Team:UNIPV-Pavia/Modelling03

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<table id="toc" class="toc"><tr><td><div id="toctitle"><h2>Contents</h2></div>  
<table id="toc" class="toc"><tr><td><div id="toctitle"><h2>Contents</h2></div>  
<ul>  
<ul>  
-
<li class="toclevel-1"><a href="#Mathematical_modelling_page"><span class="tocnumber">1</span> <span class="toctext">Mathematicall modeling page</span></a>  
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<li class="toclevel-1"><a href="#Mathematical_modelling_page"><span class="tocnumber">1</span> <span class="toctext">Mathematical modelling: introduction</span></a>  
<ul>  
<ul>  
-
<li class="toclevel-2"><a href="#The importance of the mathematical model"><span class="tocnumber">1.1</span> <span class="toctext">The importance of tha mathematical model</span></a></li>  
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<li class="toclevel-2"><a href="#The importance of the mathematical model"><span class="tocnumber">1.1</span> <span class="toctext">The importance of mathematical modelling</span></a></li>  
<li class="toclevel-2"><a href="#Equations_for_gene_networks"><span class="tocnumber">1.2</span> <span class="toctext">Equations for gene networks</span></a></li>
<li class="toclevel-2"><a href="#Equations_for_gene_networks"><span class="tocnumber">1.2</span> <span class="toctext">Equations for gene networks</span></a></li>
<ul>  
<ul>  
-
<li class="toclevel-3"><a href="#Equations_1_and_2"><span class="tocnumber">1.2.1</span> <span class="toctext">Equations (1) and (2)</span></a></li>
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<li class="toclevel-3"><a href="#Hypothesis"><span class="tocnumber">1.2.1</span> <span class="toctext">Hypothesis of the model</span></a></li>     
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<li class="toclevel-3"><a href="#Equation_3"><span class="tocnumber">1.2.2</span> <span class="toctext">Equation (3)</span></a></li>
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<li class="toclevel-3"><a href="#Equations_1_and_2"><span class="tocnumber">1.2.2</span> <span class="toctext">Equations (1) and (2)</span></a></li>
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<li class="toclevel-3"><a href="#Equation_4"><span class="tocnumber">1.2.3</span> <span class="toctext">Equation (4)</span></a></li>  
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<li class="toclevel-3"><a href="#Equation_3"><span class="tocnumber">1.2.3</span> <span class="toctext">Equation (3)</span></a></li>
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<li class="toclevel-3"><a href="#Equation_4"><span class="tocnumber">1.2.4</span> <span class="toctext">Equation (4)</span></a></li>  
</ul>  
</ul>  
   
   
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<li class="toclevel-2"><a href="#Parameter_estimation"><span class="tocnumber">1.4</span> <span class="toctext">Parameter estimation</span></a></li>  
<li class="toclevel-2"><a href="#Parameter_estimation"><span class="tocnumber">1.4</span> <span class="toctext">Parameter estimation</span></a></li>  
<ul>  
<ul>  
-
<li class="toclevel-3"><a href="#Ptet_&_Plux"><span class="tocnumber">1.4.1</span><span class="toctext">Ptet & Plux</span></a></li>  
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<li class="toclevel-3"><a href="#Ptet_&_Plux"><span class="tocnumber">1.4.1</span> <span class="toctext">pTet & pLux</span></a></li>  
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<li class="toclevel-3"><a href="#AiiA"><span class="tocnumber">1.4.2</span> <span class="toctext">AiiA</span></a></li><li class="toclevel-3"><a href="#LuxI"><span class="tocnumber">1.4.3</span> <span class="toctext">LuxI</span></a></li></ul>
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<li class="toclevel-3"><a href="#Enzymes"><span class="tocnumber">1.4.2</span> <span class="toctext"> AiiA & LuxI</span></a></li>
 +
<li class="toclevel-3"><a href="#N"><span class="tocnumber">1.4.3</span> <span class="toctext">N</span></a></li></ul>
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<li class="toclevel-3"><a href="#Degradation_rates"><span class="tocnumber">1.4.4</span> <span class="toctext">Degradation rates</span></a></li></ul>
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<a name="Mathematical_modeling_page"></a><h1><span class="mw-headline"> <b>Mathematical modelling page</b> </span></h1>  
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<a name="Mathematical_modeling_page"></a><h1><span class="mw-headline"> <b>Mathematical modelling: introduction</b> </span></h1>  
-
<div style='text-align:justify'>Mathematical modelling plays nowadays a central role in Synthetic Biology, due to its ability to serve as a crucial link between the concept and realization of a biological circuit: what we propose in this page is a modelling approach to our project, which has proved extremely useful and very helpful before and after the "wet lab". <br>
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<div style='text-align:justify'>Mathematical modelling plays nowadays a central role in Synthetic Biology, due to its ability to serve as a crucial link between the concept and realization of a biological circuit: what we propose in this page is a modelling approach to our project, which has proven extremely useful and very helpful before and after the "wet lab". <br>
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Thus, immediatly at the beginning, when there was little knowledge, a mathematical model based on a system of differential equations was derived and performed using a set of reasonable parameters, so as to validate the feasibility of the project. Once it became clear, starting from the characterization of the single subparts created in the wet lab, some of the parameters of the mathematical model were estimated (the others are known from literature) and they have been implemented in the same model, in order to predict the final behaviour of the whole engineered closed-loop circuit.
+
Thus, immediately at the beginning, when there was little knowledge, a mathematical model based on a system of differential equations was derived and implemented using a set of parameters, to validate the feasibility of the project. Once this became clear, starting from the characterization of the single subparts created in the wet lab, some of the parameters of the mathematical model were estimated (the others are known from literature) and they have been fixed to simulate the same model, in order to predict the final behaviour of the whole engineered closed-loop circuit. <font color="red">This approach is consistent with the typical one adopted for the analysis and synthesis of a biological circuit, as exemplified by Pasotti et al 2011.</font>
<br>
<br>
<br>
<br>
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Therefore here, after a brief overview about the advantages that modelling engineered circuits can bring, we deeply analyze the system of equation formulas, underlining the role and the function of the parameters involved. <br>
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Therefore here, after a brief overview about the advantages that modelling engineered circuits can bring, we deeply analyze the system of equation formulas, underlining the role and function of the parameters involved. <br>
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Experimental procedures for parameters estimation are discussed and, finally, a different type of circuit is presented and simulations performed, using ODE's with MATLAB and explaining the difference between a closed-loop model and an open one.</div>
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Experimental procedures for parameter estimation are discussed and, finally, a different type of circuit is presented. Simulations were performed, using <em>ODEs</em> with MATLAB and used to explain the difference between a closed-loop control system model and an open one.</div>
<br />  
<br />  
<br />  
<br />  
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<a name="The importance of the mathematical model"></a><h2> <span class="mw-headline"> <b>The importance of the mathematical model</b> </span></h2>  
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<a name="The importance of the mathematical model"></a><h2> <span class="mw-headline"> <b>The importance of mathematical modelling</b> </span></h2>  
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<div style='text-align:justify'>The purposes of writing mathematical models for gene networks can be: </div>  
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<div style='text-align:justify'>The purposes of deriving mathematical models for gene networks can be:  
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<br>
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<br><br>
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<ul><li><b>Prediction</b>: in the initial steps of the project, a good <em>a-priori</em> identification in silico allows to suppose the kinetics of the enzymes (aiiA, Luxi) and HSL involved in our gene network, basicly to understand if the complex circuit's structure and functioning could be achievable and to investigate the value's range of parameters ​​for which the behavior is that expected.
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<li><b>Prediction</b>: in the initial steps of the project, a good <em>a-priori</em> identification "in silico" allows to suppose the kinetics of the enzymes (AiiA, Luxi) and HSL involved in our gene network, basically to understand if the complex circuit structure and functioning could be achievable and to investigate the range of parameters values ​​for which the behavior is the one expected. <font color="red">(Endler et al, 2009)</font>
 +
<br><br>
 +
<li><b>Parameter identification</b>: a modellistic approach is helpful to get all the parameters involved, in order to perform realistic simulations not only of the single subparts created, but also of the whole final circuit, according to the <em>a-posteriori</em> identification.
 +
<br><br>
 +
<li><b>Modularity</b>: studying and characterizing basic BioBrick Parts can allow to reuse this knowledge in other studies, concerning with the same basic modules <font color="red">(Braun et al, 2005; Canton et al, 2008).</font>
 +
</div> 
<br>
<br>
-
<li><b>Parameter identification</b>: Using the <em>lsqnonlin</em> function of MATLAB it was possible to get all the parameters involved in the model, in order to perform realistic simulations not only of the single subparts created, but also of the whole final circuit, according to the <em>a-posteriori</em> identification.
 
<br>
<br>
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<li><b>Modularity</b>: studing and characterizing simple BioBrick Parts can allow to reuse this knowledge in other studies, facing with the same basic modules.
 
-
</ul>
 
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</p><br>
 
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<p>
 
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</p>
 
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<li><b>Parameter identification</b>: we already wrote that it is very important to estimate all the parameters involved in the model, in order to perform realistic simulations. Another goal that can be reached with parameter identification is 'network summarization', in fact estimated parameters can be used as 'behavior indexes' for the network (or a part of it). These indexes can be very useful for synthetic biologists to choose and compare BioBrick standard parts for genetic circuits design, just like electronic engineers choose, for example, a Zener diode, knowing its Zener voltage.
 
-
</ul>
 
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<a name="Equations_for_gene_networks"></a><h2> <span class="mw-headline"> <b>Equations for gene networks</b> </span></h2>  
<a name="Equations_for_gene_networks"></a><h2> <span class="mw-headline"> <b>Equations for gene networks</b> </span></h2>  
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<div style='text-align:justify'><div style='text-align:justify'><div class="thumbinner" style="width: 800px;"><a href="File:Circuito.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/2/2a/Circuito.jpg" class="thumbimage" height="80%" width="80%"></a></div></div>
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<div style='text-align:justify'><div class="thumbinner" style="width: 800px;"><a href="File:Circuito.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/2/2a/Circuito.jpg" class="thumbimage" height="65%" width="80%"></a></div></div>
<br>
<br>
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<div style='text-align:justify'><div class="thumbinner" style="width: 850px;"><a href="File:Schema_controllo.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/e/e2/Schema_controllo.jpg" class="thumbimage" height="50%" width="80%"></a></div></div>
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<div style='text-align:justify'><div class="thumbinner" style="width: 850px;"><a href="File:Schema_controllo.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/e/e2/Schema_controllo.jpg" class="thumbimage" height="75%" width="80%"></a></div></div>
<br>
<br>
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<div class="center"></div>
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<div style='text-align:justify'><div class="thumbinner" style="width: 850px;"><a href="File:Model1.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/0/07/Model1.jpg" class="thumbimage" height="68%" width="87%"></a></div></div>
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<div style='text-align:justify'><div class="thumbinner" style="width: 850px;"><a href="File:Model1.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/0/07/Model1.jpg" class="thumbimage" height="95%" width="80%"></a></div></div>
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<br>
<br>
 +
 +
<a name="Hyphotesis"></a><h4> <span class="mw-headline"> <b>Hyphotesis of the model</b> </span></h4>
 +
<table class="data">
 +
<tr>
 +
<td>
 +
<div style='text-align:justify'>
 +
<em>
 +
<b>HP<sub>1</sub></b>: In order to  better investigate the range of dynamics of each subparts, every promoter has been
 +
studied with 4 different RBSs, so as to develop more knowledge about the state variables in several configurations
 +
of RBS' efficiency. Hereafter, referring to the notation "RBSx" we mean, respectively,
 +
<a href="http://partsregistry.org/Part:BBa_B0030">RBS30</a>,
 +
<a href="http://partsregistry.org/Part:BBa_B0031">RBS31</a>,
 +
<a href="http://partsregistry.org/Part:BBa_B0032">RBS32</a>,
 +
<a href="http://partsregistry.org/Part:BBa_B0034">RBS34</a>.
 +
<br>
 +
<br>
 +
<b>HP<sub>2</sub></b>: In equation (2) only HSL is considered as inducer, instead of the complex LuxR-HSL.
 +
This is motivated by the fact that our final device offers a constitutive LuxR production due to the upstream constitutive promoter P&lambda. Assuming LuxR is abundant and always saturated in the cytoplasm, we can justify the simplification of attributing pLux promoter i
 +
nduction only by HSL. In conclusion LuxR, LuxI and AiiA were not included in the equation system.
 +
<br>
 +
<br>
 +
<b>HP<sub>3</sub></b>: in system equation, LuxI and AiiA amounts are expressed per cell. For this reason, the whole equation (3), except for the
 +
term of intrinsic degradation of HSL, is multiplied by the number of cells N, due to the property of the lactone to diffuse freely inside/outside bacteria.
 +
<br>
 +
<br>
 +
<b>HP<sub>4</sub></b>: as regards promoters pTet and pLux, we assume their strengths (measured in PoPs),  due to a given concentration of inducer (aTc, HSL for Ptet and Plux respectively), to be
 +
independent from the gene encoding.
 +
In other words, in our hypotesis, if the mRFP coding region is substituted with a region coding for another gene (in our case, AiiA or LuxI), we would obtain the same synthesis rate:
 +
this is the reason why the strength of the complex promoter-RBSx is expressed in Arbitrary Units [AUr].
 +
<br>
 +
<br>
 +
<b>HP<sub>5</sub></b>: considering the exponential growth, the enzymes AiiA and LuxI concentration is supposed to be constant, because their production is equally compensated by dilution.
 +
</em>
 +
</div>
 +
</td>
 +
</tr>
 +
</table>
 +
<br>
 +
<br>
<a name="Equations_1_and_2"></a><h4> <span class="mw-headline"> <b>Equations (1) and (2)</b> </span></h4>
<a name="Equations_1_and_2"></a><h4> <span class="mw-headline"> <b>Equations (1) and (2)</b> </span></h4>
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<div style='text-align:justify'>We have condensed in a unique equation transcription and translation processes. Equations (1) and (2) have identical structure, differing only in the parameters involved.
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<div style='text-align:justify'> Equations (1) and (2) have identical structure, differing only in the parameters involved. They represent the synthesis degradation and diluition of both the enzymes in the circuit, LuxI and AiiA, respectively in the first and second equation: in each of them both transcription and translation processes have been condensed.<font color="red"> The corresponding mathematical formalism is analogous to the one used by Pasotti et al 2011, Suppl. Inf., even if we do not take LuxR-HSL complex formation into account, as explained below.</font><br>
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The first term describes, through Hill's equation formalism, the synthesis rate of the protein of interest (either LuxI or AiiA) depending on the concentration of the inducible protein (anhydrotetracicline -aTc- or HSL respectively). As can be seen in the parameters table (see below),&alpha; refers to the maximum activation of the promoter, &delta; stands for its leakage activity (this means that the promoter is quite induced even if there is no input). In particular, in equation (1), the quite total inhibition of pTet promoter is due to the constitutive production of TetR by our MGZ1 strain, while, in equation (2), Plux is almost repressed in the absence of the complex given by LuxR and HSL.<br>
+
These equations are composed of 2 parts:<br><br>
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In the first term of equation (2) we have described the inducer as being represented only by HSL. This formalism stems from the fact that our final device offers a constitutive production of LuxR (due to the upstream constitutive promoter pLac), so that, assuming it abundant in the cytoplasm, we can derive the semplification of attributing pLux promoter induction only by HSL: this is the reason why we didn' t consider LuxR in the equations system as well as LuxI and AiiA.<br>
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<ol>
-
Furthermore, in both equations (1) and (2) k and &eta; stands respectively for the other parameter of the Hill relationship.
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<li> The first term describes, through Hill's equation formalism, the synthesis rate of the protein of interest (either LuxI or AiiA) depending on the concentration of the inducer (anhydrotetracicline -aTc- or HSL respectively), responsible for the activation of the regulatory element composed of promoter and RBSx. In the parameter table (see below), &alpha; refers to the maximum activation of the promoter, while &delta; stands for its leakage activity (this means that the promoter is slightly active even if there is no induction). In particular, in equation (1), the almost entire inhibition of pTet promoter is given by the constitutive production of TetR by our MGZ1 strain. In equation (2), pLux is almost inactive  in the absence of the complex LuxR-HSL.<br>
-
The second term in equation (1) and (2) is composed of two parts. The first one (&gamma;*LuxI/AiiA) describes with a linear relation the degradation rate per cell of the protein. The second one (&mu;*(Nmax-N)/Nmax)*LuxI/AiiA) takes into account the dilution term and is related to the cell replication process.
+
Furthermore, in both equations k stands for the dissociation constant of the promoter from the inducer (respectively aTc and HSL in eq. 1 and 2), while &eta; is the cooperativity constant.<br><br
 +
<li>The second term in equations (1) and (2) is in turn composed of 2 parts. The former one (<em>&gamma;</em>*LuxI or <em>&gamma;</em>*AiiA respectively) describes, with an exponential decay, the degradation rate per cell of the protein. The latter (&mu;*(Nmax-N)/Nmax)*LuxI or &mu;*(Nmax-N)/Nmax)*AiiA, respectively) takes into account the dilution factor against cell growth which is related to the cell replication process.
 +
</ol>
</div>
</div>
<br>
<br>
 +
 +
<a name="Equation_3"></a><h4> <span class="mw-headline"> <b>Equation (3)</b> </span></h4>
<a name="Equation_3"></a><h4> <span class="mw-headline"> <b>Equation (3)</b> </span></h4>
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<div style='text-align:justify'>The processes described here are not those of transcription and translation, but in principle are enzymatic reactions either related to the production or the degradation of HSL. Based on the experiments performed, we derived Hill's equation in the case of &eta;=1. They cannot be exactly defined Michaelis Menten's equations since that in our formalism, LuxI and AiiA aren't described as enzymes (since they appear also in the denominator). We simply derived empirical formulas relating either LuxI or AiiA to HSL, and treated them with the typical Michaelis Menten formalism since they presented the corresponding sigmoidal shape/switching like behaviour. Regarding to this, we believe that the saturation phenomenon observed either in HSL production rate due to LuxI, or HSL degradation rate due to AiiA, underlies limiting elements in cell metabolism.
+
<div style='text-align:justify'>Here the kinetics of HSL is modeled, through enzymatic reactions either related to the production or the degradation of HSL: based on the experiments performed, we derived appropriate expressions for HSL synthesis and degradation. This equation is composed of 3 parts: <br><br>
-
In the cell HSL binds to LuxR, and two HSL molecules form a tetramer with two complementary LuxR molecules to form a complex which can then activate the promoter Plux.<br>
+
<ol>
-
Intuitively, LuxI activity as an enzyme encounters an intrinsic limit in HSL synthesis depending on the finite and hypothetically fixed substrate concentration (namely SAM and hexanoyl-ACP, see ref.); this means that at a certain LuxI concentration, all the substrate forms activation complexes with LuxI, so that there is no more substrate available for the other LuxI produced. HSL degradation rate is limited by its availability; even if the concentration varies with time, there is always a corresponding limit in AiiA concentration, which determines a saturation in the degradation rate.<br>
+
<li> The first term represents the production of HSL due to LuxI expression. We modeled this process with a saturation curve in which V<sub>max</sub> is the HSL maximum transcription rate, while k<sub>M,LuxI</sub> is the dissociation constant of LuxI from the substrate HSL.
-
Moreover, both the formulas relating either LuxI or AiiA to HSL are multiplied by the number of cells N, due to the property of the lactone to diffuse free inside/outside bacteria.
+
<br><br>
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The third term in equation (3) is similar to the corresponding ones present in the first two equations and describes the intrinsic protein degradation.</div>
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<li> The second term represents the degradation of HSL due to the AiiA expression. Similarly to LuxI, k<sub>cat</sub> represents the maximum degradation per unit of HSL concentration, while k<sub>M,AiiA</sub> is the concentration at which AiiA dependent HSL concentration rate is (k<sub>cat</sub>*HSL)/2. <font color="red"> The formalism is similar to that found in the Supplementary Information of Danino et al, 2010.</font>
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<br>
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<br><br>
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<li> The third term (&gamma;<sub>HSL</sub>*HSL) is similar to the corresponding ones present in the first two equations and describes the intrinsic protein degradation.</div>
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<br><br>
 +
 
 +
 
<a name="Equation_4"></a><h4> <span class="mw-headline"> <b>Equation (4)</b> </span></h4>
<a name="Equation_4"></a><h4> <span class="mw-headline"> <b>Equation (4)</b> </span></h4>
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<div style='text-align:justify'>Equation (4) is the common equation describing logistic cell growth, depending on the rate &mu; and the maximum number N<sub>MAX</sub> of cells per well reachable.</div>
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<div style='text-align:justify'>This is the common logistic population cells growth, depending on the rate &mu; and the maximum number N<sub>max</sub> of cells per well reachable.</div>
<br><br>
<br><br>
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<a name="Table_of_parameters"></a><h2> <span class="mw-headline"> <b>Table of parameters</b> </span></h2>
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<a name="Table_of_parameters"></a><h2> <span class="mw-headline"> <b>Table of parameters and species</b> </span></h2>
<br>
<br>
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<center>
<center>
<table class="data">
<table class="data">
     <tr>
     <tr>
-
       <td class="row"><b>Parameter</b></td>
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       <td class="row"><b>Parameter & Species</b></td>
       <td class="row"><b>Description</b></td>
       <td class="row"><b>Description</b></td>
       <td class="row"><b>Unit of Measurement</b></td>
       <td class="row"><b>Unit of Measurement</b></td>
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   <tr>
   <tr>
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       <td class="row">&alpha;<sub>P<sub>Tet</sub></sub></td>
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       <td class="row">&alpha;<sub>p<sub>Tet</sub></sub></td>
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       <td class="row">maximum transcription rate of Ptet</td>
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       <td class="row">maximum transcription rate of pTet (related to RBSx efficiency)</td>
       <td class="row">[(AUr/min)/cell]</td>
       <td class="row">[(AUr/min)/cell]</td>
       <td class="row">-</td>
       <td class="row">-</td>
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   <tr>
   <tr>
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       <td class="row">&delta;<sub>P<sub>Tet</sub></sub></td>
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       <td class="row">&delta;<sub>p<sub>Tet</sub></sub></td>
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       <td class="row">leakage factor of promoter Ptet basic activity</td>
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       <td class="row">leakage factor of promoter pTet basic activity</td>
       <td class="row">[-]</td>
       <td class="row">[-]</td>
       <td class="row">-</td>
       <td class="row">-</td>
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   <tr>
   <tr>
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       <td class="row">&eta;<sub>P<sub>Tet</sub></sub></td>
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       <td class="row">&eta;<sub>p<sub>Tet</sub></sub></td>
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       <td class="row">Hill coefficient of Ptet</td>
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       <td class="row">Hill coefficient of pTet</td>
       <td class="row">[-]</td>
       <td class="row">[-]</td>
       <td class="row">-</td>
       <td class="row">-</td>
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   <tr>
   <tr>
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       <td class="row">k<sub>P<sub>Tet</sub></sub></td>
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       <td class="row">k<sub>p<sub>Tet</sub></sub></td>
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       <td class="row">dissociation costant of Ptet ? </td>
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       <td class="row">dissociation constant of aTc from pTet</td>
       <td class="row">[nM]</td>
       <td class="row">[nM]</td>
       <td class="row">-</td>
       <td class="row">-</td>
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   <tr>
   <tr>
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       <td class="row">&alpha;<sub>P<sub>Lux</sub></sub></td>
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       <td class="row">&alpha;<sub>p<sub>Lux</sub></sub></td>
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       <td class="row">maximum transcription rate of Plux</td>
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       <td class="row">maximum transcription rate of pLux (related to RBSx efficiency)</td>
       <td class="row">[(AUr/min)/cell]</td>
       <td class="row">[(AUr/min)/cell]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 159: Line 204:
   <tr>
   <tr>
-
       <td class="row">&delta;<sub>P<sub>Lux</sub></sub></td>
+
       <td class="row">&delta;<sub>p<sub>Lux</sub></sub></td>
-
       <td class="row">leakage factor of promoter Plux basic activity</td>
+
       <td class="row">leakage factor of promoter pLux basic activity</td>
       <td class="row">[-]</td>
       <td class="row">[-]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 166: Line 211:
   <tr>
   <tr>
-
       <td class="row">&eta;<sub>P<sub>Lux</sub></sub></td>
+
       <td class="row">&eta;<sub>p<sub>Lux</sub></sub></td>
-
       <td class="row">Hill coefficient of Plux</td>
+
       <td class="row">Hill coefficient of pLux</td>
       <td class="row">[-]</td>
       <td class="row">[-]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 173: Line 218:
   <tr>
   <tr>
-
       <td class="row">k<sub>P<sub>Lux</sub></sub></td>
+
       <td class="row">k<sub>p<sub>Lux</sub></sub></td>
-
       <td class="row">dissociation costant of Plux ?</td>
+
       <td class="row">dissociation constant of HSL from pLux</td>
       <td class="row">[nM]</td>
       <td class="row">[nM]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 180: Line 225:
   <tr>
   <tr>
-
       <td class="row">&gamma;<sub>P<sub>Lux</sub></sub></td>
+
       <td class="row">&gamma;<sub>p<sub>Lux</sub></sub></td>
-
       <td class="row">LuxI costant degradation</td>
+
       <td class="row">LuxI constant degradation</td>
       <td class="row">[1/min]</td>
       <td class="row">[1/min]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 187: Line 232:
   <tr>
   <tr>
       <td class="row">&gamma;<sub>AiiA</sub></td>
       <td class="row">&gamma;<sub>AiiA</sub></td>
-
       <td class="row">AiiA costant degradation</td>
+
       <td class="row">AiiA constant degradation</td>
       <td class="row">[1/min]</td>
       <td class="row">[1/min]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 194: Line 239:
   <tr>
   <tr>
       <td class="row">&gamma;<sub>HSL</sub></td>
       <td class="row">&gamma;<sub>HSL</sub></td>
-
       <td class="row">HSL costant degradation</td>
+
       <td class="row">HSL constant degradation</td>
       <td class="row">[1/min]</td>
       <td class="row">[1/min]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 200: Line 245:
   <tr>
   <tr>
-
       <td class="row">V<sub>max_LuxI</sub></td>
+
       <td class="row">V<sub>max</sub></td>
       <td class="row">maximum transcription rate of LuxI</td>
       <td class="row">maximum transcription rate of LuxI</td>
       <td class="row">[nM/(min*cell)]</td>
       <td class="row">[nM/(min*cell)]</td>
Line 207: Line 252:
   <tr>
   <tr>
-
       <td class="row">k<sub>m_LuxI</sub></td>
+
       <td class="row">k<sub>M,LuxI</sub></td>
-
       <td class="row">dissociation costant ?</td>
+
       <td class="row">dissociation constant of LuxI from HSL</td>
       <td class="row">[AUr/cell]</td>
       <td class="row">[AUr/cell]</td>
       <td class="row">-</td>
       <td class="row">-</td>
   </tr>
   </tr>
   <tr>
   <tr>
-
       <td class="row">k<sub>CAT</sub></td>
+
       <td class="row">k<sub>cat</sub></td>
-
       <td class="row"> ?? </td>
+
       <td class="row">maximum number of enzymatic reactions catalyzed per minute</td>
       <td class="row">[1/(min*cell)]</td>
       <td class="row">[1/(min*cell)]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 220: Line 265:
   <tr>
   <tr>
-
       <td class="row">k<sub>m_AiiA</sub></td>
+
       <td class="row">k<sub>M,AiiA</sub></td>
-
       <td class="row">dissociation costant ?</td>
+
       <td class="row">dissociation constant of AiiA from HSL</td>
       <td class="row">[AUr/cell]</td>
       <td class="row">[AUr/cell]</td>
       <td class="row">-</td>
       <td class="row">-</td>
Line 227: Line 272:
   <tr>
   <tr>
-
       <td class="row">N<sub>MAX</sub></td>
+
       <td class="row">N<sub>max</sub></td>
       <td class="row">maximum number of bacteria per well</td>
       <td class="row">maximum number of bacteria per well</td>
       <td class="row">[cell]</td>
       <td class="row">[cell]</td>
Line 235: Line 280:
   <tr>
   <tr>
       <td class="row">&mu;</td>
       <td class="row">&mu;</td>
-
       <td class="row">rate of bacteria groth</td>
+
       <td class="row">rate of bacteria growth</td>
       <td class="row">[1/min]</td>
       <td class="row">[1/min]</td>
       <td class="row">-</td>
       <td class="row">-</td>
   </tr>
   </tr>
-
</table>
 
-
</center>
 
-
<br><div style='text-align:justify'>According to the table above, the unit of the state variables are:</div><br>
 
-
 
-
<center>
 
-
<table class="data">
 
     <tr>
     <tr>
-
       <td class="row"><b>State variable</b></td>
+
       <td class="row"><b>LuxI</b></td>
-
       <td class="row"><b>Unit of Measurement</b></td>
+
       <td class="row">kinetics of enzyme LuxI</td>
-
    </tr>
+
      <td class="row">[<sup>AUr</sup>&frasl;<sub>cell</sub>]</td>
 +
      <td class="row">-</td>
 +
  </tr>
     <tr>
     <tr>
-
       <td class="row"><sup>d[LuxI]</sup>&frasl;<sub>dt</sub></td>
+
       <td class="row"><b>AiiA</b></td>
-
       <td class="row">[<sup>AUr</sup>&frasl;<sub>(min*cell)</sub>]</td>
+
      <td class="row">kinetics of enzyme AiiA</td>
-
    </tr>
+
       <td class="row">[<sup>AUr</sup>&frasl;<sub>cell</sub>]</td>
 +
      <td class="row">-</td>
 +
  </tr>
     <tr>
     <tr>
-
       <td class="row"><sup>d[AiiA]</sup>&frasl;<sub>dt</sub></td>
+
       <td class="row"><b>HSL</b></td>
-
       <td class="row">[<sup>AUr</sup>&frasl;<sub>(min*cell)</sub>]</td>
+
       <td class="row">kinetics of HSL</b></td>
-
    </tr>
+
-
 
+
-
    <tr>
+
-
      <td class="row"><sup>d[HSL]</sup>&frasl;<sub>dt</sub></td>
+
       <td class="row">[<sup>nM</sup>&frasl;<sub>(min)</sub>]</td>
       <td class="row">[<sup>nM</sup>&frasl;<sub>(min)</sub>]</td>
-
    </tr>
+
      <td class="row">-</td>
 +
  </tr>
     <tr>
     <tr>
-
       <td class="row"><sup>d[N]</sup>&frasl;<sub>dt</sub></td>
+
       <td class="row"><b>N</b></td>
-
       <td class="row">[<sup>cell</sup>&frasl;<sub>(min)</sub>]</td>
+
      <td class="row">number of cells</td>
-
    </tr>
+
       <td class="row">cell</td>
 +
      <td class="row">-</td>
 +
  </tr>
-
</table><br>
+
</table>
 +
</center>
 +
<br>
 +
<br>
-
<a name="Parameter_estimation"></a><h2> <span class="mw-headline"> <b>Parameter estimation</b></span></h2><br>
 
-
<div style='text-align:justify'>In this section we examine the parameters of the model and justify the units of measure, relating them to the experiments performed for the characterization of the parts. We want to underline again our concept of modelling: beginning to caractherize simplier parts, we get their parameters and we try to predict the behaviour of the final engineerd closed-loop.</div>
+
<a name="Parameter_estimation"></a><h2> <span class="mw-headline"> <b>Parameter estimation</b></span></h2>
 +
<div style='text-align:justify'>The philosophy of the model is to predict the behavior of the final closed loop circuit starting from the characterization of single BioBrick parts through a set of well-designed <em>ad hoc</em> experiments. Relating to these, in this section the way parameters of the model have been identified is presented.
 +
As explained before in <a href="#Hypothesis"><span class="toctext"><b><em>HP<sub>1</sub></em></b></span></a>, considering a set of 4 RBS for each subpart expands the range of dynamics and helps us to better understand the interactions between state variables and parameters.
 +
</div>
 +
<br>
-
<a name="Ptet_&_Plux"></a><h4> <span class="mw-headline"> <b>Promoter (Ptet & Plux)</b> </span></h4>
 
-
<div align="center"><div class="thumbinner" style="width: 500px;"><a href="File:Ptet.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/f/f0/Ptet.jpg" class="thumbimage" height="35%" width="50%"></a></div></div> 
 
-
<div style='text-align:justify'>These are the first subparts tested.
+
<a name="Ptet_&_Plux"></a><h4> <span class="mw-headline"> <b>Promoter (PTet & pLux)</b> </span></h4>
-
Firstly, in the figure above "RBSx" stands for, respectively,
+
<div align="center"><div class="thumbinner" style="width: 500px;"><a href="File:Ptet.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/f/f0/Ptet.jpg" class="thumbimage" height="75%" width="60%"></a></div></div> 
-
<a href="http://partsregistry.org/Part:BBa_B0030">RBS30</a>,
+
 
-
<a href="http://partsregistry.org/Part:BBa_B0031">RBS31</a>,
+
<div style='text-align:justify'>These were the first subparts tested.
-
<a href="http://partsregistry.org/Part:BBa_B0032">RBS32</a>,
+
In this phase of the project the target is to learn more about promoter pTet and pLux. Characterizing promoters only is a very hard task: for this reason we considered promoter and each RBS from the RBSx set as a whole (reference to <a href="#Hypothesis"><span class="toctext"><b><em>HP<sub>1</sub></em></b></span></a>).
-
<a href="http://partsregistry.org/Part:BBa_B0034">RBS34</a>. So we get 4 biobricks for each promoter, in order to investigate what happens in different conditions of RBS's efficiency. In this phase of the project we aim to increase our knowledge about promoter Ptet and Plux but it must be said that, here, it' s quite impossible to focus separately on the only activity of the promoter and RBSx; for this reason, when we "characterize promoters", we mean promoter and RBS together.
+
-
We realize this by introducing the mRFP fuorescent protein (followed by a double terminator), and we make the assumption that the number of fluorescent protein produced, due to the concentration of induction (aTc, HSL for Ptet, Plux respectively) is exactly the same as the number given by any other protein that would be expressed instead of the mRFP. In other words, in our hypotesis, if we would substitute the mRFP coding region with a region coding for another protein, we would obtain the same synthesis rate: this is the reason why the strength of the complex promoter-RBSx is expressed in Arbitrary Units [AUr]. Clearly this is a strong hypotesis, however its level of approximation is considered to be adequate.
+
<br>
<br>
-
+
As shown in the figure below, we considered a range of inductions and we monitored, in time, absorbance (O.D. stands for "optical density") and fluorescence; the two vertical segments for each graph highlight the exponential phase of bacterial growth. S<sub>cell</sub> (namely, synthesis rate per cell) can be derived as a function of inducer concentration, thereby providing the desired input-output relation (inducer concentration versus promoter+RBS activity), which was modelled as a Hill curve:
-
Keeping this idea in mind, let's talk about the steps to estimate parameters.<br>
+
-
As shown in the box below, we consider a wide (more or less, depending on the type of test) range of induction and we monitor, during the time, absorbance (line1, line2) and fluorescence (line3); the two vertical segments for each figure highlight the exponential phase of bacteria' s groth. We are able to make these measurement due to the Tecan Infinite F200, spectrophotometer that allows to know the Scell (explained few lines below) as a function of inducer concentration, thereby providing the desired input-output relation (inducer concentration versus promoter+RBS activity), which was modelled as a Hill curve.
+
-
<br>
+
-
After that, we can calculate the <em>Scell</em> as:
+
<div align="center"><div class="thumbinner" style="width: 600px;"><a href="File:Scell.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/5/58/Scell.jpg" class="thumbimage" height="80%" width="45%"></a></div></div>
<div align="center"><div class="thumbinner" style="width: 600px;"><a href="File:Scell.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/5/58/Scell.jpg" class="thumbimage" height="80%" width="45%"></a></div></div>
-
In the end, plotting Scell VS induction, we obtain the activation Hill curve of the promoter considered.
+
 
 +
However, also Relative Promoter Unit (RPU) has been calculated as a ratio of S<sub>cell</sub> of promoter of interest and the S<sub>cell</sub> of <a href="http://partsregistry.org/Part:BBa_J23101">BBa_J23101</a> (reference to <a href="#Hypothesis"><span class="toctext"><b><em>HP<sub>4</sub></em></b></span></a>).
<div style='text-align:justify'><div class="thumbinner" style="width: 600px;"><a href="File:Box1_new.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/7/71/Box1_new.jpg" class="thumbimage" height="100%" width="120%"></a></div></div>
<div style='text-align:justify'><div class="thumbinner" style="width: 600px;"><a href="File:Box1_new.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/7/71/Box1_new.jpg" class="thumbimage" height="100%" width="120%"></a></div></div>
-
As shown in the box above, &alpha; as already mentioned, represent the protein maximum synthesis rate, which is reached, in accordance with Hill's formalism, when the inducer concentration tends to infinite, and, more practically, for sufficently high concentrations of inducer, meanwhile the product &alpha;*&delta; stands for the leakage activity (induction=0ng/&micro;L), liable for protein production (LuxI and AiiA respectively) even in the absence of autoinducer. The paramenter &eta; is the Hill's cooperativity constant and it  affects the rapidity and ripidity of the switch like curve relating Scell with the concentration of inducer.
+
As shown in the figure above, &alpha;, as already mentioned, represents the protein maximum synthesis rate, which is reached, in accordance with Hill's formalism, when the inducer concentration tends to infinite, and, for sufficently high concentrations of inducer. Meanwhile the product &alpha;*&delta; stands for the leakage activity (at no induction), liable for protein production (LuxI and AiiA respectively) even in the absence of inducer. The paramenter &eta; is the Hill's cooperativity constant and it  affects the rapidity and ripidity of the switch like curve relating S<sub>cell</sub> with the concentration of inducer.
-
Lastly, k stands for the semi-saturation constant and, in case of a unity value for &eta;, it indicates the concentration of substrate at which half the synthesis rate is achieved.
+
Lastly, k stands for the semi-saturation constant and, in case of &eta;=1, it indicates the concentration of substrate at which half the synthesis rate is achieved.
-
The unities of the various parameters can be easily derived considering the hill equation and the unity of its left handed side (for more details see the <a href="#Table_of_parameters"><span class="toctext">Table of parameters</span></a> above). <br> <br>
+
<br>
 +
<br>
-
<a name="AiiA"></a><h4> <span class="mw-headline"> <b>AiiA</b> </span></h4>
 
-
<div align="center"><div class="thumbinner" style="width: 500px;"><a href="File:AiiA.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/3/3e/AiiA.jpg" class="thumbimage" height="26%" width="50%"></a></div></div>
 
-
<div style='text-align:justify'> These experiments aims to learn approximately the degradation rate of HSL due to the expression of AiiA. In these case, we are able to quantify exactly the concentration of HSL, using the well-characterized part <a href="http://partsregistry.org/Part:BBa_T9002">BBa_T9002</a> in the previous iGEM.
 
-
<div align="center"><div class="thumbinner" style="width: 500px;"><a href="File:T9002.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/c/c2/T9002.jpg" class="thumbimage" height="100%" width="110%"></a></div></div>
 
-
This biobrick receives in input HSL concentration, and returns in output the intensity of fluorescence.
 
-
So, our idea is to control the degradation of HSL reading the fluorescence of T9002 due to a certain concentration of HSL; monitoring it in precise samples of time since aTc induction (after having waited enough for AiiA to become in stationary phase), we can estimate the degradation rate, also compared with other constructs, which would't degradate it. According to this, it' s necessary to know very well the reationship input-output of the biosensor: a curve of "calibration" of T9002 is obtain for each test performed, even if, in theory, it should be always the same.
 
-
Summarizing in few points, the following are the passes involved in the experiment:
 
-
<ol><li>Transform a MGZ1 E. coli strain with the pTet-RBS-AiiA-TT construct, and wait three hours for reaching the exponential phase growth.</li>
 
-
<li>Induce the culture with a proper amount of aTc.</li>
 
-
<li>Take samples of the supernatant at different times (i.e. 0 h,1 h,4 h) and store them in the freezer at -20°C</li>
 
-
<li>Retrieve the supernatants prepared and use them to induce the T9002 construct contained in the TECAN spectrophotometer wells</li>
 
-
<li>Wait until sensing is completed and retrieve the results from TECAN.</li></ol>
 
-
<div style='text-align:justify'><div class="thumbinner" style="width: 500px;"><a href="" class="image"><img alt="File:Degradation.jpg" src="https://static.igem.org/mediawiki/2011/9/99/Degradation.jpg" class="thumbimage" height="90%" width="140%"></a></div></div><br><br>
+
<a name="Enzymes"></a><h4> <span class="mw-headline"> <b>AiiA & LuxI</b> </span></h4>
 +
<div style='text-align:justify'> This paragraph explains how parameters of equation (3) are estimated. The target is to learn the AiiA and LuxI degradation and production mechanisms in addition to HSL intrinsic degradation, in order to estimate V<sub>max</sub>, k<sub>M,LuxI</sub>, k<sub>cat</sub> and k<sub>M,AiiA</sub> parameters. These tests have been performed using the following BioBrick parts:
 +
</div>
 +
 
 +
<div align="center"><div class="thumbinner" style="width: 500px;"><a href="File:AiiA.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/3/3e/AiiA.jpg" class="thumbimage" height="75%" width="60%"></a></div></div>
 +
 
 +
<div style='text-align:justify'>By now, parameter identification about promoters has already been performed. Furthermore, as explained before, the <a href="#Hypothesis"><span class="toctext"><b><em>HP<sub>4</sub></em></b></span></a> is also valid in this case. Moreover, it's possible to quantify exactly the concentration of HSL, using the well-characterized BioBrick <a href="http://partsregistry.org/Part:BBa_T9002">BBa_T9002</a>.
 +
<div align="center"><div class="thumbinner" style="width: 500px;"><a href="File:T9002.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/c/c2/T9002.jpg" class="thumbimage" height="80%" width="110%"></a></div></div>
 +
This is a biosensor which receives HSL concentration as input and returns GFP intensity (more precisely S<sub>cell</sub>) as output.<font color="red"> (Canton et al, 2008).</font>
 +
According to this, it is necessary to understand the input-output relationship: so, a T9002 "calibration" curve is plotted for each test performed.<br><br>
 +
So, our idea is to control the degradation of HSL in time. ATc activates pTet and, later, a certain concentration of HSL is introduced. Then, at fixed times, O.D.<sub>600</sub> and HSL concentration are monitored using Tecan and T9002 biosensor.
 +
 +
 
 +
<div style='text-align:justify'><div class="thumbinner" style="width: 500px;"><a href="" class="image"><img alt="File:Degradation.jpg" src="https://static.igem.org/mediawiki/2011/9/99/Degradation.jpg" class="thumbimage" height="65%" width="140%"></a></div></div>
 +
Referring to <a href="#Hypothesis"><span class="toctext"><b><em>HP<sub>5</sub></em></b></span></a>, in exponential growth enzymes equilibrium is conserved.
 +
Due to a known induction of aTc, the steady-state level per cell can be calculated:
-
<a name="LuxI"></a><h4> <span class="mw-headline"> <b>LuxI</b> </span></h4>
+
<div style='text-align:justify'><div class="thumbinner" style="width: 500px;"><a href="File:Aiia_cost.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/7/74/Aiia_cost.jpg" class="thumbimage" height="70%" width="120%"></a></div></div>
 +
Considering, for a determined promoter-RBSx couple, several induction of aTc and, for each of them, several samples of HSL concentration during time, parameters V<sub>max</sub>, k<sub>M,LuxI</sub>, k<sub>cat</sub> and k<sub>M,AiiA</sub> can be estimated, through numerous iterations of an algorithm implemented in MATLAB.
<br>
<br>
-
<a name="Simulations"></a><h1><span class="mw-headline"> <b>Simulations</b> </span></h1>
 
<br>
<br>
 +
 +
 +
<a name="N"></a><h4> <span class="mw-headline"> <b>N</b> </span></h4>
 +
<div style='text-align:justify'>The parameters N<sub>max</sub> and μ can be calculated from the analysis of the OD<sub>600</sub> produced by our MGZ1 culture. In particular, μ is derived as the slope of the log(O.D.<sub>600</sub>) growth curve. Counting the number of cells of a saturated culture would be considerably complicated, so N<sub>max</sub> is determined with a proper procedure. The aim here is to derive the linear proportional coefficient &Theta; between O.D'.<sub>600</sub> and N: this constant can be estimated as the ratio between absorbance (read from TECAN) and the respective number of CFU on a petri plate. Finally, N<sub>max</sub> is calcultated as &Theta;*O.D'.<sub>600</sub>.
 +
<font color="red">(Pasotti et al, 2010)</font>.
 +
</div>
 +
<br>
 +
<br>
 +
 +
 +
<a name="Degradation_rates"></a><h4> <span class="mw-headline"> <b>Degradation rates</b> </span></h4>
 +
<div style='text-align:justify'>The parameters &gamma;<sub>LuxI</sub> and &gamma;<sub>AiiA</sub> are taken from literature since they contain LVA tag for rapid degradation. Instead, approximating HSL kinetics as a decaying exponential, &gamma;<sub>HSL</sub> can be derived as the slope of the log(concentration), which can be monitored through <a href="http://partsregistry.org/Part:BBa_T9002">BBa_T9002</a>.
 +
</div>
 +
<br>
 +
<br>
 +
 +
 +
<a name="Simulations"></a><h1><span class="mw-headline"> <b>Simulations</b> </span></h1>
 +
<div style='text-align:justify'>
 +
On a biological level, the ability to control the concentration of a given molecule reveals itself as fundamental in limiting the metabolic burden of the cell; moreover, in the particular case of HSL signalling molecules, this would give the possibility to regulate quorum sensing-based population behaviours. In this section we first present the results of the simulations of the closed-loop circuit for feasible values of the parameters. The reported figures highlight some fundamental characteristics.</div>
 +
<div style='text-align:justify'> First of all, it is clear the validity of the steady state approximation in the exponential growth phase, since that LuxI, AiiA, and also HSL, undergo only minor changes in this phase (500>t<2500 min). Secondly, it can be noted that the circuit negative feedback rapidly activates above a proper amount of HSL, and after that it competes with LuxI synthesis term in defining HSL steady state value.
 +
</div>
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 +
<table align='center' width='100%'>
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<div style='text-align:center'><div class="thumbinner" style="width: 100%;"><a href="File:LuxI AiiA time course.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/c/cd/LuxI_AiiA_time_course.jpg" class="thumbimage" width="80%"></a></div></div>
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</table>
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<table align='center' width='100%'>
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<div style='text-align:center'><div class="thumbinner" style="width: 100%;"><a href="File:HSL time course.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/1/15/HSL_time_course.jpg" class="thumbimage" width="80%"></a></div></div>
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</table>
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<p>The concept of the closed-loop model we have discussed so far can be validated by the comparison with another circuit we implemented in Matlab, that is an open loop circuit, similar to CTRL+E, except for the constitutive production of AiiA. We can point out that, under the hypothesis of an equal amount of HSL production, the open-loop circuit requires a higher AiiA production level, thereby constituting a greater metabolic burden for the cell (see figure below), uncertain to be fulfilled in realistic conditions. Moreover, there is  another major issue with the open loop circuit, that is the inability to monitor the output of the controlled system, so that it is not generally capable to adapt to changes in the system behavior.</p>
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 +
<table align='center' width='100%'>
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<div style='text-align:center'><div class="thumbinner" style="width: 100%;"><a href="File:UNIPV AiiA open loop VS closed loop.jpg" class="image"><img alt="" src="https://static.igem.org/mediawiki/2011/9/96/UNIPV_AiiA_open_loop_VS_closed_loop.jpg" class="thumbimage" width="80%"></a></div></div>
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</table>
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<a name="References"></a><h1><span class="mw-headline"> <b>References</b> </span></h1>
<a name="References"></a><h1><span class="mw-headline"> <b>References</b> </span></h1>
 +
<div style='text-align:justify'>
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D. Braun, S. Basu, R. Weiss, "Parameter Estimation for Two Synthetic Gene Networks: a Case Study", ICASSP 2005, vol. 5, v/769 - v/772.<br><br>
 +
 +
B. Canton, A. Labno and D. Endy, "Refinement and Standardization of Synthetic Biological Parts and Devices", Volume 26, Number 7, July 2008.</div><br><br>
 +
 +
T. Danino, O. Mondragon-Palomino, L. Tsimring & J. Hasty, "A Synchronized Quorum of Genetic Clocks", Nature vol. 463, pp. 326-330, January 2010.<br><br>
 +
 +
L. Endler, N. Rodriguez, N. Juty, V. Chelliah, C. Laibe, C. Li and N. Le Novere, "Designing and Encoding Models for Synthetic Biology", Journal of the Royal Society, 2009 Aug 6;6 Suppl 4:S405-17. Epub 2009 Apr 1.<br><br>
 +
 +
L. Pasotti, M. Quattrocelli, D. Galli, M.G. Cusella De Angelis, P. Magni, "Multiplexing and Demultiplexing Logic Functions for Computing Signal Processing Tasks in Synthetic Biology", Biotechnology Journal, Volume 6,pp. 784-795, 2011.<br><br>
 +
 +
L. Pasotti, M. Quattrocelli, D. Galli, M.G. Cusella De Angelis, P. Magni, "Multiplexing and Demultiplexing Logic Functions for Computing Signal Processing Tasks in Synthetic Biology, Supporting Information", Biotechnology Journal, Volume 6,available online, 2011.
</div>
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Latest revision as of 10:23, 21 September 2011

UNIPV TEAM 2011

CTRL + E

Signalling is nothing without control...


Contents



Mathematical modelling: introduction

Mathematical modelling plays nowadays a central role in Synthetic Biology, due to its ability to serve as a crucial link between the concept and realization of a biological circuit: what we propose in this page is a modelling approach to our project, which has proven extremely useful and very helpful before and after the "wet lab".
Thus, immediately at the beginning, when there was little knowledge, a mathematical model based on a system of differential equations was derived and implemented using a set of parameters, to validate the feasibility of the project. Once this became clear, starting from the characterization of the single subparts created in the wet lab, some of the parameters of the mathematical model were estimated (the others are known from literature) and they have been fixed to simulate the same model, in order to predict the final behaviour of the whole engineered closed-loop circuit. This approach is consistent with the typical one adopted for the analysis and synthesis of a biological circuit, as exemplified by Pasotti et al 2011.

Therefore here, after a brief overview about the advantages that modelling engineered circuits can bring, we deeply analyze the system of equation formulas, underlining the role and function of the parameters involved.
Experimental procedures for parameter estimation are discussed and, finally, a different type of circuit is presented. Simulations were performed, using ODEs with MATLAB and used to explain the difference between a closed-loop control system model and an open one.


The importance of mathematical modelling

The purposes of deriving mathematical models for gene networks can be:

  • Prediction: in the initial steps of the project, a good a-priori identification "in silico" allows to suppose the kinetics of the enzymes (AiiA, Luxi) and HSL involved in our gene network, basically to understand if the complex circuit structure and functioning could be achievable and to investigate the range of parameters values ​​for which the behavior is the one expected. (Endler et al, 2009)

  • Parameter identification: a modellistic approach is helpful to get all the parameters involved, in order to perform realistic simulations not only of the single subparts created, but also of the whole final circuit, according to the a-posteriori identification.

  • Modularity: studying and characterizing basic BioBrick Parts can allow to reuse this knowledge in other studies, concerning with the same basic modules (Braun et al, 2005; Canton et al, 2008).


  • Equations for gene networks




    Hyphotesis of the model

    HP1: In order to better investigate the range of dynamics of each subparts, every promoter has been studied with 4 different RBSs, so as to develop more knowledge about the state variables in several configurations of RBS' efficiency. Hereafter, referring to the notation "RBSx" we mean, respectively, RBS30, RBS31, RBS32, RBS34.

    HP2: In equation (2) only HSL is considered as inducer, instead of the complex LuxR-HSL. This is motivated by the fact that our final device offers a constitutive LuxR production due to the upstream constitutive promoter P&lambda. Assuming LuxR is abundant and always saturated in the cytoplasm, we can justify the simplification of attributing pLux promoter i nduction only by HSL. In conclusion LuxR, LuxI and AiiA were not included in the equation system.

    HP3: in system equation, LuxI and AiiA amounts are expressed per cell. For this reason, the whole equation (3), except for the term of intrinsic degradation of HSL, is multiplied by the number of cells N, due to the property of the lactone to diffuse freely inside/outside bacteria.

    HP4: as regards promoters pTet and pLux, we assume their strengths (measured in PoPs), due to a given concentration of inducer (aTc, HSL for Ptet and Plux respectively), to be independent from the gene encoding. In other words, in our hypotesis, if the mRFP coding region is substituted with a region coding for another gene (in our case, AiiA or LuxI), we would obtain the same synthesis rate: this is the reason why the strength of the complex promoter-RBSx is expressed in Arbitrary Units [AUr].

    HP5: considering the exponential growth, the enzymes AiiA and LuxI concentration is supposed to be constant, because their production is equally compensated by dilution.


    Equations (1) and (2)

    Equations (1) and (2) have identical structure, differing only in the parameters involved. They represent the synthesis degradation and diluition of both the enzymes in the circuit, LuxI and AiiA, respectively in the first and second equation: in each of them both transcription and translation processes have been condensed. The corresponding mathematical formalism is analogous to the one used by Pasotti et al 2011, Suppl. Inf., even if we do not take LuxR-HSL complex formation into account, as explained below.
    These equations are composed of 2 parts:

    1. The first term describes, through Hill's equation formalism, the synthesis rate of the protein of interest (either LuxI or AiiA) depending on the concentration of the inducer (anhydrotetracicline -aTc- or HSL respectively), responsible for the activation of the regulatory element composed of promoter and RBSx. In the parameter table (see below), α refers to the maximum activation of the promoter, while δ stands for its leakage activity (this means that the promoter is slightly active even if there is no induction). In particular, in equation (1), the almost entire inhibition of pTet promoter is given by the constitutive production of TetR by our MGZ1 strain. In equation (2), pLux is almost inactive in the absence of the complex LuxR-HSL.
      Furthermore, in both equations k stands for the dissociation constant of the promoter from the inducer (respectively aTc and HSL in eq. 1 and 2), while η is the cooperativity constant.

      The second term in equations (1) and (2) is in turn composed of 2 parts. The former one (γ*LuxI or γ*AiiA respectively) describes, with an exponential decay, the degradation rate per cell of the protein. The latter (μ*(Nmax-N)/Nmax)*LuxI or μ*(Nmax-N)/Nmax)*AiiA, respectively) takes into account the dilution factor against cell growth which is related to the cell replication process.

    Equation (3)

    Here the kinetics of HSL is modeled, through enzymatic reactions either related to the production or the degradation of HSL: based on the experiments performed, we derived appropriate expressions for HSL synthesis and degradation. This equation is composed of 3 parts:

    1. The first term represents the production of HSL due to LuxI expression. We modeled this process with a saturation curve in which Vmax is the HSL maximum transcription rate, while kM,LuxI is the dissociation constant of LuxI from the substrate HSL.

    2. The second term represents the degradation of HSL due to the AiiA expression. Similarly to LuxI, kcat represents the maximum degradation per unit of HSL concentration, while kM,AiiA is the concentration at which AiiA dependent HSL concentration rate is (kcat*HSL)/2. The formalism is similar to that found in the Supplementary Information of Danino et al, 2010.

    3. The third term (γHSL*HSL) is similar to the corresponding ones present in the first two equations and describes the intrinsic protein degradation.


    Equation (4)

    This is the common logistic population cells growth, depending on the rate μ and the maximum number Nmax of cells per well reachable.


    Table of parameters and species


    Parameter & Species Description Unit of Measurement Value
    αpTet maximum transcription rate of pTet (related to RBSx efficiency) [(AUr/min)/cell] -
    δpTet leakage factor of promoter pTet basic activity [-] -
    ηpTet Hill coefficient of pTet [-] -
    kpTet dissociation constant of aTc from pTet [nM] -
    αpLux maximum transcription rate of pLux (related to RBSx efficiency) [(AUr/min)/cell] -
    δpLux leakage factor of promoter pLux basic activity [-] -
    ηpLux Hill coefficient of pLux [-] -
    kpLux dissociation constant of HSL from pLux [nM] -
    γpLux LuxI constant degradation [1/min] -
    γAiiA AiiA constant degradation [1/min] -
    γHSL HSL constant degradation [1/min] -
    Vmax maximum transcription rate of LuxI [nM/(min*cell)] -
    kM,LuxI dissociation constant of LuxI from HSL [AUr/cell] -
    kcat maximum number of enzymatic reactions catalyzed per minute [1/(min*cell)] -
    kM,AiiA dissociation constant of AiiA from HSL [AUr/cell] -
    Nmax maximum number of bacteria per well [cell] -
    μ rate of bacteria growth [1/min] -
    LuxI kinetics of enzyme LuxI [AUrcell] -
    AiiA kinetics of enzyme AiiA [AUrcell] -
    HSL kinetics of HSL [nM(min)] -
    N number of cells cell -


    Parameter estimation

    The philosophy of the model is to predict the behavior of the final closed loop circuit starting from the characterization of single BioBrick parts through a set of well-designed ad hoc experiments. Relating to these, in this section the way parameters of the model have been identified is presented. As explained before in HP1, considering a set of 4 RBS for each subpart expands the range of dynamics and helps us to better understand the interactions between state variables and parameters.

    Promoter (PTet & pLux)

    These were the first subparts tested. In this phase of the project the target is to learn more about promoter pTet and pLux. Characterizing promoters only is a very hard task: for this reason we considered promoter and each RBS from the RBSx set as a whole (reference to HP1).
    As shown in the figure below, we considered a range of inductions and we monitored, in time, absorbance (O.D. stands for "optical density") and fluorescence; the two vertical segments for each graph highlight the exponential phase of bacterial growth. Scell (namely, synthesis rate per cell) can be derived as a function of inducer concentration, thereby providing the desired input-output relation (inducer concentration versus promoter+RBS activity), which was modelled as a Hill curve:
    However, also Relative Promoter Unit (RPU) has been calculated as a ratio of Scell of promoter of interest and the Scell of BBa_J23101 (reference to HP4).
    As shown in the figure above, α, as already mentioned, represents the protein maximum synthesis rate, which is reached, in accordance with Hill's formalism, when the inducer concentration tends to infinite, and, for sufficently high concentrations of inducer. Meanwhile the product α*δ stands for the leakage activity (at no induction), liable for protein production (LuxI and AiiA respectively) even in the absence of inducer. The paramenter η is the Hill's cooperativity constant and it affects the rapidity and ripidity of the switch like curve relating Scell with the concentration of inducer. Lastly, k stands for the semi-saturation constant and, in case of η=1, it indicates the concentration of substrate at which half the synthesis rate is achieved.

    AiiA & LuxI

    This paragraph explains how parameters of equation (3) are estimated. The target is to learn the AiiA and LuxI degradation and production mechanisms in addition to HSL intrinsic degradation, in order to estimate Vmax, kM,LuxI, kcat and kM,AiiA parameters. These tests have been performed using the following BioBrick parts:
    By now, parameter identification about promoters has already been performed. Furthermore, as explained before, the HP4 is also valid in this case. Moreover, it's possible to quantify exactly the concentration of HSL, using the well-characterized BioBrick BBa_T9002.
    This is a biosensor which receives HSL concentration as input and returns GFP intensity (more precisely Scell) as output. (Canton et al, 2008). According to this, it is necessary to understand the input-output relationship: so, a T9002 "calibration" curve is plotted for each test performed.

    So, our idea is to control the degradation of HSL in time. ATc activates pTet and, later, a certain concentration of HSL is introduced. Then, at fixed times, O.D.600 and HSL concentration are monitored using Tecan and T9002 biosensor.
    File:Degradation.jpg
    Referring to HP5, in exponential growth enzymes equilibrium is conserved. Due to a known induction of aTc, the steady-state level per cell can be calculated:
    Considering, for a determined promoter-RBSx couple, several induction of aTc and, for each of them, several samples of HSL concentration during time, parameters Vmax, kM,LuxI, kcat and kM,AiiA can be estimated, through numerous iterations of an algorithm implemented in MATLAB.

    N

    The parameters Nmax and μ can be calculated from the analysis of the OD600 produced by our MGZ1 culture. In particular, μ is derived as the slope of the log(O.D.600) growth curve. Counting the number of cells of a saturated culture would be considerably complicated, so Nmax is determined with a proper procedure. The aim here is to derive the linear proportional coefficient Θ between O.D'.600 and N: this constant can be estimated as the ratio between absorbance (read from TECAN) and the respective number of CFU on a petri plate. Finally, Nmax is calcultated as Θ*O.D'.600. (Pasotti et al, 2010).


    Degradation rates

    The parameters γLuxI and γAiiA are taken from literature since they contain LVA tag for rapid degradation. Instead, approximating HSL kinetics as a decaying exponential, γHSL can be derived as the slope of the log(concentration), which can be monitored through BBa_T9002.


    Simulations

    On a biological level, the ability to control the concentration of a given molecule reveals itself as fundamental in limiting the metabolic burden of the cell; moreover, in the particular case of HSL signalling molecules, this would give the possibility to regulate quorum sensing-based population behaviours. In this section we first present the results of the simulations of the closed-loop circuit for feasible values of the parameters. The reported figures highlight some fundamental characteristics.
    First of all, it is clear the validity of the steady state approximation in the exponential growth phase, since that LuxI, AiiA, and also HSL, undergo only minor changes in this phase (500>t<2500 min). Secondly, it can be noted that the circuit negative feedback rapidly activates above a proper amount of HSL, and after that it competes with LuxI synthesis term in defining HSL steady state value.

    The concept of the closed-loop model we have discussed so far can be validated by the comparison with another circuit we implemented in Matlab, that is an open loop circuit, similar to CTRL+E, except for the constitutive production of AiiA. We can point out that, under the hypothesis of an equal amount of HSL production, the open-loop circuit requires a higher AiiA production level, thereby constituting a greater metabolic burden for the cell (see figure below), uncertain to be fulfilled in realistic conditions. Moreover, there is another major issue with the open loop circuit, that is the inability to monitor the output of the controlled system, so that it is not generally capable to adapt to changes in the system behavior.

    References

    D. Braun, S. Basu, R. Weiss, "Parameter Estimation for Two Synthetic Gene Networks: a Case Study", ICASSP 2005, vol. 5, v/769 - v/772.

    B. Canton, A. Labno and D. Endy, "Refinement and Standardization of Synthetic Biological Parts and Devices", Volume 26, Number 7, July 2008.


    T. Danino, O. Mondragon-Palomino, L. Tsimring & J. Hasty, "A Synchronized Quorum of Genetic Clocks", Nature vol. 463, pp. 326-330, January 2010.

    L. Endler, N. Rodriguez, N. Juty, V. Chelliah, C. Laibe, C. Li and N. Le Novere, "Designing and Encoding Models for Synthetic Biology", Journal of the Royal Society, 2009 Aug 6;6 Suppl 4:S405-17. Epub 2009 Apr 1.

    L. Pasotti, M. Quattrocelli, D. Galli, M.G. Cusella De Angelis, P. Magni, "Multiplexing and Demultiplexing Logic Functions for Computing Signal Processing Tasks in Synthetic Biology", Biotechnology Journal, Volume 6,pp. 784-795, 2011.

    L. Pasotti, M. Quattrocelli, D. Galli, M.G. Cusella De Angelis, P. Magni, "Multiplexing and Demultiplexing Logic Functions for Computing Signal Processing Tasks in Synthetic Biology, Supporting Information", Biotechnology Journal, Volume 6,available online, 2011.

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