From 2014.igem.org

This is a polymerase derived from Hepatitis C Virus Strain 1b isolate Con1 which catalyses the replication of RNA from an RNA template, reffered to as NS5B in the contact of the HCV genome. Heterelogous expression of NS5B has been achieved in insect and bacterial hosts, with RNA-dependent RNA synthesis initiated de novo (Behrens et al., 1996; Lohmann et al., 1997). Structural studies indicate the hydrophobic C-terminal 21 amino acid residues cause insertion into the membrane with other intracellular protein-protein interactions implicated (Moradpour et al., 2004) making the final 63 bases essential for HCV RNA replication in eukaryotic cells (Moradpour et al., 2004). In prokaryotic cells the final 21 amino acids are expendable. RdRp initiates viral RNA synthesis with nucleotidyl transfer activity found within palm motifs A and C, with several amino acid residues implicated in nucleotide triphosphate contact (Bressanelli et al., 2002). NS5B activity has been demonstrated ''in vitro'', with synthesis of full length HCV RNA (Lohmann et al., 1997; Ferrari et al., 1999). 5’ and 3’ untranslated regions (UTRs) of the HCV genome contains ordered RNA structures, which are evolutionary conserved and contain crucial cis-acting elements for viral RNA replication. 150 nt in the 3’ termini of HCV RNA contains elements which are essential for RdRp binding and replication of viral RNA (Cheng et al., 1999; Yi and Lemon, 2003).

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              <div id = "pageContent">
              <!-- THIS IS WHERE YOUR MAIN BODY GOES -->
-             <h1> MODELLING </h1> <br> <br>
+             <h1> RdRp </h1> <br> <br>
-<p> Our modelling in this project has several aims: </p>
+<p>This is a polymerase derived from Hepatitis C Virus Strain
-<ul type="circle">
- <li>To find the amount of DPP-IV reduction reached when the system reaches equilibrium</li>
- <li>To find a way to control the level of DPP-IV reduction</li>
- <li>To find the minimum number of RdRps, replicons, etc to be initially transfected into the cell, which are required to achieve a steady state for the system</li>
- <li>To find out how long does it take for the system to reach equilibrium</li>
- <li>To find out the level of reduction we need to treat diabetes</li>
- <li>To find out how stable the system is (i.e. will the system only work in very specific situations, or in lots of different systems?)
-</ul>
-<p> We are currently using Simbiology in Matlab and Copasi to model the system. We are currently adapting several different models, which come from research into HCV replicons, to our system. If our models can be made to fit our experiments well, we may extend our project to try and find a way to control the level of DPP-IV which is reduced. In addition modelling the system will allow it to be better optimised in the future, and optimum values for constants such as the strength of the ribosome binding sites, and the number of siRNAs produced by each degradation, so that the effect of our biobrick can be optimised. </p>
-<p> We are currently using Simbiology in Matlab and Copasi to model the system. We are currently adapting several different models, which come from research into HCV replicons, to our system. If our models can be made to fit our experiments well, we may extend our project to try and find a way to control the level of DPP-IV which is reduced. In addition modelling the system will allow it to be better optimised in the future, and optimum values for constants such as the strength of the ribosome binding sites, and the number of siRNAs produced by each degradation, so that the effect of our biobrick can be optimised. </p>
-<p> Initially we determined that our system should reach some equilibrium after a certain amount of time. This is because firstly, HCV is a successful virus, so the replicons should not completely degrade away as time goes to infinity.  Secondly, since there are only a finite amount of resources within the cell, the number of replicons in the system cannot keep increasing forever. This means either the number of replicons must tend towards a certain constant (constant with respect to time), or the number of replicons should tend towards oscillations. </p>
+b isolate Con1 which catalyses the replication of RNA from an RNA template, reffered to as NS5B in
-<p>
+the contact of the HCV genome. Heterelogous expression of NS5B has been achieved in insect and
-        \begin{eqnarray}
-	\label{system1}
+bacterial hosts, with RNA-dependent RNA synthesis initiated de novo (Behrens et al., 1996; Lohmann
-	\frac{dm}{dt} &amp;=&amp; \alpha_m - \beta_m m - k_s ms
-\\	\label{system2}
+et al., 1997). Structural studies indicate the hydrophobic C-terminal 21 amino acid residues cause
-\frac{ds}{dt} &amp;=&amp; \alpha_s - \beta_s s - p_s k_s ms - k_r sr
-\\	\label{system3}
+insertion into the membrane with other intracellular protein-protein interactions implicated (Moradpour
-\frac{dr}{dt} &amp;=&amp; \alpha_r - \beta_r r - p_r k_r sr
-\end{eqnarray}
+et al., 2004) making the final 63 bases essential for HCV RNA replication in eukaryotic cells
-</p>
+(Moradpour et al., 2004). In prokaryotic cells the final 21 amino acids are expendable. RdRp initiates
+viral RNA synthesis with nucleotidyl transfer activity found within palm motifs A and C, with several
+amino acid residues implicated in nucleotide triphosphate contact (Bressanelli et al., 2002). NS5B
+activity has been demonstrated ''in vitro'', with synthesis of full length HCV RNA (Lohmann et al.,
+; Ferrari et al., 1999). 5’ and 3’ untranslated regions (UTRs) of the HCV genome contains
+ordered RNA structures, which are evolutionary conserved and contain crucial cis-acting elements for
+viral RNA replication. 150 nt in the 3’ termini of HCV RNA contains elements which are essential for
+RdRp binding and replication of viral RNA (Cheng et al., 1999; Yi and Lemon, 2003).</p>
+<h2> Click <a href="http://parts.igem.org/wiki/index.php?title=Part:BBa_K1442100">here</a> to learn about our RdRp. </h2>
+<h2> Click <a href=" http://parts.igem.org/wiki/index.php?title=Part:BBa_K1442101">here</a> to learn about our mutant RdRp. </h2>
 </div>

Team:Warwick/Parts/RdRp

From 2014.igem.org

Revision as of 23:53, 16 October 2014

RdRp

Click here to learn about our RdRp.

Click here to learn about our mutant RdRp.