Team:UEA-JIC Norwich/Nittygritty-algae
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- | + | <h1 style="font-family:verdana;color:Green">ALGAE</h1> | |
- | <h1 style="font-family:verdana;color: | + | <p>We have preformed two different types of protocol; glass bead and electroporation to transform the algal species <i>Chlamydomonas reinhardtii</i>. This is a single celled, photosynthetic eukaryote. We have been using the specific strain CC-4350 cw15-302 mt+. This strain is biflagellate with a high transformation frequency, due in part to its lack of a cell wall. Its genome has been sequenced, allowing us to research its codon bias.</p> |
- | <p>We | + | <p>There are twenty common amino acids, but over sixty codon configurations. So, each amino acid can be coded for by multiple codons. The code is thus said to be degenerate. However, most organisms display a preference for one codon or another, and so prefer to express a given amino acid by a certain codon. This is known as the codon bias. We researched the codon bias for <i>Chlamydomonas reinhardtii</i>, and are using this information to optimise the Biobricks we wish to use for expression in <i>C. reinhardtii</i>.</p> |
- | <p>There are twenty common amino acids, but over sixty codon configurations. So, each amino acid can be coded for by multiple codons. The code is thus said to be degenerate. However, most organisms display a preference for one codon or another, and so prefer to express a given amino acid by a certain codon. This is known as the codon bias. We researched the codon bias for <i>Chlamydomonas reinhardtii</i>, and | + | |
- | < | + | |
<br> | <br> | ||
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<td>Tris base</td> | <td>Tris base</td> | ||
<td>2.42g</td> | <td>2.42g</td> | ||
- | <td>H2NC( | + | <td>H2NC(CH<sub>2</sub>OH)<sub>3</sub> </td> |
<td></td> | <td></td> | ||
- | <td>2.00 . 10-2 M</td> | + | <td>2.00 . 10<sup>-2</sup>M</td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>TAP-salts (Beijerinck salts)</td> | <td>TAP-salts (Beijerinck salts)</td> | ||
<td>25mL</td> | <td>25mL</td> | ||
- | <td> | + | <td>NH<sub>4</sub>Cl MgSO<sub>4</sub> . 7H<sub>2</sub>O CaCl<sub>2</sub> . 2H<sub>2</sub>O</td> |
- | <td>15 g . L-1 | + | <td>15 g . L<sup>-1</sup> |
- | 4 g . L-1 | + | 4 g . L<sup>-1</sup> |
- | 2 g . L-1</td> | + | 2 g . L<sup>-1</sup></td> |
- | <td>7.00 . 10-3 M | + | <td>7.00 . 10<sup>-3</sup> M |
- | 8.30 . 10-4 M | + | 8.30 . 10<sup>-4</sup> M |
4.50 . 10-4 M</td> | 4.50 . 10-4 M</td> | ||
</tr> | </tr> | ||
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<td>Phosphate solution</td> | <td>Phosphate solution</td> | ||
<td>1mL</td> | <td>1mL</td> | ||
- | <td> | + | <td>K<sub>2</sub>HPO<sub>4</sub> |
- | + | KH<sub>2</sub>PO<sub>4</sub></td> | |
- | <td>28.8 g . 100 mL-1 | + | <td>28.8 g . 100 mL<sup>-1</sup> |
- | 14.4 g . 100 mL-1</td> | + | 14.4 g . 100 mL<sup>-1</sup></td> |
- | <td>1.65 . 10-3 M | + | <td>1.65 . 10<sup>-3</sup> M |
- | 1.05 . 10-3 M</td> | + | 1.05 . 10<sup>-3</sup>M</td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>Hunter’s trace Elements</td> | <td>Hunter’s trace Elements</td> | ||
<td>1mL</td> | <td>1mL</td> | ||
- | <td>5.00 g . 100 mL-1 | + | <td>5.00 g . 100 mL<sup>-1</sup> |
- | 2.20 g . 100 mL-1 | + | 2.20 g . 100 mL<sup>-1</sup> |
- | 1.14 g . 100 mL-1 | + | 1.14 g . 100 mL<sup>-1</sup> |
- | 0.50 g . 100 mL-1 | + | 0.50 g . 100 mL<sup>-1</sup> |
- | 0.50 g . 100 mL-1 | + | 0.50 g . 100 mL<sup>-1</sup> |
- | 0.16 g . 100 mL-1 | + | 0.16 g . 100 mL<sup>-1</sup> |
- | 0.16 g . 100 mL-1 | + | 0.16 g . 100 mL<sup>-1</sup> |
- | 0.11 g . 100 mL-1</td> | + | 0.11 g . 100 mL<sup>-1</sup></td> |
- | <td>5.00 g . 100 mL-1 | + | <td>5.00 g . 100 mL<sup>-1</sup> |
- | 2.20 g . 100 mL-1 | + | 2.20 g . 100 mL<sup>-1</sup> |
- | 1.14 g . 100 mL-1 | + | 1.14 g . 100 mL<sup>-1</sup> |
- | 0.50 g . 100 mL-1 | + | 0.50 g . 100 mL<sup>-1</sup> |
- | 0.50 g . 100 mL-1 | + | 0.50 g . 100 mL<sup>-1</sup> |
- | 0.16 g . 100 mL-1 | + | 0.16 g . 100 mL<sup>-1</sup> |
- | 0.16 g . 100 mL-1 | + | 0.16 g . 100 mL<sup>-1</sup> |
- | 0.11 g . 100 mL-1</td> | + | 0.11 g . 100 mL<sup>-1</sup></td> |
- | <td>1.34 . 10-4 M | + | <td>1.34 . 10<sup>-4</sup> M |
- | 1.36 . 10-4 M | + | 1.36 . 10<sup>-4</sup> M |
- | 1.84 . 10-4 M | + | 1.84 . 10<sup>-4</sup> M |
- | 4.00 . 10-5 M | + | 4.00 . 10<sup>-5</sup> M |
- | 3.29 . 10-5 M | + | 3.29 . 10<sup>-5</sup> M |
- | 1.23 . 10-5 M | + | 1.23 . 10<sup>-5</sup> M |
- | 1.00 . 10-5 M | + | 1.00 . 10<sup>-5</sup> M |
- | 4.44 . 10-6 M</td> | + | 4.44 . 10<sup>-6</sup> M</td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>Acetic Acid</td> | <td>Acetic Acid</td> | ||
<td>1mL</td> | <td>1mL</td> | ||
- | <td> | + | <td>CH<sub>3</sub>COOH</td> |
<td></td> | <td></td> | ||
<td></td> | <td></td> | ||
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<h3 style="font-family:verdana;color:green">Method:</h3> | <h3 style="font-family:verdana;color:green">Method:</h3> | ||
- | <p>Dissolve | + | <p>Dissolve Na<sub>2</sub>EDTA . 2H<sub>2</sub>O in 100 mL dd-H<sub>2</sub>O by heating to 60-80 °C, then adjust pH with KOH to 5.0. |
Add all trace elements separately and check the pH value constantly. The pH value should not increase | Add all trace elements separately and check the pH value constantly. The pH value should not increase | ||
- | above 6.8, otherwise | + | above 6.8, otherwise MnSO<sub>4</sub> may precipitate. Let the solution stand at 4 °C; when the colour changes |
from orange to red after approx. 2 weeks, filter it, split it and store at -20 °C teflon or polycarbonate | from orange to red after approx. 2 weeks, filter it, split it and store at -20 °C teflon or polycarbonate | ||
containers (do not use glass containers for trace elements as these tend to adsorb to the glass surface). | containers (do not use glass containers for trace elements as these tend to adsorb to the glass surface). | ||
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<p>For stock cultures on agar slants add 1.0-1.3 % Agar (e.g. purified high strength, 1000 g . cm-²) to | <p>For stock cultures on agar slants add 1.0-1.3 % Agar (e.g. purified high strength, 1000 g . cm-²) to | ||
prepared medium before autoclaving.</p> | prepared medium before autoclaving.</p> | ||
- | The genome integration of plasmids lowers the transformation frequency of Chlamydomonas, as it is difficult to direct the specific site the DNA will integrate into. This raises the risk of integration within a gene vital for the organisms survival, thus killing the organism. The presence of a cell wall potentially hinders the transformations of many strains, but strains are available that are cell wall deficient (such as the CC-4350 cw15-302 mt+ strain we are using). Using such a strain negates the problem. | + | The genome integration of plasmids lowers the transformation frequency of <i>Chlamydomonas</i>, as it is difficult to direct the specific site the DNA will integrate into. This raises the risk of integration within a gene vital for the organisms survival, thus killing the organism. The presence of a cell wall potentially hinders the transformations of many strains, but strains are available that are cell wall deficient (such as the CC-4350 cw15-302 mt+ strain we are using). Using such a strain negates the problem. |
<h3 style="font-family:verdana;color:green">Plasmid Design:</h3> | <h3 style="font-family:verdana;color:green">Plasmid Design:</h3> | ||
- | <p>The genome integration of plasmids lowers the transformation frequency of Chlamydomonas, as it is difficult to direct the specific site the DNA will integrate into. This raises the risk of integration within a gene vital for the organisms survival, thus killing the organism. The presence of a cell wall potentially hinders the transformations of many strains, but strains are available that are cell wall deficient (such as the CC-4350 cw15-302 mt+ strain we are using). Using such a strain negates the problem.</p> | + | <p>The genome integration of plasmids lowers the transformation frequency of <i>Chlamydomonas</i>, as it is difficult to direct the specific site the DNA will integrate into. This raises the risk of integration within a gene vital for the organisms survival, thus killing the organism. The presence of a cell wall potentially hinders the transformations of many strains, but strains are available that are cell wall deficient (such as the CC-4350 cw15-302 mt+ strain we are using). Using such a strain negates the problem.</p> |
<br> | <br> | ||
+ | References: | ||
<br> | <br> | ||
- | + | <br> | |
+ | 1. http://cccryo.fraunhofer.de/sources/files/medien/TAP.pdf | ||
+ | <br> | ||
+ | <br> | ||
+ | |||
</html> | </html> |
Latest revision as of 20:28, 21 September 2011
ALGAE
We have preformed two different types of protocol; glass bead and electroporation to transform the algal species Chlamydomonas reinhardtii. This is a single celled, photosynthetic eukaryote. We have been using the specific strain CC-4350 cw15-302 mt+. This strain is biflagellate with a high transformation frequency, due in part to its lack of a cell wall. Its genome has been sequenced, allowing us to research its codon bias.
There are twenty common amino acids, but over sixty codon configurations. So, each amino acid can be coded for by multiple codons. The code is thus said to be degenerate. However, most organisms display a preference for one codon or another, and so prefer to express a given amino acid by a certain codon. This is known as the codon bias. We researched the codon bias for Chlamydomonas reinhardtii, and are using this information to optimise the Biobricks we wish to use for expression in C. reinhardtii.
Chlamydomonas Fact File
Name:Chlamydomonas reinhardtii
Attributes
Can be transformed by a variety of methods – electroporation; the bacterium Agrobacterium tumorfaciens; glass beads; or by a biolistic particle delivery system (gene gun)
Eukaryotic photosynthetic organism – therefore its post translational modifications will more closely reflect those seen in plants and other higher organisms when compared to, for example, E.coli
Difficulties of Use
Many strains have a cell wall, and therefore prove difficult to transform
Growing time of around a week in cultures or plates
Low transformation frequency due to genome integration of plasmids
Growth Conditions
Requires TAP (tris-acetone phosphate) media
Must be grown in sunlight
Must be grown at 25°C
Must be grown in an incubator shaker to ensure adequate aeration of the media with carbon dioxide
Stock solution | Volume | Component | Concentration in stock Solution | Concentration in final media |
---|---|---|---|---|
Tris base | 2.42g | H2NC(CH2OH)3 | 2.00 . 10-2M | |
TAP-salts (Beijerinck salts) | 25mL | NH4Cl MgSO4 . 7H2O CaCl2 . 2H2O | 15 g . L-1 4 g . L-1 2 g . L-1 | 7.00 . 10-3 M 8.30 . 10-4 M 4.50 . 10-4 M |
Phosphate solution | 1mL | K2HPO4 KH2PO4 | 28.8 g . 100 mL-1 14.4 g . 100 mL-1 | 1.65 . 10-3 M 1.05 . 10-3M |
Hunter’s trace Elements | 1mL | 5.00 g . 100 mL-1 2.20 g . 100 mL-1 1.14 g . 100 mL-1 0.50 g . 100 mL-1 0.50 g . 100 mL-1 0.16 g . 100 mL-1 0.16 g . 100 mL-1 0.11 g . 100 mL-1 | 5.00 g . 100 mL-1 2.20 g . 100 mL-1 1.14 g . 100 mL-1 0.50 g . 100 mL-1 0.50 g . 100 mL-1 0.16 g . 100 mL-1 0.16 g . 100 mL-1 0.11 g . 100 mL-1 | 1.34 . 10-4 M 1.36 . 10-4 M 1.84 . 10-4 M 4.00 . 10-5 M 3.29 . 10-5 M 1.23 . 10-5 M 1.00 . 10-5 M 4.44 . 10-6 M |
Acetic Acid | 1mL | CH3COOH |
Method:
Dissolve Na2EDTA . 2H2O in 100 mL dd-H2O by heating to 60-80 °C, then adjust pH with KOH to 5.0. Add all trace elements separately and check the pH value constantly. The pH value should not increase above 6.8, otherwise MnSO4 may precipitate. Let the solution stand at 4 °C; when the colour changes from orange to red after approx. 2 weeks, filter it, split it and store at -20 °C teflon or polycarbonate containers (do not use glass containers for trace elements as these tend to adsorb to the glass surface). After addition of acetic acid the pH should range at about 7.0.
Adjust medium to final pH of 6.0 or as desired with acetic acid and autoclave at 121 °C for 20 min.
For stock cultures on agar slants add 1.0-1.3 % Agar (e.g. purified high strength, 1000 g . cm-²) to prepared medium before autoclaving.
The genome integration of plasmids lowers the transformation frequency of Chlamydomonas, as it is difficult to direct the specific site the DNA will integrate into. This raises the risk of integration within a gene vital for the organisms survival, thus killing the organism. The presence of a cell wall potentially hinders the transformations of many strains, but strains are available that are cell wall deficient (such as the CC-4350 cw15-302 mt+ strain we are using). Using such a strain negates the problem.Plasmid Design:
The genome integration of plasmids lowers the transformation frequency of Chlamydomonas, as it is difficult to direct the specific site the DNA will integrate into. This raises the risk of integration within a gene vital for the organisms survival, thus killing the organism. The presence of a cell wall potentially hinders the transformations of many strains, but strains are available that are cell wall deficient (such as the CC-4350 cw15-302 mt+ strain we are using). Using such a strain negates the problem.
References:
1. http://cccryo.fraunhofer.de/sources/files/medien/TAP.pdf