Template:Team:Bonn:NetworkData

Revision as of 18:29, 1 October 2013 (view source)

Maria1708 (Talk | contribs)

← Older edit

Revision as of 18:32, 1 October 2013 (view source)

Leonievb (Talk | contribs)

Newer edit →

Line 177:

case 13:

-

content.i = 13;

content.parents=[12];

-

content.~~childs~~=[];

+

content.titleShort = "ClpXP protease";

-

content.~~titleShort~~ = "~~Ec.~~ ClpXP";

+

content.summary= "The ClpXP protein complex is an AAA+ protease, which means that it uses the energy of ATP hydrolysis to unfold and degenerate marked proteins.";

-

content.~~titleLong~~ = "";

+

content.text= "<b> Introduction: </b> </br>The ClpXP protein complex is an AAA+ protease, which means that it uses the energy of ATP hydrolysis to unfold and degenerate marked proteins. The genetic code of this complex is highly conserved and can be found in human cells as well as in the bacteria Escherichia coli. The degradation system was discovered in the early 1990's and is now well established <sup><a href="#13.1">[13.1]</a></sup>.In our project, we used ClpXP to degrade specific proteins in order to control their amount and effect. Therefor, we utilized the common adaptor sspB.This protein recognizes substrates tagged with ssrA . In order to have a better control, we actually made use of a sspB split system. For more detailed information about the ClpXP degradation system in our project go to ClpXP general. </br> </br> <b> Structure: </b> </br> The ClpXP complex consists of two functional and structural different parts. The ClpX protein, an ATPase, is a hexameric ring (Fig.1) with a pore in the center<div align='left'><img src='https://static.igem.org/mediawiki/2013/9/98/Bonn_Clp_Fig1.jpg' height='348' width='320'>Fig. 1: the hexameric ring of ClpX, each color represents a subunit, from 'ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554'</div> </br> Each subunit contains a N-terminal domain (Fig.2, B), which assumes the adaptor recognition and is stabilized by coordinated zinc atoms.However, the important part of a subunit is the AAA+ module (Fig.2, C), divided in a large and a small domain. <div align='left'><img src='https://static.igem.org/mediawiki/2013/d/d0/BonnClp_Fig2.jpg' height='262' width='499'>Fig. 2: structure of a ClpX subunit, B: the N-terminal domain with brown zinc atoms, C: the AAA+ module, from 'ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554'</div> </br> Between these domains the ATP binding site can be found, but not every subunit is able to bind the nucleotide. The arrangement of ATP binding and not-binding subunits in the hexameric ring is essential for the tertiary structure and the conformation changes after hydrolysis. The ClpP protein is a tetradecameric peptidase (Fig. 3, A and B).The subunits are arranged as two heptameric rings, one ring stacked on top of the other, with also a narrow pore in the center. This pore leads into the proteolytic chamber, which is barrel-shaped. Every subunit accommodates a classical Ser-His-Asp catalytic triad and oxyanion hole inside the chamber. Those proteolytic acitve sites (Fig. 3, C) can form several hydrogen bonds to the substrate<sup><a href="#13.2">[13.2]</a></sup>. <div align='left'><img src='https://static.igem.org/mediawiki/2013/0/06/BonnClp_Fig3.jpg' height='401' width='382'>Fig. 3: structure of ClpP, A: side view with stabilizing residues (blue), B: top view with the pore (red), C: active site of a subunit with a bonded substrate, from 'ClpXP, an ATP-powered unfolding and protein-degradation machine, Bakeret al, Biochim Biophys Acta, 2012, PMCID: PMC3209554'</div> </br> </br> </br><b> Functions: </b> </br>The ClpXP complex has three tasks to fulfill: </br> </br>1. Binding: The substrate binding process at the ClpX unit is normally conducted with the aid of an adaptor protein.This protein identifies tagged substrates and delivers them to the complex (Fig. 4, left). In order to transfer the protein,the adaptor also binds to the ClpX unit (Fig. 4, right), so that parts of the tag get approximated to a special binding site on the complex. After the linking between the tag and the binding site has been performed, the unfolding starts.The binding process also works without an adaptor protein, but an adaptor enhances the degratation by improving enzyme-substrate affinity. </br> </br> 2. Unfolding and translocation: The translocation of polypeptids through the ClpX unit to the ClpP chamber is an active process using energy from ATP-binding and -hydrolysing cycles. Therefor are several ATP molecules linked to the ClpXprotein. The separation of one phosphate molecule results in conformation changes, which pulls the linked protein more inside the pore located in the center of ClpX. The remaining ADP has to be replaced by a new ATP molecule before the cycle can start again. Meanwhile the unfolding is driven automatically, because the large tagged protein has to fit into the narrow pore, which forces the three-dimensional structure to become linear. </br> </br> 3. Degradation: The axial pore of the ClpP unit is also very narrow, allowing the entry of only small unfolded peptides into the proteolytic chamber. Inside the chamber, the substrate binds to an active site over several hydrogen bonds. It also can be linked to multiple active sites. In this position, proteins are cleaved in a maximum speed of around 10,000 proteins per minute by ClpP alone. If the ClpX unit is added, the rate is with ~0.2 proteins per minute and 0.3 &my;M substrate much lower, because the unfolding process takes longer time<sup><a href="#13.3">[13.3]</a></sup><sup><a href="13.4">[13.4]</a></sup>. </br> </br> <div align='left'><img src='https://static.igem.org/mediawiki/2013/b/b8/BonnClp_Fig4.jpg' height='311' width='628'>Fig. 4: Model of the degradation process with the sspB adaptor, from 'Engineering controllable protein degradation, McGinness et al, Molecular cell, 2006, PMID:16762842'</div> <h2><b> References </b> </h2></br> </br> <p><a id="13.1">[13.1]</a> ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554</br> <a id="13.2">[13.2]</a> See above </br> <a id="13.3">[13.3]</a> See above </br> <a id="13.4">[13.4]</a> Flexible Linkers Leash the Substrate Binding Domain of SspB to a Peptide Module that Stabilizes DeliveryComplexes with the AAA ClpXP Protease, Wah et al, 2003, Molecular cell, PMID: 14536075</p></br>';

-

~~content~~.~~summary~~= "";

+

content.type="Background";

-

~~content~~.~~text~~= "";

+

-

content.type="Background";

+

break;

Line 203:

Line 199:

case 15:

+

content.i = 15;

+

content.parents=[12]; -> parents einfügen

+

content.titleShort = "ssrA tag";

+

content.summary= "The ssrA tag is a sequence, which allows proteolytic enzymes to degrade them. It relates to proteases like the ClpXP complex in E.coli and it also allows adaptor proteins such as sspB binding and delivering substrates to the proteases in order to make the process more efficient";

+

content.text= "<b> Introduction </b> </br> For cells it is important to have a steady control over their own functions and reactions. During evolution many regulation systems evolved with controlling protein concentrations amongst them. In fact, increasing or decreasing protein amount is an effective way to manipulate cell activities. Therefore proteins can be marked with special tag sequences, which allows proteolytic enzymes to degrade them. One of those tags is called ssrA and relates to proteases like the ClpXP complex in E.coli. The tag also allows adaptor proteins such as sspB binding and delivering substrates to the proteases in order to make the process more efficient<sup><a href="#15.1">[15.1]</a></sup>. </br> For our project, the ssrA tag was very important, because we synthetically marked proteins with it to degrade them by placing the ssrA gen-code next to the protein code and letting ribosomes translate the new sequence. We also used sspB and the adaptor-mediated variant as described below, whereas the direct binding pathway wasn't an opinion for us. The reason is that we needed to control degradation level and therefor we set in a splitted version of sspB, which we could reunite through light radiation. For further information about the ClpXP degradation system in our project go to ClpXP general. Although it was not part of our project, the information in chapter 'Translation control' exhiit another important functional aspect of ssrA tags.</br> </br><b>Structure </b></br>The ssrA tag is a short sequence consisting of eleven amino-acids and is translated with the associated protein simultaneously. The sequence can be divided into two functional parts (Fig. 1). The 'AANDENY'-part, which is directly connected with the C-terminal end of the protein, is responsible for the binding to the sspB adaptor. Each letter in the part name stands for another amino-acid, A for example means Alanine. The other part, called 'LAA', interacts with the ClpX subunit of the ClpXP protease.

+

The parts are connected over an Alanine molecule<sup><a href="#15.2">[15.2]</a></sup>. </br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/1/18/BonnSsra_fig1.jpg' height='76' width='344'>Fig. 1: amino-acid sequence of ssrA, from 'Engineering controllable protein degradation, McGinness et al, Molecular cell, 2006, PMID:16762842' </div></br><b>Function </b> </br>The ssrA tag works as a degrading signal for proteases like ClpXP. Therefor ClpX owns a ssrA binding site at its axial pore. According to the availability of sspB adaptors, there are two different binding pathways. </br> </br>1. Direct binding: If a tagged protein and the ClpX subunit incidentally bump into each other in correct orientation, they develop a binding. The binding site of ClpX is made out of several loops and ssrA can be crosslinked to them. The determinant factor for this binding is the negative charged α-COOH group on the terminal alanine of ssrA, because the loops are positive charged. Using this way, ClpXP reaches a maximum degradation rate of around 4 proteins per minute<sup><a href="#15.3">[15.3]</a></sup>.</br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/a/a7/BonnSsra_fig2.jpg' height='281' width='361'>Fig. 2: direct binding of a tagged GFP protein, GFP is an green fluorescence protein, from 'Protein unfolding by a AAA+ protease is dependent on ATP-hydrolysis rates and substrate energy landscapes, Martin et al, Nature Structural & Molecular Biology, 2008, PMID: 18223658'</div> </br>2. Adaptor-mediated binding: sspB is an adaptor protein with a special binding site for the 'AADENY'-domain of ssrA. Therefor, the sspB dimer contains a pore in each subunit and while 'AADENY' is linked with the inside, the 'LAA'-domain faces outwards, free to bind ClpX (Fig. 2). The affinity of this binding amounts around 20 &my;M, which suggests a relative strong connection. The sspB dimer also owns two extremely flexible ClpX binding tails at each C-terminal end. With docking on ClpX, the 'LAA'-domain lies closely to ClpX's axial pore and can be bound to it.To sum up, there are three bonds connecting the ssrA-sspB-ClpX-complex and making it relative stable: ssrA with sspB, sspB with ClpX and ssrA with ClpX. Hence follows a lower K<sub>M</sub> than the direct binding process has (hab hierzu keine konkreten Daten). This lower K<sub>M</sub> means, that a smaller amount of substrate are needed to reach the maximum degradation speed.

+

So actually sspB doesn't increase the maximum speed, but this tempo can be reached with less substrate concentrations<sup><a href="#15.4">[15.4]</a></sup><sup><a href="#15.5">[15.5]</a></sup>.</br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/7/7c/BonnSsra_fig3.jpg' height='251' width='216'>Fig. 3: ssrA tag with sspB adaptor and protein substrate, from 'Engineering controllable protein degradation, McGinness et al, Molecular cell, 2006, PMID:16762842' </div> </br><b>Translation control</b> </br>Beneath the already mentioned functions, ssrA tags also play a role in quality control during ribosomal translation of genetic codes into protein sequences. In a normal working translation tRNA molecules deliver the amino-acids and a ribosome puts them together in the right order, using a mRNA strand as template. But this complicated process can be afflicted with mistakes, for example premature abruption or missing stop codons. Mistakes mostly result in defect proteins, which can be dangerous for he cell. In order to circumvent this danger, defect proteins are tagged with ssrA for quick degradation by special tmRNA molecules. TmRNA is a mixture of mRNA and tRNA. On the one hand it is formed like a tRNA molecule, is able to bind to a ribosome and delivers one amino-acid, but on the other hand it do not have an anticodon. Instead, an ORF mRNA part can be found. ORF means 'open reading frame' and is a coding sequence mostly for degradation tags like ssrA. As shown in figure 5, ssrA assembly is complex process. The tmRNA molecule binds to the A site of a stalled ribosome, takes over the already assembled amino-acid sequence and adds Alanine. Then it swaps the template mRNA for its ORF region and finishes translation with the new template. As a result the defect protein is now tagged and can be degradated by proteases like ClpXP<sup><a href="#15.6">[15.6]</a></sup>.</br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/0/02/BonnSsra_fig4.jpg' height='500' width='325'>Fig. 4: Model for tmRNA-mediated tagging, from 'The tmRNA System for Translational Surveillance and Ribosome Rescue, Moore SD et al, Annual Reviews Biochemistry, 2007, PMID: 17291191'</div> </br><h2><b> References </b></h2> </br><a id="15.1">[15.1]</a> Engineering controllable protein degradation, McGinnes KE et al, Molecular cell, 2006, PMID: 16762842<a id="15.2">[15.2]</a> Altered Tethering of the SspB Adaptor to the ClpXP Protease Causes Changes in Substrate Delivery, McGinnes KE et al, The journal of Biological Chemistry, 2007, PMID: 17317664 </br><a id="15.3">[15.3]</a> ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554</br><a id="15.4">[15.4]</a> See above </br>

+

<a id="15.5">[15.5]</a> Altered Tethering of the SspB Adaptor to the ClpXP Protease Causes Changes in Substrate Delivery, McGinnes KE et al, The journal of Biological Chemistry, 2007, PMID: 17317664 </br><a id="15.6">[15.6]</a> The tmRNA System for Translational Surveillance and Ribosome Rescue, Moore SD et al, Annual Reviews Biochemistry, 2007, PMID: 17291191 </br>";content.type="Background"; break;

-

~~content.i = 15;~~

-

~~content.parents=[12];~~

-

~~content.childs=[];~~

-

~~content.titleShort = "Ec. ssrA";~~

-

~~content.titleLong = "";~~

-

~~content.summary= "";~~

-

~~content.text= "";~~

-

~~content.type="Background";~~

-

~~break;~~

@@ Line 177: / Line 177: @@
 case 13:
 content.i = 13;
 content.parents=[12];
-content.childs=[];
+content.titleShort = "ClpXP protease";
-content.titleShort = "Ec. ClpXP";
+content.summary= "The ClpXP protein complex is an AAA+ protease, which means that it uses the energy of ATP hydrolysis to unfold and degenerate marked proteins.";
-content.titleLong = "";
+content.text= "<b> Introduction: </b> </br>The ClpXP protein complex is an AAA+ protease, which means that it uses the energy of ATP hydrolysis to unfold and degenerate marked proteins. The genetic code of this complex is highly conserved and can be found in human cells as well as in the bacteria Escherichia coli. The degradation system was discovered in the early 1990's and is now well established <sup><a href="#13.1">[13.1]</a></sup>.In our project, we used ClpXP to degrade specific proteins in order to control their amount and effect. Therefor, we utilized the common adaptor sspB.This protein recognizes substrates tagged with ssrA . In order to have a better control, we actually made use of a sspB split system. For more detailed information about the ClpXP degradation system in our project go to ClpXP general. </br> </br> <b> Structure:  </b> </br> The ClpXP complex consists of two functional and structural different parts. The ClpX protein, an ATPase, is a hexameric ring (Fig.1) with a pore in the center<div align='left'><img src='https://static.igem.org/mediawiki/2013/9/98/Bonn_Clp_Fig1.jpg' height='348' width='320'>Fig. 1: the hexameric ring of ClpX, each color represents a subunit, from  'ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554'</div> </br> Each subunit contains a N-terminal domain (Fig.2, B), which assumes the adaptor recognition and is stabilized by coordinated zinc atoms.However, the important part of a subunit is the AAA+ module (Fig.2, C), divided in a large and a small domain. <div align='left'><img src='https://static.igem.org/mediawiki/2013/d/d0/BonnClp_Fig2.jpg' height='262' width='499'>Fig. 2: structure of a ClpX subunit, B: the N-terminal domain with brown zinc atoms, C: the AAA+ module, from  'ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554'</div> </br> Between these domains the ATP binding site can be found, but not every subunit is able to bind the nucleotide. The arrangement of ATP binding and not-binding subunits in the hexameric ring is essential for the tertiary structure and the conformation changes after hydrolysis. The ClpP protein is a tetradecameric peptidase (Fig. 3, A and B).The subunits are arranged as two heptameric rings, one ring stacked on top of the other, with also a narrow pore in the center. This pore leads into the proteolytic chamber, which is barrel-shaped. Every subunit accommodates a classical Ser-His-Asp catalytic triad and oxyanion hole inside the chamber. Those proteolytic acitve   sites (Fig. 3, C) can form several hydrogen bonds to the substrate<sup><a href="#13.2">[13.2]</a></sup>. <div align='left'><img src='https://static.igem.org/mediawiki/2013/0/06/BonnClp_Fig3.jpg' height='401' width='382'>Fig. 3: structure of ClpP, A: side view with stabilizing residues (blue), B: top view with the pore (red), C: active site of a subunit with a bonded substrate, from 'ClpXP, an ATP-powered unfolding and protein-degradation machine, Bakeret al, Biochim Biophys Acta, 2012, PMCID: PMC3209554'</div> </br> </br> </br><b> Functions: </b> </br>The ClpXP complex has three tasks to fulfill: </br> </br>1. Binding: The substrate binding process at the ClpX unit is normally conducted with the aid of an adaptor protein.This protein identifies tagged substrates and delivers them to the complex (Fig. 4, left). In order to transfer the protein,the adaptor also binds to the ClpX unit (Fig. 4, right), so that parts of the tag get approximated to a special binding site on the complex. After the linking between the tag and the binding site has been performed, the unfolding starts.The binding process also works without an adaptor protein, but an adaptor enhances the degratation by improving enzyme-substrate affinity. </br> </br> 2. Unfolding and translocation: The translocation of polypeptids through the ClpX unit to the ClpP chamber is an active process using energy from ATP-binding and -hydrolysing cycles. Therefor are several ATP molecules linked to the ClpXprotein. The separation of one phosphate molecule results in conformation changes, which pulls the linked protein more inside the pore located in the center of ClpX. The remaining ADP has to be replaced by a new ATP molecule before the cycle can start again. Meanwhile the unfolding is driven automatically, because the large tagged protein has to fit into the narrow pore, which forces the three-dimensional structure to become linear. </br> </br> 3. Degradation: The axial pore of the ClpP unit is also very narrow, allowing the entry of only small unfolded peptides into the proteolytic chamber. Inside the chamber, the substrate binds to an active site over several hydrogen bonds. It also can be linked to multiple active sites. In this position, proteins are cleaved in a maximum speed of around 10,000 proteins per minute by ClpP alone. If the ClpX unit is added, the rate is with ~0.2 proteins per minute and 0.3 &my;M substrate much lower, because the unfolding process takes longer time<sup><a href="#13.3">[13.3]</a></sup><sup><a href="13.4">[13.4]</a></sup>. </br> </br> <div align='left'><img src='https://static.igem.org/mediawiki/2013/b/b8/BonnClp_Fig4.jpg' height='311' width='628'>Fig. 4: Model of the degradation process with the sspB adaptor, from 'Engineering controllable protein degradation, McGinness et al, Molecular cell, 2006, PMID:16762842'</div> <h2><b> References </b> </h2></br> </br> <p><a id="13.1">[13.1]</a> ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554</br> <a id="13.2">[13.2]</a> See above </br> <a id="13.3">[13.3]</a> See above </br> <a id="13.4">[13.4]</a> Flexible Linkers Leash the Substrate Binding Domain of SspB to a Peptide Module that Stabilizes DeliveryComplexes with the AAA ClpXP Protease, Wah et al, 2003, Molecular cell, PMID: 14536075</p></br>';
-content.summary= "";
+content.type="Background";
-content.text= "";
-content.type="Background";
 break;
@@ Line 203: / Line 199: @@
 case 15:
+content.i = 15;
+content.parents=[12]; -> parents einfügen
+content.titleShort = "ssrA tag";
+content.summary= "The ssrA tag is a sequence, which allows proteolytic enzymes to degrade them. It relates to proteases like the ClpXP complex in E.coli and it also allows adaptor proteins such as sspB binding and delivering substrates to the proteases in order to make the process more efficient";
+content.text= "<b> Introduction </b> </br> For cells it is important to have a steady control over their own functions and reactions. During evolution many regulation systems evolved with controlling protein concentrations amongst them. In fact, increasing or decreasing protein amount is an effective way to manipulate cell activities. Therefore proteins can be marked with special tag sequences, which allows proteolytic enzymes to degrade them. One of those tags is called ssrA and relates to proteases like the ClpXP  complex in E.coli. The tag also allows adaptor proteins such as sspB binding and delivering substrates to the proteases in order to make the process more efficient<sup><a href="#15.1">[15.1]</a></sup>. </br> For our project, the ssrA tag was very important, because we synthetically marked proteins with it to degrade them by placing the ssrA gen-code next to the protein code and letting ribosomes translate  the new sequence. We also used sspB and the adaptor-mediated variant as described below, whereas the direct binding pathway wasn't an opinion for us. The reason is that we needed to control degradation level and therefor we set in a splitted version of sspB, which we could reunite through light radiation. For further information about the ClpXP degradation system in our project go to ClpXP general. Although it was not part of our project, the information in chapter 'Translation control' exhiit another important functional aspect of ssrA tags.</br> </br><b>Structure </b></br>The ssrA tag is a short sequence consisting of eleven amino-acids and is translated with the associated protein simultaneously. The sequence can be divided into two functional parts (Fig. 1). The 'AANDENY'-part, which is directly connected with the C-terminal end of the protein, is responsible for the binding to the sspB adaptor. Each letter in the part name stands for another amino-acid, A for example means Alanine. The other part, called 'LAA', interacts with the ClpX subunit of the ClpXP protease.
+The parts are connected over an Alanine molecule<sup><a href="#15.2">[15.2]</a></sup>. </br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/1/18/BonnSsra_fig1.jpg' height='76' width='344'>Fig. 1: amino-acid sequence of ssrA, from 'Engineering controllable protein degradation, McGinness et al, Molecular cell, 2006, PMID:16762842' </div></br><b>Function </b> </br>The ssrA tag works as a degrading signal for proteases like ClpXP. Therefor ClpX owns a ssrA binding site at its axial pore. According to the availability of sspB adaptors, there are two different binding pathways. </br> </br>1. Direct binding: If a tagged protein and the ClpX subunit incidentally bump into each other in correct orientation, they develop a binding. The binding site of ClpX is made out of several loops and ssrA can be crosslinked to them. The determinant factor for this binding is the negative charged &alpha;-COOH group on the terminal alanine of ssrA, because the loops are positive charged. Using this way, ClpXP reaches a maximum degradation rate of around 4 proteins per minute<sup><a href="#15.3">[15.3]</a></sup>.</br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/a/a7/BonnSsra_fig2.jpg' height='281' width='361'>Fig. 2: direct binding of a tagged GFP protein, GFP is an green fluorescence protein, from 'Protein unfolding by a AAA+ protease is dependent on ATP-hydrolysis rates and substrate energy landscapes, Martin et al, Nature Structural & Molecular Biology, 2008, PMID: 18223658'</div> </br>2. Adaptor-mediated binding: sspB is an adaptor protein with a special binding site for the 'AADENY'-domain of ssrA. Therefor, the sspB dimer contains a pore in each subunit and while 'AADENY' is linked with the inside, the 'LAA'-domain faces outwards, free to bind ClpX (Fig. 2). The affinity of this binding amounts around 20 &my;M, which suggests a relative strong  connection. The sspB dimer also owns two extremely flexible ClpX binding tails at each C-terminal end. With docking on ClpX, the 'LAA'-domain lies closely to ClpX's axial pore and can be bound to it.To sum up, there are three bonds connecting the ssrA-sspB-ClpX-complex and making it relative stable: ssrA with sspB, sspB with ClpX and ssrA with ClpX. Hence follows a lower K<sub>M</sub> than the direct binding process has (hab hierzu keine konkreten Daten). This lower K<sub>M</sub> means, that a smaller amount of substrate are needed to reach the maximum degradation speed.
+So actually sspB doesn't increase the maximum speed, but this tempo can be reached with less substrate concentrations<sup><a href="#15.4">[15.4]</a></sup><sup><a href="#15.5">[15.5]</a></sup>.</br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/7/7c/BonnSsra_fig3.jpg' height='251' width='216'>Fig. 3: ssrA tag with sspB adaptor and protein substrate, from 'Engineering controllable protein degradation, McGinness et al, Molecular cell, 2006, PMID:16762842' </div> </br><b>Translation control</b> </br>Beneath the already mentioned functions, ssrA tags also play a role in quality control during ribosomal translation of genetic codes into protein sequences. In a normal working translation tRNA molecules deliver the amino-acids and a ribosome puts them together in the right order, using a mRNA strand as template. But this complicated process can be afflicted with mistakes, for example premature abruption or missing stop codons. Mistakes mostly result in defect proteins, which can be dangerous for he cell. In order to circumvent this danger, defect proteins are tagged with ssrA for quick degradation by special tmRNA molecules. TmRNA is a mixture of mRNA and tRNA. On the one hand it is formed like a tRNA molecule, is able to bind to a ribosome and delivers one amino-acid, but on the other hand it do not have an anticodon. Instead, an ORF mRNA part can be found. ORF means 'open reading frame' and is a coding sequence mostly for degradation tags like ssrA. As shown in figure 5, ssrA assembly is complex process. The tmRNA molecule binds to the A site of a stalled ribosome, takes over the already assembled amino-acid sequence and adds Alanine. Then it swaps the template mRNA for its ORF region and finishes translation with the new template. As a result the defect protein is now tagged and can be degradated by proteases like ClpXP<sup><a href="#15.6">[15.6]</a></sup>.</br> </br><div align='left'><img src='https://static.igem.org/mediawiki/2013/0/02/BonnSsra_fig4.jpg' height='500' width='325'>Fig. 4: Model for tmRNA-mediated tagging, from 'The tmRNA System for Translational Surveillance and Ribosome Rescue, Moore SD et al, Annual Reviews Biochemistry, 2007, PMID: 17291191'</div> </br><h2><b> References </b></h2> </br><a id="15.1">[15.1]</a> Engineering controllable protein degradation, McGinnes KE et al, Molecular cell, 2006, PMID: 16762842<a id="15.2">[15.2]</a>   Altered Tethering of the SspB Adaptor to the ClpXP Protease Causes Changes in Substrate Delivery, McGinnes KE et al, The journal of Biological Chemistry, 2007, PMID: 17317664 </br><a id="15.3">[15.3]</a> ClpXP, an ATP-powered unfolding and protein-degradation machine, Baker et al, Biochim Biophys Acta, 2012, PMCID: PMC3209554</br><a id="15.4">[15.4]</a>  See above </br>
+<a id="15.5">[15.5]</a>  Altered Tethering of the SspB Adaptor to the ClpXP Protease Causes Changes in Substrate Delivery, McGinnes KE et al, The journal of Biological Chemistry, 2007, PMID: 17317664 </br><a id="15.6">[15.6]</a> The tmRNA System for Translational Surveillance and Ribosome Rescue, Moore SD et al, Annual Reviews Biochemistry, 2007, PMID: 17291191 </br>";content.type="Background"; break;
-content.i = 15;
-content.parents=[12];
-content.childs=[];
-content.titleShort = "Ec. ssrA";
-content.titleLong = "";
-content.summary= "";
-content.text= "";
-content.type="Background";
-break;

Template:Team:Bonn:NetworkData

From 2013.igem.org

Revision as of 18:32, 1 October 2013