Team:HKUST-Hong Kong/characterization.html

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BioBricks Master List and Characterization Data

1. BBa_K524000 –oriR101 & repA101-ts: This heat sensitive origin of replication has been shown to be functional at 30°C. Partial loss of plasmid happens at 33°C, and complete loss of plasmid is observed at 37°C.

2. BBa_K524001 –pLac + RBS + sfGFP1-10: This contains coding DNA sequences for superfolder GFP amino residues 1-214 driven by RBS BBa_B0034 and pLac BBa_R0010.

3. BBa_K524002 –pLac + RBS + sfGFP11 + double terminator: This contains coding DNA sequences for superfolder GFP amino residues 215-238 driven by RBS BBa_B0034 and pLac BBa_R0010, with double terminator B0015 at the end.

4. BBa_K524003 – nadE gene + double terminator: an essential gene that encodes constitutively- expressed NAD+ synthetase.

5. BBa_K524004 –pir gene: the pir gene encodes the autogenously regulated pi protein.

6. BBa_K524005 – pToolkit: A plasmid that is only maintained in strains with pir+ genotype. The plasmid was modified from the plasmid pKD46, which has been shown to trigger DNA recombination and subsequent gene knockout under induction of arabinose.

7. BBa_K524006 –RBS + sfGFP1-10: This contains coding DNA sequences for superfolder GFP amino residues 1-214 driven by RBS BBa_B0034.

8. BBa_K524007 –RBS + sfGFP11 + double terminator: This contains coding DNA sequences for superfolder GFP amino residues 215-238 driven by RBS BBa_B0034, with double terminator B0015 at the end.

9. BBa_K524100 – bcr CDS + double terminator B0015: The gene product is responsible for multidrug efflux system that pumps out antibiotics. Effect of pump was documented by other researchers: it confers varying degrees of resistance to 5 different antibiotics.

Characterization Data for BBa_K524000

Heat Sensitive Origin of Replication (oriR101 & repA101-ts)

Abstract

oriR101 & repA101-ts constitute a low copy origin of replication derived from the pSC101 replication origin. Initiation of replication at oriR101 is regulated in trans by the heat-labile protein product of repA101-ts, which loses activity significantly at 37°C. Hence when bacteria harboring plasmids with this origin are incubated at 37°C, the activity of this origin would decrease. Temperatures higher than 42°C would cause the construct to cease its functions completely. (Phillips GJ, 1995).

In the process of its fabrication, a point mutation was introduced (base substitute of C to G at nucleotide residue 1391) so as to make the construct compatible with Biobrick standard assembly requirements. Nevertheless, our characterization results do not seem to suggest great impacts to the construct's functions, causing only a slight increase in its thermosensitivity.

Construction of This Part

This construct was cloned out from the pKD46 plasmid harboured in the E. coli strain BW25113 (courtesy of The Coli Genetic Stock Center). A single nucleotide mutation, performed through overlapping PCR, was introduced to eliminate a SpeI cut site originally present inside the construct, specifically between the promoter and CDS of the ori101R & repA101-ts. The mutation has been successfully confirmed by restriction digestion (Figure 1) and nucleotide sequencing.

#Figure 1: Digestion with SpeI for Confirmation of Successful Mutation

Characterization

Construct Preparation for Heat Sensitivity Test

Characterization of the oriR101 & repA101-ts was done with the insert ligated to RFP reporter and harbored in partregistry.org's standard assembly pSB1AK3 plasmid. The enzymes PstI and SmaI were then used to cut out the normal replication origin (pMB1) of pSB1AK3 and part of its KanR gene. After the blunt end treatment, the linearized plasmid was self-ligated and transformed into E. coli DH10b. Restriction digestion test, along with the presence of red fluorescence and absence of Kanamycin resistance, is used for plasmid verification. The final construct used for thermosensitivity test is referred to as “ori-ts” for convenience.

Characterization Methods

Qualitative Test

To test the thermosensitivity of the origin, we employed the plasmid-loss assay. When the cells were incubated in non-permissive temperatures (i.e. temperatures above 37°C), the plasmid containing the antibiotic-resistance gene will be lost and no growth of cells harboring ori-ts will be seen on the antibiotic-containing plates (here we used ampicillin with working concentrations of 150μg/ml); while cells that contain a plasmid with the corresponding antibiotic-resistance gene and a normal replication origin will survive and proliferate.

In our tests, serial dilution was performed on overnight cultures of ori-ts(+) cells. Dilutions were performed to give the following bacterial concentrations: 1 cell/7μl, 10 cells/7μl, 100 cells/7μl, and 1000 cells/7μl. 7μl of the abovementioned solutions were applied on LB and LB(Amp) plates. The plates were then incubated at 30°C, 33°C, 37°C, and 42°C. LB plates were prepared as a control to reflect the actual titration of E.coli in each dilution.

Quantitative Test

To quantitatively determine the elimination rate of plasmids bearing our oriR101 & repA101-ts, (approximated) equal numbers of ori-ts-harboring bacterial cells were spread on LB plates (labeled as LB_ori-ts) and LB (Amp) plates (labeled as Amp_ori-ts). Four replicas of this experimental setup were prepared for overnight incubations at four different temperatures: 30°C, 33°C, 37°C, and 42°C. Then, colonies formed on the plates after overnight incubation were quantified. For each set, the ratios of colonies on Amp_ori-ts plates vs. LB_ori-ts plates were calculated. The same protocol described above was applied to the same E. coli strain (DH10b) containing only the plasmids pKD46 and pBlueScriptKS+ to serve as controls.

The total plasmid elimination rate with the thermosensitive replication origins (both the mutated version in pSB1AK3 and original version in pKD46) is computed by the following formula:

Characterization Results

Qualitative Test

Several sets of serial dilution tests were done at 30°C, 33°C, 37°C and 42°C. The evidence and results are shown below.

#Figure 2: Qualitative Description of the Temperature Sensitivity Test data.

For each temperature point in the gradient, the most concentrated O/N culture was applied on the leftmost-side, and serially diluted by 10-fold towards the rightward direction.

A robust growth of ori-ts(+) cells was observed when the cells were incubated at 30°C. This robustness (indicated by the density of bacterial colonies in each droplet, and associated with the proper functioning of the plasmid's heat sensitive origin) steadily declined as the incubation temperature was increased. Partial replication origin dysfunction was observed after 33°C incubation, and near-complete loss of function was observed at 37°C. Comparing this trend with the tested result of the original oriR101 & repA101-ts in pKD46 (partial loss of function observed at 37°C, and near-complete loss of function at 42°C), the mutated one shows higher thermosensitivity.

Quantitative test

The result of the quantitative thermosensitive test and trend of the % elimination of ori-ts is shown by the following graph:

#Figure 3: Quantitative Analysis of the temperature sensitivity origin.

Conclusion

This pKD46-derived oriR101 & repA101-ts displays intensified thermosensitive properties, which might be due to the point mutation introduced during the fabrication of the construct. The optimal incubation temperature for plasmid maintenance purposes is 30°C, whereas our recommended temperature for plasmid loss induction is 37°C or above.

References

Datsenko KA, Wanner BL.(2000).One-step inactivation of chromosomal genes in Escherichia coli K-12 using PCR products, Proc Natl Acad Sci U S A. 2000 Jun 6;97(12):6640-5.
D. Manen, L. Caro.(1991).The replication of plasmid pSC101, Mol Microbiol. 1991 Feb;5(2):233-7.
Phillips GJ.(1995). New Cloning Vectors with Temperature-Sensitive Replication, Plasmid. 1999 Jan;41(1):78-81.

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+<p align="left"><font face="Verdana, Arial, Helvetica, sans-serif" size="6" color="white">
-<p align="center"><font face="Verdana, Arial, Helvetica, sans-serif" size="7" color="white" line-height="15px"><br>BioBricks Master List<br><br>&<br><br>Characterization Data </font></p>
+<br>
+BioBricks Master List and Characterization Data
+</font></p>
-<br><br>
+<br>
 </td></tr></table>
 <br>
@@ Line 61: / Line 60: @@
 <blockquote>
-. <a href=http://partsregistry.org/Part:BBa_K524000><font color=blue>BBa_K524000</font></a> –oriR101 & repA101-ts: This heat sensitive origin of replication origin has been shown to be function at 30°C Partial loss of plasmid happens at 33°C, and complete loss of plasmid is observed at 37°C.<br><br>
+. <a href=http://partsregistry.org/Part:BBa_K524000><font color=blue>BBa_K524000</font></a> –oriR101 & repA101-ts: This heat sensitive origin of replication has been shown to be functional at 30°C. Partial loss of plasmid happens at 33°C, and complete loss of plasmid is observed at 37°C.<br><br>
 <img src="https://static.igem.org/mediawiki/2011/b/b2/Ust_BBa_K524000.png" width="700px">
 <br >
@@ Line 73: / Line 72: @@
 <br >
-. <a href=http://partsregistry.org/Part:BBa_K524003><font color=blue>BBa_K524003</font></a> – nadE gene + double terminator: an essential gene that encodes constitutive expressed NAD+ synthatase.<br><br>
+. <a href=http://partsregistry.org/Part:BBa_K524003><font color=blue>BBa_K524003</font></a> – nadE gene + double terminator: an essential gene that encodes constitutively- expressed NAD+ synthetase.<br><br>
 <img src="https://static.igem.org/mediawiki/2011/2/2a/Ust_BBa_K524003.png" width="700px">
 <br >
@@ Line 81: / Line 80: @@
 <br >
-. <a href=http://partsregistry.org/Part:BBa_K524005><font color=blue>BBa_K524005</font></a> – pToolkit: A plasmid that is only maintained in strains with genotype pir+. The plasmid was modified from another plasmid pKD46, which has been shown to trigger DNA recombination and subsequent gene knockout under induction of arabinose.<br><br>
+. <a href=http://partsregistry.org/Part:BBa_K524005><font color=blue>BBa_K524005</font></a> – pToolkit: A plasmid that is only maintained in strains with pir+ genotype. The plasmid was modified from the plasmid pKD46, which has been shown to trigger DNA recombination and subsequent gene knockout under induction of arabinose.<br><br>
 <img src="https://static.igem.org/mediawiki/2011/2/2b/Ust_BBa_K524005.png" width="700px">
 <br />
@@ Line 95: / Line 94: @@
-. <a href=http://partsregistry.org/Part:BBa_K524100><font color=blue>BBa_K524100</font></a> – bcr CDS + double terminator B0015: The gene product is responsible for multidrug efflux system that pumps out antibiotics. Effect of pump was documented by other researchers: it confers varying degrees of resistance to 5 antibiotics.<br><br>
+. <a href=http://partsregistry.org/Part:BBa_K524100><font color=blue>BBa_K524100</font></a> – bcr CDS + double terminator B0015: The gene product is responsible for multidrug efflux system that pumps out antibiotics. Effect of pump was documented by other researchers: it confers varying degrees of resistance to 5 different antibiotics.<br><br>
 <img src="https://static.igem.org/mediawiki/2011/5/5d/Ust_BBa_K524100.png" width="700px">
 <br >
@@ Line 101: / Line 100: @@
 </blockquote>
-<hr>
+<hr >
 <p><font size=3><b><u>Characterization Data for BBa_K524000</u></b></font>  </p>
-<p align="left"><strong>Heat sensitive origin of  replication (oriR101 &amp; repA101-ts) </strong></p>
+<p align="left"><strong>Heat Sensitive Origin of  Replication (oriR101 &amp; repA101-ts) </strong></p>
-<p align="left"><u>Abstract</u></p>
+<p align="left"><u><strong>Abstract</strong></u></p>
-<p>oriR101  and repA101ts constitute a low copy origin of replication derived from the  pSC101 replication origin. Initiation of replication at oriR101 is regulated in  trans by the heat- labile protein product of the repA101ts, which denatures at  37°C. Due to this property, bacterial (hence plasmid) exposure to incubation  temperature of 37°C would decrease the activity of this origin, while  temperatures higher than 42°C would cause the construct to completely cease  functioning. (Datsenko, K.A.  and Wanner, B.L. 2000).<br>
+<p>oriR101 & repA101-ts constitute a low copy origin of replication derived from the pSC101 replication origin. Initiation of replication at oriR101 is regulated in <i>trans</i> by the heat-labile protein product of repA101-ts, which loses activity significantly at 37°C. Hence when bacteria harboring plasmids with this origin are incubated at 37°C, the activity of this origin would decrease. Temperatures higher than 42°C would cause the construct to cease its functions completely. (Phillips GJ, 1995).<br>
    <br>
-   In its fabrication  process, a point mutation was introduced to construct so as to make it compatible  with Biobrick standard assembly requirements. Nevertheless, characterization  results show that this mutation does not greatly impact its properties, causing  only a slight increase in its thermosensitivity. </p>
+   In the process of its fabrication, a point mutation was introduced (base substitute of C to G at nucleotide residue 1391) so as to make the construct compatible with Biobrick standard assembly requirements. Nevertheless, our characterization results do not seem to suggest great impacts to the construct's functions, causing only a slight increase in its thermosensitivity.
-<p align="left"><u>Construction of this part</u><br>
+ </p>
-  This construct  was cloned out from the pKD46 plasmid harboured in the E. coli strain BW25113  (courtesy of The Coli Genetic Stock Center). The function of its thermo-  sensitive replication origin was first mentioned by Datsenko, K.A. and Wanner,  B.L. (2000)<br>
+<p align="left"><u><strong>Construction of This Part</strong></u><br></p>
-  A single nucleotide mutation, performed through  overlapping PCR, was introduced to eliminate a SpeI cutting site originally  present inside the construct between the promoter and CDS of RepA-ts protein. The  mutation has been successfully confirmed by restriction digestion test (Figure  1) and nucleotide sequencing.</p>
-<p align="left"><strong>#Figure 1:  Digestion with SpeI for confirmation of mutation success</strong><br>
+<p>This construct was cloned out from the pKD46 plasmid harboured in the <i>E. coli</i> strain BW25113 (courtesy of The Coli Genetic Stock Center).
+A single nucleotide mutation, performed through overlapping PCR, was introduced to eliminate a SpeI cut site originally present inside the construct, specifically between the promoter and CDS of the ori101R & repA101-ts. The mutation has been successfully confirmed by restriction digestion (Figure 1) and nucleotide sequencing.</p> <br>
+<p align="left"><strong>#Figure 1:  Digestion with SpeI for Confirmation of Successful Mutation</strong><br>
    <img src="https://static.igem.org/mediawiki/2011/9/9d/Ust_Gel_photo_chara_oriR101.jpg" alt="" width="554" height="144"><strong> </strong></p>
-<p align="left"><u>Characterization</u></p>
+<p align="left"><u><strong>Characterization</strong></u></p>
 <ul>
-   <li>Construct preparation for heat sensitivity  test</li>
+   <b><li>Construct Preparation for Heat Sensitivity  Test</li></b>
+</ul>
+<p align="left">Characterization of the oriR101 & repA101-ts was done with the insert ligated to RFP reporter and harbored in partregistry.org's standard assembly pSB1AK3 plasmid. The enzymes PstI and SmaI were then used to cut out the normal replication origin (pMB1) of pSB1AK3 and part of its KanR gene. After the blunt end treatment, the linearized plasmid was self-ligated and transformed into <em>E. coli</em> DH10b. Restriction digestion test, along with the presence of red fluorescence and absence of Kanamycin resistance, is used for plasmid verification. The final construct used for thermosensitivity test is referred to as “<i>ori-ts</i>” for convenience.</p>
+<ul>
+  <b><li>Characterization Methods</li></b>
 </ul>
-<p align="left">Characterization  of the oriR101&amp;repA101-ts was done with the insert ligated to RFP reporter  and harbored in partregistry&rsquo;s standard assembly pSB1AK3 plasmid. The enzymes  Pst1 and Sma1 were then used to cut out the normal replication origin (pMB1) of  pSB1AK3 and part of its KanR gene. The linearized plasmid was then allowed to  self- ligate and transformed to DH10b <em>E.  coli</em> strain. Restriction digestion test, along with the presence of red  fluorescence and absence of Kanamycin resistance, is used as an indicator for  plasmid verification. The final construct used for thermosensitivity test is referred  to as &ldquo;ori-ts&rdquo; for convenience.</p>
 <ul>
-  <li>Characterization method</li>
    <ul>
-     <li>Qualitative test</li>
+     <b><li>Qualitative Test</li></b>
    </ul>
 </ul>
-<p align="left">For construct  thermosensitivity test, serial dilution was performed to well- grown overnight  culture of ori- ts- positive cells. Dilutions done were aimed to give the  following bacterial concentrations: ~1 bacterium/7μl, ~10 bacteria/7μl, ~100 bacteria/7μl, ~1000 bacteria/7μl, etc. A droplet 7μl in volume from each dilution dose in the  series was applied on Amp plate and incubated at certain incubations  temperatures (30°C, 33°C, 37°C and 42°C). To give us an idea about the accuracy  of dilutions performed, the above protocol was repeated with LB- only plates  instead of LB+Amp plates.<br>
+<p align="left">  To test the thermosensitivity of the origin, we employed the plasmid-loss assay. When the cells were incubated in non-permissive temperatures (i.e. temperatures above 37°C), the plasmid containing the antibiotic-resistance gene will be lost and no growth of cells harboring <i>ori-ts</i> will be seen on the antibiotic-containing plates (here we used ampicillin with working concentrations of 150μg/ml); while cells that contain a plasmid with the corresponding antibiotic-resistance gene and a normal replication origin will survive and proliferate.
-   Quantitative test<br>
+<br /><br>
-   To  quantitatively determine the elimination rate of plasmids bearing  oriR101&amp;repA101-ts, theoretically equal numbers of ori-ts- harboring  bacterial cells were spread on another set of LB+Amp (labeled as Amp_ori-ts) and  LB- only plates (labeled as LB_ori-ts). Then, single colonies formed on the  plates after overnight incubation were quantified. Ratio of colony count on Amp_ori-ts  plate to that on LB_ori-ts was then calculated. The same protocol was applied  to the same E.coli strain (DH10B) containing the plasmids pKD46 and pBlueScript  as controls.<br>
+In our tests, serial dilution was performed on overnight cultures of <i>ori-ts</i>(+) cells. Dilutions were performed to give the following bacterial concentrations: 1 cell/7μl, 10 cells/7μl, 100 cells/7μl, and 1000 cells/7μl. 7μl of the abovementioned solutions were applied on LB and LB(Amp) plates. The plates were then incubated at 30°C, 33°C, 37°C, and 42°C. LB plates were prepared as a control to reflect the actual titration of <em>E.coli</em> in each dilution.</p>
-   The total elimination  rate of plasmid with thermosensitive replication origins (both mutated version  in pSB1AK3 and unmutated version in pKD46) is computed by the following  formula:<br>
+<br>
-   <img src="https://static.igem.org/mediawiki/2011/0/0e/Ust_OriR101_equation.jpg" alt="" width="554"></p>
+   <ul>
+  <ul>
+    <b><li>Quantitative Test</li></b>
+   </ul>
+</ul>
+<p align="left">To quantitatively determine the elimination rate of plasmids bearing our oriR101 & repA101-ts, (approximated) equal numbers of <i>ori-ts</i>-harboring bacterial cells were spread on LB plates (labeled as LB_ori-ts) and LB (Amp) plates (labeled as Amp_ori-ts). Four replicas of this experimental setup were prepared for overnight incubations at four different temperatures: 30°C, 33°C, 37°C, and 42°C. Then, colonies formed on the plates after overnight incubation were quantified. For each set, the ratios of colonies on Amp_ori-ts plates vs. LB_ori-ts plates were calculated. The same protocol described above was applied to the same <i>E. coli</i> strain (DH10b) containing only the plasmids pKD46 and pBlueScriptKS+ to serve as controls.
+  <br><br>
+   The total plasmid elimination rate with the thermosensitive replication origins (both the mutated version in pSB1AK3 and original version in pKD46) is computed by the following  formula:<br></p>
+   <center><img src="https://static.igem.org/mediawiki/2011/0/0e/Ust_OriR101_equation.jpg" alt="" width="554"></center></p>
+<ul>
+  <b><li>Characterization Results</li></b>
+</ul>
 <ul>
-  <li>Characterization result</li>
    <ul>
-     <li>Qualitative test</li>
+     <b><li>Qualitative Test</li></b>
    </ul>
 </ul>
-<p align="left">Several sets of  serial dilution tests are done at 30°C, 33°C, 37°C and 42°C. The image proof  and the result summary are shown below.<br>
+<p align="left">Several sets of  serial dilution tests were done at 30°C, 33°C, 37°C and 42°C. The evidence and results are shown below.<br>
-   <strong>#Figure 2: Qualitative Description of the temperature sensitivity test data.</strong> </p>
+  <br>
+   <strong>#Figure 2: Qualitative Description of the Temperature Sensitivity Test data.</strong> </p>
 <img src="https://static.igem.org/mediawiki/2011/c/c2/Ust_Ori-ts_testing_patch_plates.jpg" width="900px" align="middle">
-<p align="left">A robust growth  of ori-ts- positive cells was observed when the cells were incubated at 30°C.  This robustness - indicated by the density of bacterial colonies in each  droplet- covered region and associated with proper functioning of plasmid&rsquo;s  heat sensitive origin - steadily declined as the incubation temperature was  increased. Partial replication origin dysfunction was observed after 33°C  incubation and near- complete loss of function was observed at 37°C. Comparing  this trend with the testing result of the unmutated oriR101&amp;repA101-ts in  pKD46 (partial loss of function observed at 37°C, and near- complete function at  42°C), the mutated one shows higher thermosensitivity.</p>
+<p align="left"><i>For each temperature point in the gradient, the most concentrated O/N culture was applied on the leftmost-side, and serially diluted by 10-fold towards the rightward direction.</i></p>
+<p align="left">A robust growth of <i>ori-ts</i>(+) cells was observed when the cells were incubated at 30°C. This robustness (indicated by the density of bacterial colonies in each droplet, and associated with the proper functioning of the plasmid's heat sensitive origin) steadily declined as the incubation temperature was increased. Partial replication origin dysfunction was observed after 33°C incubation, and near-complete loss of function was observed at 37°C. Comparing this trend with the tested result of the original oriR101 & repA101-ts in pKD46 (partial loss of function observed at 37°C, and near-complete loss of function at 42°C), the mutated one shows higher thermosensitivity.</p>
+<br>
 <ul>
    <ul>
-     <li>Quantitative test</li>
+     <b><li>Quantitative test</li></b>
    </ul>
 </ul>
-<p align="left">The primary  result of the quantitative thermosensitive test and trend of the elimination  rate of ori-ts is shown by the following graph</p>
+<p align="left">The result of the quantitative thermosensitive test and trend of the % elimination of <i>ori-ts</i> is shown by the following graph:</p>
-<p align="left"><u>Conclusion</u><br>
+<p align="left"><strong>#Figure 3: Quantitative Analysis of the temperature sensitivity origin.</strong></p><center>
-   This pKD46-  derived oriR101&amp;repA101-ts displays obvious thermosensitive properties,  which have seemed to intensified due to the point mutation introduced during  the fabrication of the construct. The optimal incubation temperature for  plasmid maintenance purpose is 30°C, whereas the recommended temperature for  plasmid loss induction is 37°C or above. </p>
+<img src="https://static.igem.org/mediawiki/2011/9/92/Ust_Ori-ts_analysis.jpg" width="800px"></center>
+<p align="left"><u><strong>Conclusion</strong></u><br>
+ <br />
+   This pKD46-derived oriR101 & repA101-ts displays intensified thermosensitive properties, which might be due to the point mutation introduced during the fabrication of the construct. The optimal incubation temperature for  plasmid maintenance purposes is 30°C, whereas our recommended temperature for  plasmid loss induction is 37°C or above. </p>
 <p><br>
    <br>
-</p></td></tr></table>
+</p>
+<br>
+<p><b><u>References</u></b></p>
+<p>
+Datsenko KA, Wanner BL.(2000).One-step inactivation of chromosomal genes in <i>Escherichia coli</i> K-12 using PCR products, Proc Natl Acad Sci U S A. 2000 Jun 6;97(12):6640-5.
+<br />
+D. Manen, L. Caro.(1991).The replication of plasmid pSC101, Mol Microbiol. 1991 Feb;5(2):233-7.
+<br />
+Phillips GJ.(1995). New Cloning Vectors with Temperature-Sensitive Replication, Plasmid. 1999 Jan;41(1):78-81.
+</p>
+<br>
+</TD>
+   </TR>
+</table>
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-<p align="center"><b><font face="Verdana, Arial, Helvetica, sans-serif" size="2" color="#FFE1E1">
+<p align="center">
-<a href="https://2011.igem.org/Team:HKUST-Hong_Kong" target=_top><font face="Verdana, Arial, Helvetica, sans-serif" size="4" color="#FFE1E1" font color=white><span style="font-weight:700">Home</span></font></a></font></b></p>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong" target=_top>
+<b><font color="#FFE1E1" size=3>Home</font></b>
 </p>
 </td>
-<td width="332px" bgcolor="#CCFF99" valign="baseline">
+<td width="382px" bgcolor="#CCFF99" valign="baseline">
-<p align="center" valign="baseline"><b> <font face="Verdana, Arial, Helvetica, sans-serif" size="3" color="green">
+<p align="center" valign="baseline">
+<b><font color="green">Our Project</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/overview.html" target=_top>Overview</a><font color="green"> | </font>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/data.html" target=_top>Data Page</a><br></p>
+<p align="center" valign="baseline">
+<b><font color="green">Experiments and Results</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/asm.html"  target=_top>Strain Construction</a><font color="green"> | </font>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/mic.html"  target=_top>Culture Tests</a><font color="green"> | </font>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/modeling.html"  target=_top>Modeling</a><br></p>
+<p align="center" valign="baseline">
+<b><font color="green">Miscellaneous</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/notebook.html" target=_top>Notebook</a></p>
-Our Project</font></b></p>
-<p align="left"><font size="2" face="Verdana, Arial, Helvetica, sans-serif" color="green">
-<a href="team.html" target=_top><font color=green>
-<a href="overview.html" target=_top>Overview</a> |
-<a href="data.html" target=_top>Data Page</a><br>
-<span style="line-height:1; font-weight:600">Experiments and Results</span><br>
-<a href="asm.html"  target=_top>Strain Construction</a> |
-<a href="mic.html"  target=_top>Culture Tests</a> |
-<a href="modeling.html"  target=_top>Modeling</a><br>
-<span style="line-height:1; font-weight:600">Miscellaneous</span><br>
-<a href="notebook.html" target=_top>Notebook</a>
-</font></a><br></font></p>
 </td>
-<td width="332px" bgcolor="#D09C00" valign="baseline">
-<p align="left"><b><font face="Verdana, Arial, Helvetica, sans-serif" size="3" color="#FFF4D0">
-iGEM Resources</font></b></p>
-<p align="left"><font face="Verdana, Arial, Helvetica, sans-serif" size="2" color="#FFFFFF">
-<a href="acknowledgement.html" target=_top>Acknowledgements</a><br>
-<span style="line-height:0.7; font-weight:600">The Team</span><br>
-<a href="team.html" target=_top>iGEM Member List</a> |
-<a href="contribution.html" target=_top>Contributions</a><br>
-<span style="line-height:0.7; font-weight:600">Achievements</span><br>
-<a href="medal.html" target=_top>Medal Requirements</a> |
-<a href="biosafety.html" target=_top>BioSafety</a><br>
-<span style="line-height:0.7; font-weight:600">BioBricks</span><br>
-<a href="characterization.html" target=_top>Master List & Characterization Data</a>
+<td width="302px" bgcolor="#D09C00" valign="baseline">
+<p align="center" valign="baseline">
+<b><font color="#FFF4D0">iGEM Resources</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/acknowledgement.html" target=_top>Acknowledgements</a></p>
+<p align="center" valign="baseline">
+<b><font color="#FFF4D0">The Team</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/team.html" target=_top>iGEM Member List</a><font color="#FFF4D0"> | </font>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/contribution.html" target=_top>Contributions</a><br></p>
+<p align="center" valign="baseline">
+<b><font color="#FFF4D0">Achievements</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/medal.html" target=_top>Medal Requirements</a><font color="#FFF4D0"> | </font>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/biosafety.html" target=_top>BioSafety</a><br></p>
+<p align="center" valign="baseline">
+<b><font color="#FFF4D0">BioBricks</font></b></p>
+<p align="center" valign="baseline">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/characterization.html" target=_top>Master List & Characterization Data</a><br></p>
-<a href=.html><font color=white>
-</font></a><br><font></p>
 </td>
-<td width="200px"bgcolor="#980000"valign="baseline">
+<td width="180px"bgcolor="#980000"valign="baseline">
-<p align="left" valign="baseline"><b><font face="Verdana, Arial, Helvetica, sans-serif" size="3" color="#FFE0E0">
+<p align="center" valign="baseline">
-Human Practice</font></b></p>
+<b><font color="#FFE0E0">Human Practice</font></b></p>
-<p align="left"><font face="Verdana, Arial, Helvetica, sans-serif" size="2" color="#FFFFFF">
-<a href="workshop.html" target=_top>Workshop</a> |
+<p align="center" valign="baseline">
-<font face="Verdana, Arial, Helvetica, sans-serif" size="2" color="#FFFFFF">
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/workshop.html" target=_top>Workshop</a><font color="white"> | </font>
-<a href="survey.html" target=_top>Survey</a>
+<a href="https://2011.igem.org/Team:HKUST-Hong_Kong/survey.html" target=_top>Survey</a><br></p>
-</span></p>
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