Team:Utah State/Modeling
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<td width="172" id="ana"><span class="currentPage"><font size = 4>MODELING</font></span> | <td width="172" id="ana"><span class="currentPage"><font size = 4>MODELING</font></span> | ||
+ | <a href="#parameters">Parameters</a><br /> | ||
+ | <a href="#simulations">Simulations</a><br /> | ||
+ | <a href="#references">References</a> | ||
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There is currently limited information on how to properly select which secretion pathway should be used for a given protein (Choi, 2004). The construction of models that evaluate protein secretion may provide a useful framework for studying and attempting to predict secretion efficiency. Models of the Sec and Tat translocation pathways were made using MATLAB’s Simbiology toolbox. They were evaluated using the embedded ordinary differential equation solver in the software. Assumptions were made for both models due to lack of time scale information for individual steps for these translocation mechanisms. However, both provide a flexible framework that can become more detailed as additional information is found in literature or discovered in the laboratory. Within both models, a protein is first generated and then carried out of the cytoplasm to the periplasm. Only protein species were tracked, as species involved with making the protein are currently not as useful to monitor. | There is currently limited information on how to properly select which secretion pathway should be used for a given protein (Choi, 2004). The construction of models that evaluate protein secretion may provide a useful framework for studying and attempting to predict secretion efficiency. Models of the Sec and Tat translocation pathways were made using MATLAB’s Simbiology toolbox. They were evaluated using the embedded ordinary differential equation solver in the software. Assumptions were made for both models due to lack of time scale information for individual steps for these translocation mechanisms. However, both provide a flexible framework that can become more detailed as additional information is found in literature or discovered in the laboratory. Within both models, a protein is first generated and then carried out of the cytoplasm to the periplasm. Only protein species were tracked, as species involved with making the protein are currently not as useful to monitor. | ||
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+ | <a name="parameters"> | ||
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+ | <b><i><font size="3" face="Helvetica, Arial, San Serif" color =#000033> | ||
+ | Model Parameters | ||
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In both models, parameters for the manufacture of protein were the same and found using averaged values for <i>E. coli</i>. The average length of an mRNA for <i>E. coli</i> is 1100 nucleotides and an <i>E. coli</i> cell transcribes at an average rate of 70 nucleotides per second. A simple rate calculation determines that a strand of mRNA is made approximately every 15.7 seconds. This value was then used to yield a first order reaction rate of (1/15.7) 1/second. The translation rate was found in a similar manner. Given an average protein size in <i>E. coli</i> as 360 amino acids and the average translation rate is 40 amino acids per second, the first order translation rate constant is (1/9) 1/s (Institute for Biomolecular Design, 2008). To initiate the model, the concentration of the gene was set at 1, which was locked at that value over the course of the simulation. The median half life for mRNA was found to be 3.7 minutes, after which it will degrade (Milo, n. d.). For the Tat-dependent mechanism, the protein is fully folded prior to translocation (Mergulhão, 2005). For this folding time, a place holder value of 10 minutes was used as an approximate order of magnitude, although the value can easily be changed depending on parameters of the protein in question. Degradation of protein was modeled as the average time it takes the cell to reproduce, which is given as half an hour (Institute for Biomolecular Design, 2008). | In both models, parameters for the manufacture of protein were the same and found using averaged values for <i>E. coli</i>. The average length of an mRNA for <i>E. coli</i> is 1100 nucleotides and an <i>E. coli</i> cell transcribes at an average rate of 70 nucleotides per second. A simple rate calculation determines that a strand of mRNA is made approximately every 15.7 seconds. This value was then used to yield a first order reaction rate of (1/15.7) 1/second. The translation rate was found in a similar manner. Given an average protein size in <i>E. coli</i> as 360 amino acids and the average translation rate is 40 amino acids per second, the first order translation rate constant is (1/9) 1/s (Institute for Biomolecular Design, 2008). To initiate the model, the concentration of the gene was set at 1, which was locked at that value over the course of the simulation. The median half life for mRNA was found to be 3.7 minutes, after which it will degrade (Milo, n. d.). For the Tat-dependent mechanism, the protein is fully folded prior to translocation (Mergulhão, 2005). For this folding time, a place holder value of 10 minutes was used as an approximate order of magnitude, although the value can easily be changed depending on parameters of the protein in question. Degradation of protein was modeled as the average time it takes the cell to reproduce, which is given as half an hour (Institute for Biomolecular Design, 2008). | ||
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In addition to the discussed values regarding the manufacture of protein, parameters for the Sec and Tat pathway are required. A literature review yielded no specific rate constants or time parameters for the individual steps involved with either process. However, one article stated that the Sec and Tat pathways take a few seconds and a few minutes, respectively, to translocate protein to the periplasmic space (Mergulhão, 2005). Accordingly, the Sec and Tat pathways were modeled to require 3 seconds and 3 minutes for protein translocation, respectively. First order rate constants were determined by taking the inverse of these values in seconds. Images of the model diagrams are seen below. The different pathways after the formation of protein can be activated and deactivated as more detailed information comes available about the translocation and secretion processes. The Sec secretion pathway also includes the SRP secretion pathway as a possible option. The constructed models for the Sec and Tat pathways are given as Figures 1 and 2, respectively. | In addition to the discussed values regarding the manufacture of protein, parameters for the Sec and Tat pathway are required. A literature review yielded no specific rate constants or time parameters for the individual steps involved with either process. However, one article stated that the Sec and Tat pathways take a few seconds and a few minutes, respectively, to translocate protein to the periplasmic space (Mergulhão, 2005). Accordingly, the Sec and Tat pathways were modeled to require 3 seconds and 3 minutes for protein translocation, respectively. First order rate constants were determined by taking the inverse of these values in seconds. Images of the model diagrams are seen below. The different pathways after the formation of protein can be activated and deactivated as more detailed information comes available about the translocation and secretion processes. The Sec secretion pathway also includes the SRP secretion pathway as a possible option. The constructed models for the Sec and Tat pathways are given as Figures 1 and 2, respectively. | ||
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<b><i> PUT IN FIGURES</b></i> | <b><i> PUT IN FIGURES</b></i> | ||
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- | Simulations for the Sec pathways were run for 5400 seconds (1.5 hours), which allowed the number of periplasmic to reach approximately steady state. The simulation for the Sec pathway secretion model is shown below as Figure 3. | + | </td></tr> |
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+ | Simulations | ||
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+ | <p class = "class">Simulations for the Sec pathways were run for 5400 seconds (1.5 hours), which allowed the number of periplasmic to reach approximately steady state. The simulation for the Sec pathway secretion model is shown below as Figure 3. | ||
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<b><i> PUT IN FIGURES </b></i> | <b><i> PUT IN FIGURES </b></i> | ||
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References | References | ||
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Revision as of 03:08, 21 October 2009
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