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	<h3>The methylation subsystem</h3>		<h3>The methylation subsystem</h3>
-	The second adaption system of ''B.Subtilis'' described here is the methylation system, which is similar to the methylation system of ''E.Coli''. The methylation system regulates the CheA phosphorylation rate through phosphorylated CheB (BP) (which obtains its phosphor group from AP) and CheR. For B.Subtilis it is proposed that BP and CheR do not demethylate and remethylate the receptor, but shuffle the methyl groups between different residues so that the methylation of certain residues activates the receptor, whilst the methylation of others deactivates it [x2].	+	<p>The second adaption system of <i>B.Subtilis</i> is the methylation system, which regulates the CheA phosphorylation rate through phosphorylated CheB (BP) and CheR. After obtaining its phosphor group from AP, BP can shuffle methyl groups between different receptor residues. It is thus proposed that the methylation of certain receptor residues can activate the receptor, whilst the methylation of others can deactivate it [x2]. In order to provide negative AP feedback, BP would then shuffle methyl groups on the activation residues to the deactivation residues, whilst CheR shuffles methyl groups from the deactivation residues to the activation residues. We describe this system with the chemical reactions given below, where T<i>M0</i> represents the methyl-deactivated receptors and <i>M1</i> the methyl-activated receptors. Finally, k3 and k5 are linear functions of attractant concentrations (fig x and x), which enables us to eliminate the feedback loop involving AP, BP, and T<i>M1</i>. </p>
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		+	</td></tr><tr><td><font size="1">Figure 2</font></td></tr></table></div>
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Revision as of 12:23, 30 September 2013

Heat Motility

The goal for our heat motility system is to obtain higher concentrations of silk in close proximity to the implant. This is achieved by immobilizing the silk producing bacteria once they are within some distance to the implant, which is enabled by integrating the standard chemotaxis system with the DesK membrane fluidity sensor system. The result is that ''B. Subtilis'' stops moving when it is 37°C, and swims when it is 25°C. In our model we simulate the behaviour of these systems and, if necessary, implement biologically plausible modifications to make it feasible.

The chemotaxis system of '' B. subtilis''

We first setup a model for the standard chemotaxis system. This system enables bacteria to seek out areas of higher concentrations of nutrients by modifying the direction of flagella rotations as a response to changes in concentrations of attractants and repellents. An increase in the concentration of attractants results in more clockwise (CW) rotations, and an increase in the concentration of repellents in more counter clockwise (CCW) rotations, which corresponds to an increased chance of swimming straight and tumbeling respectively. This effect is complemented by the systems essential ability to adapt to any concentration of attractant or repellent. Given a homogenous environment, the system will therefore allways maintain the same swimming to tumbling ratios.

At the molecular level the flagella behaviour is controlled directly by the concentration of phosphorylated CheY (YP): more YP results in more CW rotations (more swimming) and less YP in more CCW rotations (more tumbeling). YP is controlled by phosphorylated CheA concentrations (AP), its natural decay rate, and by CheC_CheD complex concentrations (CD), which act as YP dephosphorylases. Because the actual rate coefficients are unknown, we combined the natural and CD induced dephosphorylation rates by making the k11 rate coefficient a function of CD.

In order to obtain proper swimming behaviour, we require an initial increase and a delayed decrease in YP. The initial YP increase is due to an in increase in AP (which donate their phosphor groups to CheY) as a response to increased attractant concentrations. The decrease in YP is realized by two negative feedback systems, the CheV and the methylation subsystem, which decrease CheA phosphorylation rates, and by one negative feedfoward system, the CheC-CheD subsystem, which increases the YP decay rate.

CheA phosphorylation

Inside the cell CheW, CheA and CheV form complexes with the intermembrane receptor protein. When attractants bind to the receptor, CheA undergoes a change in conformation that enables it to be phosphorylated.

Following the example of David C. and John Ross [x1], we assume the binding and dissociation of attractants with their receptors is fast, and that it can be described with the equillibrium equation (1), where KD is the dissociation constant for the aspartate receptor (which is focus of this model). The concentration of unbound receptors is then given by (2).

Due to high concentrations of ATP in the cell, we assume similar kinetics for the CheA (A) phosphorylation rate. It then follows that the positive increase in AP levels is proportional to bound receptor (Ta) and unbound receptor (T0) levels, and can be described by (3), where ATR is a constant.

The CheV subsystem

The first adaption system of B.Subtilis, the CheV subsystem, contributes to a delayed decrease in YP through a decrease in AP. This is realized by phosphorylated CheV (VP), which obtains its phospfor group from AP, after which it may disrupt the bond between the attractant-bound receptor and CheA, thus inhibiting CheA phosphorylation [x2].

Because AP levels are proportional to attractant levels we neglect the AP in our reactions (chem reaction 2) and take the rate coefficient k1 as a linear function of attractant levels (fig x). Because the negative decrease in AP levels is dependent on VP, this disrupts feedback loop between AP and VP levels, thus making the optimization later easier (see section x).

The negative decrease in AP due to VP is approximately 22% of the positive increase in AP described in (3), and is calculated simply by subtracting VP from AP (4).

The methylation subsystem

The second adaption system of B.Subtilis is the methylation system, which regulates the CheA phosphorylation rate through phosphorylated CheB (BP) and CheR. After obtaining its phosphor group from AP, BP can shuffle methyl groups between different receptor residues. It is thus proposed that the methylation of certain receptor residues can activate the receptor, whilst the methylation of others can deactivate it [x2]. In order to provide negative AP feedback, BP would then shuffle methyl groups on the activation residues to the deactivation residues, whilst CheR shuffles methyl groups from the deactivation residues to the activation residues. We describe this system with the chemical reactions given below, where TM0 represents the methyl-deactivated receptors and M1 the methyl-activated receptors. Finally, k3 and k5 are linear functions of attractant concentrations (fig x and x), which enables us to eliminate the feedback loop involving AP, BP, and TM1.

The CheC CheD subsystem

Exact adaption

Motility model

Homogenous and non-homogenous environments

CheC knockout

The effects of temperature

The DesK system

Demonstration

Matlab code

References

[x2] the three adaption systems of b subtilis