Team:iHKU/biobrick
From 2008.igem.org
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<p><a href="#p17">List of Biobricks:</a></p> | <p><a href="#p17">List of Biobricks:</a></p> | ||
<p><a href="#p0">BBa_K094100</a>, <a href="#p2">BBa_K094101</a>, <a href="#p3">BBa_K094102</a>, <a href="#p4">BBa_K094103</a>, <a href="#p5">BBa_K094104</a>, <a href="#p6">BBa_K094105</a>, <a href="#p7">BBa_K094106</a>, <a href="#p8">BBa_K094110</a>, <a href="#p9">BBa_K094111</a>, <a href="#p10">BBa_K094112</a>, <a href="#p11">BBa_K094113</a>, <a href="#p12">BBa_K094120</a>, <a href="#p13">BBa_K094130</a>, <a href="#p14">BBa_K094141</a>, <a href="#p15">BBa_K094150</a>, <a href="#p16">BBa_K094151</a></p> | <p><a href="#p0">BBa_K094100</a>, <a href="#p2">BBa_K094101</a>, <a href="#p3">BBa_K094102</a>, <a href="#p4">BBa_K094103</a>, <a href="#p5">BBa_K094104</a>, <a href="#p6">BBa_K094105</a>, <a href="#p7">BBa_K094106</a>, <a href="#p8">BBa_K094110</a>, <a href="#p9">BBa_K094111</a>, <a href="#p10">BBa_K094112</a>, <a href="#p11">BBa_K094113</a>, <a href="#p12">BBa_K094120</a>, <a href="#p13">BBa_K094130</a>, <a href="#p14">BBa_K094141</a>, <a href="#p15">BBa_K094150</a>, <a href="#p16">BBa_K094151</a></p> | ||
- | <p><a href="#p18">Characterization</a></p> | + | <p><a href="#p18">Characterization of BBa_pSB2K3</a></p> |
<p> </p> | <p> </p> | ||
<p> </p> | <p> </p> | ||
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<p><u><a name="p16" id="p16"></a></u>BBa_K094151 <img width="162" height="61" src="https://static.igem.org/mediawiki/2008/4/4d/Biobrick_pic16.gif" /><br /> | <p><u><a name="p16" id="p16"></a></u>BBa_K094151 <img width="162" height="61" src="https://static.igem.org/mediawiki/2008/4/4d/Biobrick_pic16.gif" /><br /> | ||
pLacI/ara-1-rbs-luxI-terminator: The luxI operon is controlled by promoter LacI/ara-1.</p> | pLacI/ara-1-rbs-luxI-terminator: The luxI operon is controlled by promoter LacI/ara-1.</p> | ||
+ | <p align="right"><a href="#p1">[Back to top]</a></p> | ||
<p> </p> | <p> </p> | ||
<p> </p> | <p> </p> | ||
<p> </p> | <p> </p> | ||
<p> </p> | <p> </p> | ||
- | <p><h2 class="style7"><a name=" | + | <p><h2 class="style7"><a name="p18" id="p"></a>Characterization: Effect of IPTG inducement on BBa_pSB2K3 copy number</h2></p> |
- | + | <p>Plasmid pSB2K3 is a variable copy number plasmid that carries one F’ replication origin and a P1 lytic replication origin. The P1 lytic origin must be activated by proteins encoded by a gene carried by the plasmid itself. The gene, however, is controlled by a pLacI promoter and is thus inducible by IPTG. When the plasmid is inserted into cells producing lacI protein, the P1 lytic origin is non-functional and its only active origin is the F’ origin that keeps plasmid copy number at a very low level, possibly one or two (which is determined by the nature of F’ origin). When induced by IPTG, the P1 lytic origin is activated and thus may keep copy number at a very high level. <br /> | |
To find out the relationship between the concentration of inducing IPTG and the copy number of the plasmid, we performed a series of experiments.</p> | To find out the relationship between the concentration of inducing IPTG and the copy number of the plasmid, we performed a series of experiments.</p> | ||
<p>Method:<br /> | <p>Method:<br /> | ||
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<p>5. The extracted plasmid is run with 1.0% agarose gel. 1kb plus DNA ladder is used as a control of DNA amount and plasmid size. The plasmid is digested with XbaI before gel electrophoresis.</p> | <p>5. The extracted plasmid is run with 1.0% agarose gel. 1kb plus DNA ladder is used as a control of DNA amount and plasmid size. The plasmid is digested with XbaI before gel electrophoresis.</p> | ||
<p>6. Photo of the gel result is analyzed by brightness measuring software.</p> | <p>6. Photo of the gel result is analyzed by brightness measuring software.</p> | ||
- | <p | + | <p>Rationale and result interpretation:<br /> |
The experiment is repeated twice (altogether three times) to ensure the repeatability of this method. The values shown in the result chart (figure 1) are the mean values of the three experiments with error bar. Figure 2 is an enlarged part of figure 1 showing the first two data.<br /> | The experiment is repeated twice (altogether three times) to ensure the repeatability of this method. The values shown in the result chart (figure 1) are the mean values of the three experiments with error bar. Figure 2 is an enlarged part of figure 1 showing the first two data.<br /> | ||
<img src="https://static.igem.org/mediawiki/2008/f/f9/1_1.gif" alt="bbc1" width="504" height="402" /> <br /> | <img src="https://static.igem.org/mediawiki/2008/f/f9/1_1.gif" alt="bbc1" width="504" height="402" /> <br /> | ||
Figure 1</p> | Figure 1</p> | ||
- | <p | + | <p><img src="https://static.igem.org/mediawiki/2008/2/27/2.gif" alt="bbc2" width="482" height="289" /> <br /> |
Figure 2</p> | Figure 2</p> | ||
<p>Six data are shown in the chart, because for IPTG concentration larger than 100 μmol/L the effect of inducement seems to have no difference. Attached in the chart is one of the original gel photos, with C being the control. This data is got from exponentially growing culture, in which the mean copy number is generally smaller than the mean copy number of cells from stationary phase, for the simple reason that in newly divided cells there is not enough time for plasmids to replicate to the limit.<br /> | <p>Six data are shown in the chart, because for IPTG concentration larger than 100 μmol/L the effect of inducement seems to have no difference. Attached in the chart is one of the original gel photos, with C being the control. This data is got from exponentially growing culture, in which the mean copy number is generally smaller than the mean copy number of cells from stationary phase, for the simple reason that in newly divided cells there is not enough time for plasmids to replicate to the limit.<br /> | ||
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<p>The result shows that for IPTG concentration less than 20 μmol/L, the effect of inducement is scarcely perceivable. It also shows that from 20 μmol/L to 100 μmol/L the copy number is induced by IPTG in a way quite proportional to its concentration. It seems that over 100 μmol/L IPTG concentration is “saturated” and a further increase in IPTG concentration cannot raise the copy number (the data of which is not shown in the chart).<br /> | <p>The result shows that for IPTG concentration less than 20 μmol/L, the effect of inducement is scarcely perceivable. It also shows that from 20 μmol/L to 100 μmol/L the copy number is induced by IPTG in a way quite proportional to its concentration. It seems that over 100 μmol/L IPTG concentration is “saturated” and a further increase in IPTG concentration cannot raise the copy number (the data of which is not shown in the chart).<br /> | ||
Attention*: This result is from exponentially growing culture. For cell culture in stationary phase the copy number possibly increases (due to time limit, only one experiment is done with stationary phase culture and the result seems to suggest that this raise in plasmid copy number is more significant with lower IPTG concentration. Because there are no repeats, the data is not included).</p> | Attention*: This result is from exponentially growing culture. For cell culture in stationary phase the copy number possibly increases (due to time limit, only one experiment is done with stationary phase culture and the result seems to suggest that this raise in plasmid copy number is more significant with lower IPTG concentration. Because there are no repeats, the data is not included).</p> | ||
- | <p>According to the experiment, we suggest that 100 μmol/L IPTG is enough for pSB2K3 to reach its peak copy number, and if moderate copy number is needed then 40-60 μmol/L is a good choice. This result is also valuable when using pSB2K3 with other IPTG induced genetic devices.</p> | + | <p>According to the experiment, we suggest that 100 μmol/L IPTG is enough for pSB2K3 to reach its peak copy number, and if moderate copy number is needed then 40-60 μmol/L is a good choice. This result is also valuable when using pSB2K3 with other IPTG induced genetic devices.</p> |
+ | <p align="right"><a href="#p1">[Back to top]</a></p> | ||
</td> | </td> |
Latest revision as of 19:23, 29 October 2008
BiobrickCONTENTS:BBa_K094100, BBa_K094101, BBa_K094102, BBa_K094103, BBa_K094104, BBa_K094105, BBa_K094106, BBa_K094110, BBa_K094111, BBa_K094112, BBa_K094113, BBa_K094120, BBa_K094130, BBa_K094141, BBa_K094150, BBa_K094151 Characterization of BBa_pSB2K3
List of Biobricks:BBa_K094100
BBa_K094101
BBa_K094102
BBa_K094103
BBa_K094104
BBa_K094105
BBa_K094106
BBa_K094110
BBa_K094111
BBa_K094112
BBa_K094113
BBa_K094120
BBa_K094130
BBa_K094141 <
BBa_K094150
BBa_K094151
Characterization: Effect of IPTG inducement on BBa_pSB2K3 copy numberPlasmid pSB2K3 is a variable copy number plasmid that carries one F’ replication origin and a P1 lytic replication origin. The P1 lytic origin must be activated by proteins encoded by a gene carried by the plasmid itself. The gene, however, is controlled by a pLacI promoter and is thus inducible by IPTG. When the plasmid is inserted into cells producing lacI protein, the P1 lytic origin is non-functional and its only active origin is the F’ origin that keeps plasmid copy number at a very low level, possibly one or two (which is determined by the nature of F’ origin). When induced by IPTG, the P1 lytic origin is activated and thus may keep copy number at a very high level. Method: 1. Pre-culture of pSB2K3 containing cells in 2% LB medium with Kanamycin concentration of 50mg/L. (not induced with IPTG) 2. When O.D. has reached 1, begin the experimental culture with a 1:100 dilution of the pre-culture into 2% LB medium containing Kanamycin and IPTG. 10 different IPTG concentrations were selected and they are 0, 10, 20, 40, 60, 80, 100, 200, 500, 1000 (unit: μmol/L). 3. Wait until the experimental culture has reached an O.D. close to 1. Measure the O.D. and calculate the volume of sample to be collected to make it contain the same cell mass as 5ml of O.D.=1.000 culture. Then collect the 10 samples and put them on ice. 4. Centrifuge down the cells and extract plasmid using a QIAGEN extraction kit. The extraction is done with extreme carefulness and strict protocol to ensure a high recovery and high repeatability. 5. The extracted plasmid is run with 1.0% agarose gel. 1kb plus DNA ladder is used as a control of DNA amount and plasmid size. The plasmid is digested with XbaI before gel electrophoresis. 6. Photo of the gel result is analyzed by brightness measuring software. Rationale and result interpretation: Six data are shown in the chart, because for IPTG concentration larger than 100 μmol/L the effect of inducement seems to have no difference. Attached in the chart is one of the original gel photos, with C being the control. This data is got from exponentially growing culture, in which the mean copy number is generally smaller than the mean copy number of cells from stationary phase, for the simple reason that in newly divided cells there is not enough time for plasmids to replicate to the limit. The result shows that for IPTG concentration less than 20 μmol/L, the effect of inducement is scarcely perceivable. It also shows that from 20 μmol/L to 100 μmol/L the copy number is induced by IPTG in a way quite proportional to its concentration. It seems that over 100 μmol/L IPTG concentration is “saturated” and a further increase in IPTG concentration cannot raise the copy number (the data of which is not shown in the chart). According to the experiment, we suggest that 100 μmol/L IPTG is enough for pSB2K3 to reach its peak copy number, and if moderate copy number is needed then 40-60 μmol/L is a good choice. This result is also valuable when using pSB2K3 with other IPTG induced genetic devices. |