Team:Toulouse/Modelling

From 2014.igem.org

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Modelling is a tool used to simplify and study systems. We can try to predict behaviour with bibliographic information or information obtained from experiment.</br>
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Modelling is a tool used to simplify and study systems. We can try to predict behavior with bibliographic information or information obtained from experiment.</br>
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Our project focuses on the development of our bacteria in tree. The way of bacterial growth in tree seems to be unknown, so we must infer bacillus subtilis behaviour.</p>
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Our project focuses on the development of our engineered bacteria in tree. The bacterial growth in tree seems to be unknown, so we must infer <i>Bacillus subtilis</i> behavior.</p>
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Objective
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Aim
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<i>Bacillus subtilis</i> is a trees endophyte strain, a study <b>[1]</b> showed that <i>Bacillus subtilis</i> could develop and colonize fully a tree and reach a concentration of 10⁵ cells per g of fresh plant. We need to know in which conditions the growth are optimum in a tree and if the weather can stop its development in winter. We work on the <i>Bacillus subtilis</i> growth in function of the temperature during year. Modeling bacterial growth in a tree section generate some difficulties, we need to know distance between two tree extremities (treetops and root) or the speed sap flow which can vary with temperature during the day and seasons, cause of the type of sap (phloem, xylem). Furthermore tree is not a homogeneous system, its roots, trunk and branch do not contain same amount of sap and wood. The average speed of the plane tree sap is 2.4m/h <b>[2]</b> that means that in a day the sap will flow from one end to the other of a tree 30m. Tree is reduced to a bioreactor.
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<i>Bacillus subtilis</i> is a trees endophyte strain. A study <b>[1]</b> showed that <i>Bacillus subtilis</i> could develop and fully colonize a tree, reaching a concentration of 10⁵ cells per gram of fresh plant. We need to know in which conditions the growth of <i>B. subtilis</i> is optimum in a tree and if the weather can stop its development during winter. So we decided to work on the <i>Bacillus subtilis</i> growth in function of the temperature during the year. Modeling bacterial growth in a tree section generates some difficulties, we need to know distance between two tree extremities (treetops and root) or the speed sap flow which can vary with temperatures during the day and seasons, cause of the type of sap (phloem, xylem). Furthermore a tree is not an homogeneous system, its roots, trunk and branch do not contain same amount of sap and wood. The average speed of the plane tree sap is 2.4m/h <b>[2]</b>, which means that in a day the sap will flow from one end to the other of a tree 30m. Tree is reduced to a bioreactor.
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According to the publication of <b>Xianling Ji[1]</b>, after 6 months of <i>Bacillus subtilis</i> growth in a tree bacteria cells reach a concentration of 10⁵ cells per gram of fresh plant. Assume that 10⁵ cells / g is the maximum concentration.
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According to the publication of <b>Xianling Ji[1]</b>, after 6 months of <i>Bacillus subtilis</i> growth in a tree, bacteria cells reach a concentration of 10⁵ cells per gram of fresh plant. We assume that 10⁵ cells / g is the maximum concentration.
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with n = 1 and m = 0.5</br></br>
with n = 1 and m = 0.5</br></br>
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Term (1-(Nmin/N)) is not taken into account when there is growth and (1-(N/Nmax)) is not taken account when there is bacterial decay.</br>
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Term (1-(Nmin/N)) is not taken into account when there is growth and (1-(N/Nmax)) is not taken into account when there is bacterial decay.</br>
Meteorological records of the Toulouse region of 2011-2013 are used to do averages daily temperatures. Thus we can determine <i>B.subtilis</i> growth during a year on Toulouse. This values are obtained for each day by the average on the hightest and the lowest temperature.
Meteorological records of the Toulouse region of 2011-2013 are used to do averages daily temperatures. Thus we can determine <i>B.subtilis</i> growth during a year on Toulouse. This values are obtained for each day by the average on the hightest and the lowest temperature.
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The density of green wood plane is about 650kg / m³. The average diameter of the trunks of the trees in question is about 0.80m and 15m high. This represents a volume of 30 m³ . The weight of the trunk is therefore 19604kg .
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The density of green wood plane is about 650kg / m³. The average diameter of the trunks of the trees in question is about 0.80m and 15m high. This represents a volume of 30 m³ . The weight of the trunk is therefore 19,604kg .
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Added to this weight the weight of branches, twigs, leaves about 25 % and about 15% of roots (source).
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Added to this weight the weight of branches, twigs, leaves about 25% and about 15% of roots (source).
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The average weight of a tree plane is 27446kg where in inoculated 10mL of bacterial culture at 10⁹cfu/mL, ie 10^10 bacterial cells. This represents 3.64x10² cfu/g of fresh plant (N0).
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The average weight of a tree plane is 27,446kg where in inoculated 10mL of bacterial culture at 10⁹cfu/mL, ie 10^10 bacterial cells. This represents 3.64x10² cfu/g of fresh plant (N0).
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In our model growth start only from 10°C this product between March and April. This period seems to be suitable to put the strain in the tree. From December the temperature down to be below 4°C, threshold below which bacterias dies.
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In our model, growth starts only from 10°C, which happens between March and April. This period seems to be suitable to put the strain in the tree. From December the temperature decreased below 4°C, threshold below which bacteria die.
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In practice, the temperature variations are certainly lower in tree than outside, especially if roots extend very deep. Composition of the tree sap must also intervene in the growth rate, nutrient content of sap is also temperature dependent. The effects of the decrease of the temperature in winter also involve a fall of the sap and this must also be involved in the disappearance of our strain in the tree. The period of <i>Bacillus subtilis</i> growth is certainly affected by the change in temperature, the rise of sap, its composition variations can consequently slow the growth rate.
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In practice, temperature variations are certainly lower in tree than outside, especially if roots extend very deep. Composition of the tree sap must also intervene in the growth rate, nutrient content of sap is also temperature dependent. The effects of the decrease of the temperature in winter also involves a fall of the sap and this must also be involved in the disappearance of our strain in the tree. The period of <i>Bacillus subtilis</i> growth is certainly affected by the change in temperature, the rise of sap, its composition variations can consequently slow the growth rate.
The modeling work is done with the programming language 'R' script attached.
The modeling work is done with the programming language 'R' script attached.

Revision as of 17:47, 12 October 2014