later experiments on either strain we will need to know how long to incubate the cultures for so that the growth of the colony is in the logarithmic phase.
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">CFU</button>) plated on agar plates (fig. 2).</p>
Beyond the log phase (stationary phase) the bacteria will start to lyse as the nutrients runs out and the bacteria start to starve. Before the log phase (lag phase) too few bacteria will be present and they will not be dividing at their optimum rate. Tests carried out on the bacteria in lag or stationary phases would not give representative data.</li>
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<li>The entC mutation could have had effects on the growth rate of the mutant JC28 strain. In order to assess whether the mutant had a growth defect, we needed to compare the wildtype and mutant growth curves. Knowing if the mutant had a growth defect would allow us to take this into consideration in future experiments.</li>
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                          <p>The bacteria were grown in three different growth media; Lysogeny broth (LB), M9 minimal media and EZ defined media. This was necessary because we wanted to characterise the growth of our mutant over a range of iron conditions. It was hypothesised that the mutant would grow nearly as well as the wild type  when iron is plentiful and it would not have to rely on siderophores for iron uptake, but would be significantly limited by low-iron conditions.</p>
</ol>
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                        <h2>The Different Media</h2>
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                          <p>The growth curves behaving as predicted would confirm that our mutant is impaired in iron acquisition, which is to be expected if the mutant is unable to produce siderophores.</p>
<p>The bacteria were grown in three different growth media; Lysogeny broth (LB), M9 minimal media and EZ defined media. LB is a nutritionally rich medium that allows for rapid growth of E. coli. M9 minimal media contains the minimum set of nutrients for the growth of many wildtype E. coli strains. The EZ defined media contains only a specific set of salts, amino acids, and a carbon source. The defined media allows more precise control over the amount of iron available to the cells.
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<p>It was predicted that when both strains were grown in the LB liquid media there would be very little difference in the growth curves. This result is expected due to the LB media containing a good source of iron, ensuring that iron availability is not a limiting factor to growth.
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</p>
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<p>However, it was hypothesised that in the defined media, the mutant bacteria would struggle to grow in low iron conditions and this would be reflected in a much lower growth curve. As an important element for many metabolic processes and ultimately for growth, the ability of the bacteria to scavenge and acquire iron becomes very important. The JC28 mutant does not produce siderophores – a key mechanism for iron scavenging and uptake – so their growth would be significantly inhibited when grown under iron-limited conditions.
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                                 <h2>LB liquid media</h2>
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                                 <h2>Iron-rich media (LB media)</h2>
<p>As predicted, there is only a slight difference in the growth curves of the two strains cultured in LB liquid media.</p>
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                                <p>In order to confirm the effect of iron on growth, we first grew both strains in an iron-rich liquid media (LB).</p>
<!--Image 1-->
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<p>Figure 1. The optical densities of W3110 and JC28 E. coli strains at 30 minute intervals from the time of inoculation. The cultures were incubated in a 37OC environment and were suspended in a LB liquid media. 1ml samples were taken for each strain and the optical density at 600nm was recorded. W3110 is the wildtype E. coli whilst JC28 is the mutant E. coli lacking the functional entC gene. The JC28 mutant showed some slight growth defects.
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</p>
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<!--Image 2-->
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<p>Figure 2. Bacterial count (in colony forming units) from the point of inoculation. The cultures were incubated in a 37OC environment in LB liquid media. 1ml samples were taken at 30 minute intervals and 5 serial dilutions made. Each dilution was spotted 3 times onto a LB agar plate, the average CFU of these spots were taken for each dilution.
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</p>
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<!--CAS plate pictures -->
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<p>At the same time point (T4.5) the size of the mutant JC28 colonies were significantly smaller than the wildtype W3110 colonies as shown in Image 1 and 2.
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</p>
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<img src="https://static.igem.org/mediawiki/2016/b/b8/T--Sheffield--Growth-graph4.png">
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<p><b>Figure 1. Growth curves of <i>E. coli</i> W3110 (wild type) and JC28 (mutant) in liquid LB media from OD<sub>600</sub>.</b> <i>1 ml of overnight cultures <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="W3110" data-content="A common lab strain of <i>E. coli</i> K12. Parent strain of the JC28 mutant type.">W3110</button> and <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="JC28" data-content="A mutant <i>E. coli</i> strain with the genotype: W3110 <i>∆fecABCDE ∆zupT ∆mntH ∆entC ∆feoABC</i>. Deficient in siderophore production.">JC28</button> were diluted into 50 ml of fresh LB media at an <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="OD<sub>600</sub>" data-content="The optical density of a sample, which is indicative of the concentration of cells. This is determined by measuring absorbance at 600nm using a spectrophotometer.
 +
">OD<sub>600</sub></button> of ~0.01 and incubated at 37 °C, 200 rpm. Growth kinetics were monitored taking OD<sub>600</sub> measurement in 30 minute intervals from inoculation using 1 ml samples.</i></p>
 +
 
 +
                                <img src="https://static.igem.org/mediawiki/2016/8/84/T--Sheffield--Growth-graph3.png">
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 +
<p><b>Figure 2. CFU counts of W3110 (wild type) and JC28 (mutant) grown in liquid LB media.</b> <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="CFU" data-content="Colony Forming Units, a single viable cell forming a colony on an agar plate.
 +
"><i>CFU</i></button> <i>counts were performed from the same growth curve experiment. 1 ml samples were taken at 30 min intervals and 3x10 µl dilutions from 10<sup>-1</sup> to 10<sup>-6</sup> were spotted on a LB agar plate and incubated at 37 °C overnight. The average CFU of these spots were taken for each dilution.</i></p>
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 +
<p>As predicted, only slight differences in growth between both strains were observed in liquid LB media (Fig. 1 and 2). Interestingly, at the same time point (T4.5) the size of the <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="Mutant" data-content="A strain, gene, or characteristic that is distinct from the typical “wild type”
 +
">mutant</button> Interestingly at the same time point, JC28 colonies were smaller than the <button class="btn btn-lg btn-danger" data-toggle="popover" data-placement="top" title="Wild Type" data-content="A strain, gene, or characteristic which prevails among individuals in natural conditions, as distinct from an atypical mutant type">Wild Type</button>  W3110 colonies (Fig. 3). </p>
 +
                                <img src="https://static.igem.org/mediawiki/2016/d/dd/T--Sheffield--Growth-colony-size.png">
 +
<p><b>Figure 3. Comparison of wild type and mutant colony sizes from T4.5 on LB agar plates after being incubated overnight at 37 °C.</b></p>
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                                         <h2>M9 media</h2>
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                                         <h2>Iron-limiting media 1 (M9 media)</h2>
<p>We measured the growth of W3110 and JC28 in M9 minimal media with a range of added iron concentrations. It was hypothesised that JC28 would grow at a similar rate to W3110 in the high-iron media, but be unable to grow as rapidly in low-iron media.  
+
<p>We measured the growth of <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="W3110" data-content="A common lab strain of <i>E. coli</i> K12. Parent strain of the JC28 mutant type.">W3110</button> (<button class="btn btn-lg btn-danger" data-toggle="popover" title="Wild Type" data-placement="top" data-content="A strain, gene, or characteristic which prevails among individuals in natural conditions, as distinct from an atypical mutant type">Wild Type</button> ) and <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="JC28" data-content="A mutant <i>E. coli</i> strain with the genotype: W3110 <i>∆fecABCDE ∆zupT ∆mntH ∆entC ∆feoABC</i>. Deficient in siderophore production.">JC28</button> (<button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="Mutant" data-content="A strain, gene, or characteristic that is distinct from the typical “wild type”
 +
">mutant</button>) in M9 minimal media with a range of added iron concentrations. It was hypothesised that JC28 would grow at a similar rate to W3110 in the high-iron media, but be unable to grow as rapidly in low-iron media.  
 
</p>
 
</p>
<p>While W3110 was able to grow, no significant growth of JC28 was observed after 5 hours at any of the tested iron concentrations. This experiment showed that M9 media was missing some nutrients that JC28 requires, leading us to investigate a richer defined medium where we could still control the level of iron.  
+
<img src="https://static.igem.org/mediawiki/2016/2/26/T--Sheffield--Growth-graph5.png">
 +
                                        <p><b>Figure 4. Growth curves of <i>E. coli</i> W3110 wild type and JC28 (mutant) in liquid M9 minimal media from OD<sub>600</sub>.</b> <i>1 ml from an overnight culture of W3110 and JC28 was diluted into 50 ml of fresh M9 minimal media at an <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="OD<sub>600</sub>" data-content="The optical density of a sample, which is indicative of the concentration of cells. This is determined by measuring absorbance at 600nm using a spectrophotometer.
 +
">OD<sub>600</sub></button> of around 0.01 and incubated at 37 °C and 200 rpm. Growth kinetics were monitored taking the OD<sub>600</sub> measurement in 30 or 60 minute intervals from inoculation using 1 ml samples.</i>
 
</p>
 
</p>
<!-- graph -->
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                                        <p>No growth of W3110 or JC28 was observed after 5 hours at any of the tested iron concentrations. This experiment showed that M9 media was missing some nutrients that our strains require, leading us to investigate a richer defined medium where we could still control the level of iron. </p>
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                                 <h2>Defined media</h2>
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                                 <h2>Iron-limiting media 2 (defined media)</h2>
<!--graph -->
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<p>The growth curves in defined media show that wildtype W3110 is not significantly affected by the varying iron concentrations we tested. However, JC28 demonstrated significantly reduced growth when grown under iron-limited conditions. This shows that JC28 is deficient in iron uptake.
+
<p>We investigated the growth of <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="W3110" data-content="A common lab strain of <i>E. coli</i> K12. Parent strain of the JC28 mutant type.">W3110</button> (<button class="btn btn-lg btn-danger" data-toggle="popover" data-placement="top" title="Wild Type" data-content="A strain, gene, or characteristic which prevails among individuals in natural conditions, as distinct from an atypical mutant type">Wild Type</button> ) and <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="JC28" data-content="A mutant <i>E. coli</i> strain with the genotype: W3110 <i>∆fecABCDE ∆zupT ∆mntH ∆entC ∆feoABC</i>. Deficient in siderophore production.">JC28</button> (<button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="Mutant" data-content="A strain, gene, or characteristic that is distinct from the typical “wild type”
</p>
+
">mutant</button>) in EZ defined media with two added iron concentrations, 0 µM and 20 µM. It was predicted that JC28 would grow at a similar rate to W3110 in the high-iron media, but be unable to grow as rapidly in low-iron media.
 +
                               
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                                <p><b>Figure 5. Growth curves of <i>E. coli</i> W3110 (wild type) and JC28 (mutant) in liquid defined media from OD<sub>600</sub>, with either added iron (III) chloride to 20 µM or without.</b> <i>1 ml from overnight cultures of W3110 and JC28 was diluted into 50 ml of fresh defined media, either with or without iron (III) chloride added to 20 µM, at an <button class="btn btn-lg btn-danger" data-placement="top" data-toggle="popover" title="OD<sub>600</sub>" data-content="The optical density of a sample, which is indicative of the concentration of cells. This is determined by measuring absorbance at 600nm using a spectrophotometer.
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                                <p>The growth curves in defined media (Fig. 5) show that W3110 (wild type ) is not affected by the varying iron concentrations we tested. However, JC28 (mutant) demonstrated reduced growth when grown under iron-limited conditions. This shows that JC28 is impaired in its ability to uptake iron.</p>
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Latest revision as of 09:54, 19 October 2016

A template page

GROWTH CURVES

Introduction & Aims

Our proposed reporter systems required an E. coli strain that allows the manipulation of intracellular iron levels via uptake. We chose to use the strain that has an knockout mutation, meaning that it is unable to produce enterobactin. In order to keep intracellular iron-levels of JC28 low while the strain still grows, we needed to test a range of media and varying iron concentrations.

We carried out growth curve experiments to determine the growth model of both the () and JC28 () E. coli strains. As part of this, we cultured the wild type and mutant strains and measured the growth of the cultures both indirectly, by measuring optical density (fig. 1), and directly, by counting the number of colony forming units () plated on agar plates (fig. 2).

The bacteria were grown in three different growth media; Lysogeny broth (LB), M9 minimal media and EZ defined media. This was necessary because we wanted to characterise the growth of our mutant over a range of iron conditions. It was hypothesised that the mutant would grow nearly as well as the wild type when iron is plentiful and it would not have to rely on siderophores for iron uptake, but would be significantly limited by low-iron conditions.

The growth curves behaving as predicted would confirm that our mutant is impaired in iron acquisition, which is to be expected if the mutant is unable to produce siderophores.

Iron-rich media (LB media)

In order to confirm the effect of iron on growth, we first grew both strains in an iron-rich liquid media (LB).

Figure 1. Growth curves of E. coli W3110 (wild type) and JC28 (mutant) in liquid LB media from OD600. 1 ml of overnight cultures and were diluted into 50 ml of fresh LB media at an of ~0.01 and incubated at 37 °C, 200 rpm. Growth kinetics were monitored taking OD600 measurement in 30 minute intervals from inoculation using 1 ml samples.

Figure 2. CFU counts of W3110 (wild type) and JC28 (mutant) grown in liquid LB media. counts were performed from the same growth curve experiment. 1 ml samples were taken at 30 min intervals and 3x10 µl dilutions from 10-1 to 10-6 were spotted on a LB agar plate and incubated at 37 °C overnight. The average CFU of these spots were taken for each dilution.

As predicted, only slight differences in growth between both strains were observed in liquid LB media (Fig. 1 and 2). Interestingly, at the same time point (T4.5) the size of the Interestingly at the same time point, JC28 colonies were smaller than the W3110 colonies (Fig. 3).

Figure 3. Comparison of wild type and mutant colony sizes from T4.5 on LB agar plates after being incubated overnight at 37 °C.

Iron-limiting media 1 (M9 media)

We measured the growth of ( ) and () in M9 minimal media with a range of added iron concentrations. It was hypothesised that JC28 would grow at a similar rate to W3110 in the high-iron media, but be unable to grow as rapidly in low-iron media.

Figure 4. Growth curves of E. coli W3110 wild type and JC28 (mutant) in liquid M9 minimal media from OD600. 1 ml from an overnight culture of W3110 and JC28 was diluted into 50 ml of fresh M9 minimal media at an of around 0.01 and incubated at 37 °C and 200 rpm. Growth kinetics were monitored taking the OD600 measurement in 30 or 60 minute intervals from inoculation using 1 ml samples.

No growth of W3110 or JC28 was observed after 5 hours at any of the tested iron concentrations. This experiment showed that M9 media was missing some nutrients that our strains require, leading us to investigate a richer defined medium where we could still control the level of iron.

Iron-limiting media 2 (defined media)

We investigated the growth of ( ) and () in EZ defined media with two added iron concentrations, 0 µM and 20 µM. It was predicted that JC28 would grow at a similar rate to W3110 in the high-iron media, but be unable to grow as rapidly in low-iron media.

Figure 5. Growth curves of E. coli W3110 (wild type) and JC28 (mutant) in liquid defined media from OD600, with either added iron (III) chloride to 20 µM or without. 1 ml from overnight cultures of W3110 and JC28 was diluted into 50 ml of fresh defined media, either with or without iron (III) chloride added to 20 µM, at an of around 0.01 and incubated at 37 °C and 200 rpm. Growth kinetics were monitored taking OD600 measurement in 30 or 60 minute intervals from the time of inoculation using 1 ml samples.

The growth curves in defined media (Fig. 5) show that W3110 (wild type ) is not affected by the varying iron concentrations we tested. However, JC28 (mutant) demonstrated reduced growth when grown under iron-limited conditions. This shows that JC28 is impaired in its ability to uptake iron.