Team:Oxford/progress2

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<h1>Modelling Progress Part 2</h1>
 
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<h2>Week 6 Day 5 </h2>
 
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<h2>Leroy says:</h2>
 
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<p> A big chunk of this morning was spent in our weekly iGEM meetings. At the meeting, I talked the rest of the team through the progress that had been made this week. A few suggestions were made. Firstly, a refinement of the microcompartment shape mutation model which made the mutations not random but based on deformations confirmed by observation. Secondly, the potential use of the compartment function in GEPASI to model both our microcompartment and to further the Melbourne modelling collaboration.</p>
 
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<p> The rest of the afternoon was spent finalizing the 150 word project abstract which took frustratingly long. After this, I developed the model of pH change in our system as a function of HEPES buffer concentration. <p>
 
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[[File:Buffer effect on ph change.png|840px|centre|thumb|This graph demonstrates the affect of varying HEPES concentration on the resulting pH change in our system]]
 
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<h2>Week 6 Day 4 </h2>
 
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<h2>Leroy says:</h2>
 
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<p> I have developed a new stochastic diffusion model but again have been running into a few problems. As such, I have decided to put that model on hold for the time being and am currently exploring GEPASI 3.3 as a simulation tool to track the concentrations of our intermediates. I have realized that the main difficulty in using GEPASI will be finding the constants required to output any useful data- this values will likely be taken from literature which is more difficult for me to navigate given my relative ignorance about biochemistry but perhaps this is a good opportunity for interdisciplinary co-operation! In addition to this, I have also developed a model which can simulate the random distortion of microcompartments from their idealized icosahedron form as this is what we expect will occur during their expression in our bacteria. </p>
 
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[[File:Microcompartment shape mutation.png|840px|centre|thumb|A 3D rendering of a mutated microcompartment (in blue) versus a perfect icosahedron (in red).]]
 
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<h2>Week 6 Day 3 </h2>
 
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<h2>Leroy says:</h2>
 
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<p> Continued the work I started yesterday on a new model as per Andreas' suggestion. The first step in simulating the concentrations of formaldehyde in the cell was reducing the model to a one-dimensional system. I then managed to develop a deterministic model of concentration given a constant rate of production within the microcompartment and having the remainder of the system governed by normal diffusion laws. I also made a first attempt to develop a stochastic model but there are a number of issues which arise when the model is left to run for too long. </p>
 
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[[File:1D Stochastic diffusion.png|840px|centre|thumb|A comparison of a basic stochastic and deterministic model for the concentration of formaldehyde within the cell.]]
 
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<h2>Matt says:</h2>
 
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<p>Only here for half a day today, went through the activationrepression stuff i did last week, tidied it up and changed AtivationRepression3ABC quite a bit to make it easier to see what was going on. Had a meeting last night about initial ideas for the poster design and spent this morning looking at past models for what was useful for the project, was aesthetic and was easy to understand. I came up with a list and will fill Leroy in when he comes in.</p>
 
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<h2>Week 6 Day 2 </h2>
 
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<h2>Matt says:</h2>
 
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<p>Forgot to update this last week, what i did was carry on the stochastic model for actual activation using the michaelis-menten equation modelling a time delayed step input of DCM which activates DCMA which activates GFP, both the DCMA and GFP had basal rates which changed the graph quite dramatically. Today i have been looking at a bit of what Emily does in the lab, redoing the video for the light detecting circuit and finishing up with the line of best fit stuff i was doing yesterday. The line of best fit model produce a line of the form y=a*x^b to approximate the expression of genes from lab data.</p>
 
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[[File:KineticOrderCalculator.png|840px|centre|thumb|Plotting an approximate response for data from a text book]]
 
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[[File:SystemStochastic.png|840px|centre|thumb|Stochastic simulation of activation of DCMR and GFP from a step input of DCM]]
 
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<h2>Week 6 Day 1 </h2>
 
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<h2>Leroy says:</h2>
 
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<p> I spent the morning having a meeting with Andreas about some issues I was running into with my 3D compartment collision model. Andreas, however, suggested that the model was far too complex and the number of assumptions required to get any sort of information out of the system rendered any conclusions from it redundant. Thus, the model has been abandoned. In the afternoon, I started working on solving and plotting a few differential equations which Jack gave me to ultimately plot a pH - time curve for our system. The results are plotted below. </p>
 
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[[File:Jacks equations 2.png|840px|centre|thumb|The simulations of pH change against moles of HCl produced vary according to the concentration of the HEPES buffer introduced.]]
 
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<h2>Week 5 Day 5 </h2>
 
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<h2>Oliver says:</h2>
 
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<p> Today I will be working on adapting the result that I got yesterday (the pH dependent volume of DCM degraded) by varying the parameters that we are either uncertain of or can vary either mechanically (eg. amount of water added) or biologically (eg. Kcat through directed evolution) to analyse exactly how these parameters affect the overall important response of our system. </p>
 
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[[File:Oxford model 29.png|840px|centre]]
 
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[[File:Oxford model 30.png|840px|centre]]
 
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<h2>Leroy says:</h2>
 
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<p>Today and yesterday was spent further developing the compartment diffusion model. The model is now able to plot multiple species and highlight points of collision. The data which I hope to get out of this simulation is the ability to predict the interactions and accumulations of products during the metabolic pathway. The biochemists have told me, however, of the existence of a software package called GEPASI which will help me do this more effectively. Thus, my reaction model will likely only be used to illustrate the presence and likelihood of collisions between molecular species.  </p>
 
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[[File:Compartment collisions marker.png|900px|centre|thumb|For clarity, this image illustrates only the interactions of two molecules. The molecule trajectories are plotted but the intersections must also be temporal hence the relative lack of collision markers - the red circles.]]
 
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<h2>Week 5 Day 4 </h2>
 
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<h2>Oliver says:</h2>
 
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<p>Today I have been working on the pH dependence of the system; namely making sure that the model doesn't assume that the bacteria will keep on degrading the bacteria once the pH reaches a level that the bacteria are unable to live in.  </p>
 
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<p> This idea will be extended to allow us to either calculate how much buffer to add to the aqueous layer or to allow us to calculate the amount of water to add to the aqueous layer so that in the lifetime of the bacteria, the pH doesn't drop to a level that would kill the bacteria prematurely. </p>
 
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<p>As you can see from the plots, the predictions for the amount of DCM that we should be able to degrade are quite promising. A major extension of this idea is that for our bacteria, Kcat is around 0.6 (molecules of DCM degraded per second by each dcmA molecule). This will be categorised more accurately by the biochems and their assays. However, for some degradation reactions in biology, the Kcat values are closer to 100000. As the volume of DCM degraded is directly proportional to the Kcat value, this hints that if we applied this system to breaking down other harmful substances with other bacteria, we could dramatically improve the rate at which we break down harmful substances, developing a new form of bio-remediation.</p>
 
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[[File:Oxford model 28.png|840px|centre]]
 
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<h2>Week 5 Day 3 </h2>
 
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<h2>Oliver says:</h2>
 
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<p>Gave the presentation with Glen this morning to the Biochemistry Department. It was very good experience for giving presentations and for answering the questions that come afterwards.</p>
 
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<p>The afternoon was spent looking into the variations in how the total amount of DCM that we should be able to degrade is affected by the number of dcmA molecules in the cell. This is obviously a linear relationship that depends on the amount of time that you let the system run for. This is shown in a time varying 3D plot, this is shown on the right below.</p>
 
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<p>This is an important consideration because when we are doing things like adding microcompartments to the cell, we need to analyse how this will affect the total percentage of cellular protein that will be dcmA and will therefore be utilized in breaking down the DCM.</p>
 
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<p>The eventual plan is for the models that Matt and Leroy have been doing to coincide with mine. They should be able to increase the accuracy to which we know some of the terms in the equations.</p>
 
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[[File:Oxford model 27.png|840px|left]]
 
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<h2>Leroy says:</h2>
 
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<p>Today was spent further developing the compartment model of diffusion which I started yesterday. The model is now able to simulate any number of realizations of two different species of molecules with different properties. In addition to this, some of the molecules have been constrained to appear only in the microcompartment (DcmA) while some of the molecules are created anywhere within the space and can flow through the microcompartment unhindered.</p>
 
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[[File:Compartment diffusion model 2.png|900px|centre|thumb|Here are some of the results produced by the improved version of the compartment model. The red represents DcmA while the blue represents DCM molecules.]]
 
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<h2>Week 5 Day 2 </h2>
 
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<h2>Oliver says:</h2>
 
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<p>Spent the day on SolidWorks in the Engineering department. I built a 3D model of the product that we plan to build to allow us to visualize it and spot any flaws in the design. It also allows us to explain the project to potential users. It will be useful for the presentation to the Biochemistry Department tomorrow lunchtime.</p>
 
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[[File:Oxford model 26.png|840px|left]]
 
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<h2>Matt says:</h2>
 
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<p>Produced a new stochastic model which has a step input of C (DCM) after 50s which activates the production of B (DCMR), the equations were taken from Antonis's lecture notes about gene expression. I included a basal rate of B so that there was a small amount produced even when there is no C present.</p>
 
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<h2>Leroy says:</h2>
 
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<p>This was my first day back after taking about a week off for family reasons. Matt has continued the stochastic modelling which I started off on Friday of Week 3. I spent today developing the diffusive aspect of the stochastic modelling and have successfully modeled the diffusive motion, according to the Smoluchowski equations, of DCM and DCMA within the microcompartment. The model is such that DCMA molecules cannot diffuse through the microcompartment but DCM molecules can move in and out unhindered due to their small size. </p>
 
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[[File:DCM DCMA in microcompartment.jpg|900px|centre|thumb|A visualization of the diffusion of DCM and DCMA within the microcompartment. DCM is indicated by the red lines and can pass through the microcompartment while DCMA is black and cannot diffuse out of the microcompartment]]
 
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[[File:Compartment diffusion model.jpg|900px|centre|thumb|An initial 'digitized' version of the 3D diffusion model. This is the first stage in modelling diffusion driven reactions]]
 
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<h2>Week 5 Day 1 </h2>
 
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<h2>Matt says:</h2>
 
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<p>I went through the derivation of a general stochastic model today and proved that the steady state variance=steady state mean=k2/k1 where k2=production constant and k1=degradation constant. I introduced this variance into ProductionDegradation3 then using Standard deviation=(Variance)^0.5 introduced a basic upper/lower bound for the population by adding and taking away 1.3 standard deviation to the mean. This gives us a confidence interval of 90% that the population will lie between the 2 blue lines. (Assuming the variation in population around the mean can be modelled using the normal distribution) </p>
 
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[[File:1.3SDInMeanPD3.png|840px|centre]]
 
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<h2>Oliver says:</h2>
 
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<p>Corrected the model that I built on Wednesday last week. That model was concerned with intracellular HCl concentration and therefore intracellular pH. However, after speaking to Ciaran, we think it's more realistic to assume that the cells have a chloride efflux pump. Therefore, we should be concerned with both the HCl concentration and pH outside of the cell. This obviously also depends on the volume of the aqueous layer, so the pH change that I've calculated won't be the real pH change of the system due to the fact that we will add a buffer solution to the container. The new volume of DCM degraded and pH change (without buffer) curves are shown below. The amount of DCM that we can degrade will be proportional to the number of happy bacteria that we have in the system and the length of time that we can keep them alive for.</p>
 
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[[File:Oxford model 25.png|840px|left]]
 
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Latest revision as of 01:01, 18 October 2014