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Team:Bielefeld-CeBiTec/Project/CO2-fixation/Carboxysome
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<font size="1" style="text-align:center;">Carboxysome</font> | <font size="1" style="text-align:center;">Carboxysome</font> | ||
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| - | <p>A carboxysome is an bacterial, intracellular microcompartiment surrounded by a protein shell. Carboxysomes play an essential role in carbon fixation mechanism, as they are the seperated center for these reaction. The first carboxysomes were discovered in 1956, and purified carboxysomes were first characterized in 1973 by | + | <p>A carboxysome is an bacterial, intracellular microcompartiment surrounded by a protein shell. Carboxysomes play an essential role in carbon fixation mechanism, as they are the seperated center for these reaction. The first carboxysomes were discovered in 1956, and purified carboxysomes were first characterized in 1973 by <a href="#shively1973">Shively et al., 1973</a>. |
The protein shell consists of two different types of proteins. Pentamers are used for the vertices of the icosaeder and hexamers for the facets. In the interior there are two different enzymes. On the one hand there is the RuBisCO which catalyses the reaction like described above. On the other hand there is the carbonic anhydrase which converts hydrogen carbonate (HCO3<sup>-</sup>) to carbon dioxide. The resulting carbon dioxide is the substrate for the RuBisCO.<br> | The protein shell consists of two different types of proteins. Pentamers are used for the vertices of the icosaeder and hexamers for the facets. In the interior there are two different enzymes. On the one hand there is the RuBisCO which catalyses the reaction like described above. On the other hand there is the carbonic anhydrase which converts hydrogen carbonate (HCO3<sup>-</sup>) to carbon dioxide. The resulting carbon dioxide is the substrate for the RuBisCO.<br> | ||
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| - | Shively et al., 1973. Functional organelles in Prokaryotes: Polyhedral Inclusions (Carboxysomes) of Thiobacillus neapolitanus. <a href="http://www. | + | Shively et al., 1973. Functional organelles in Prokaryotes: Polyhedral Inclusions (Carboxysomes) of Thiobacillus neapolitanus. <a href="http://www.sciencemag.org/content/182/4112/584.full.pdf" target="_blank">Science</a>, vol. 182, pp. 584-586 |
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Revision as of 23:19, 14 October 2014
CO2 Fixation
Carboxysome
Carboxysome
A carboxysome is an bacterial, intracellular microcompartiment surrounded by a protein shell. Carboxysomes play an essential role in carbon fixation mechanism, as they are the seperated center for these reaction. The first carboxysomes were discovered in 1956, and purified carboxysomes were first characterized in 1973 by Shively et al., 1973.
The protein shell consists of two different types of proteins. Pentamers are used for the vertices of the icosaeder and hexamers for the facets. In the interior there are two different enzymes. On the one hand there is the RuBisCO which catalyses the reaction like described above. On the other hand there is the carbonic anhydrase which converts hydrogen carbonate (HCO3-) to carbon dioxide. The resulting carbon dioxide is the substrate for the RuBisCO.
The advantage of the microcompartiment is that the concentration of carbon dioxide inside can be much higher than outside which increases the efficiency of the RuBisCO.
There are two different types of carboxysomes which are classified by the habitat of the organism. It is found in all cyanobacteria and some chemolitoautotrophic bacteria. A deletion mutant for a single gene of the cluster results in a conditionally lethal phenotype which requires high concentrations of carbon dioxide.
