Team:TU Darmstadt/Project/Scaffold

From 2014.igem.org

(Difference between revisions)
 
(51 intermediate revisions not shown)
Line 1: Line 1:
{{:Team:TU_Darmstadt/Template}}
{{:Team:TU_Darmstadt/Template}}
<html>
<html>
 +
<body>
<div id="contentWrap" class="container_24">
<div id="contentWrap" class="container_24">
<div id="breadcrumbs" class="grid_24">
<div id="breadcrumbs" class="grid_24">
-
<p>Sie sind hier:&nbsp; <a href="https://2014.igem.org/Team:TU_Darmstadt/Home" >wiki</a> &rsaquo;&nbsp;<a href="https://2014.igem.org/Team:TU_Darmstadt/Project" >Project</a> &rsaquo;&nbsp;<span class="current"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Scaffold" >Scaffold</a></span></p>
+
</div>
</div>
<div id="leftNavi" class="grid_5">
<div id="leftNavi" class="grid_5">
<nav>
<nav>
-
<ul class="menu"><li class="first"><a href="https://2014.igem.org/Team:TU_Darmstadt/Home" >Home</a></li><li class="active"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project" >Project</a><ul class="menu2"><li class="first"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Overview" >Overview</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Anthocyanins" >Anthocyanins</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Graetzel_Cell" >Grätzel cell / DSC</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Pathway" >Pathway</a></li><li class="active"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Scaffold" >Scaffold</a></li><li class="last"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Safety" >Safety</a></li></ul></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Results" >Results</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/PolicyandPractices" >Policy & Practices</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Achievements" >Achievements</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Notebook" >Notebook</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Team" >Team</a></li><li class="last"><a href="https://2014.igem.org/Team:TU_Darmstadt/Gallery" >Gallery</a></li></ul>
+
<ul class="menu"><li class="first"><a href="https://2014.igem.org/Team:TU_Darmstadt">Home</a></li><li class="active"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project">Project</a><ul class="menu2"><li class="first"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Overview">Overview</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Anthocyanins">Anthocyanins</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Graetzel_Cell">Grätzel cell / DSC</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Pathway">Pathway</a></li><li class="active"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Scaffold">Scaffold</a></li><li class="last"><a href="https://2014.igem.org/Team:TU_Darmstadt/Project/Safety">Safety</a></li></ul></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Results">Results</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/PolicyandPractices">Policy &amp; Practices</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Achievements">Achievements</a></li><li><a href="https://2014.igem.org/Team:TU_Darmstadt/Notebook">Notebook</a></li><li><a href="Team">Team</a></li><li class="last"><a href="Gallery">Gallery</a></li></ul>
</nav>
</nav>
</div>
</div>
-
+
<div id="wikicontent" class="grid_19">
-
<div id="wikicontent" wikiclass="grid_19">
+
 
-
<!--TYPO3SEARCH_begin--><div id="c254" class="csc-default"><div class="csc-header csc-header-n1"><h1 class="csc-firstHeader">Introduction</h1></div><p>It is important to address the concerns and possible consequences of intentional or accidental release into the environment when working with genetically engineered systems. These issues were already under discussion in the early years of Genetic Engineering and the Asilomar Conference in 1975 came to the conclusion that containment should always be made an important consideration in the design of the experiment. Furthermore should the effectiveness of the containment-approach match the estimated risk as closely as possible [1]. These principles still hold up until today and their importance even increased as the technology in recent years has shifted from the use of „simple“ transgenic&nbsp; organisms to designed synthetically constructs.</p></div><div id="c256" class="csc-default"><p>The goal of our iGEM safety project 2014 is to produce anthocyans in E.coli under laboratory or industrial conditions. Therefore our bacteria are not intended to be released into the environment and our considerations about biosafety are focused on preventing proliferation in case of an accidental release. To do so we decided to follow an active strategy for containment by designing a suicide construct that should prevent the survival of our cells if they get released into the environment but still does not limit the bacteria growth under controlled laboratory conditions. The main item of our suicide construct is the hokD gene of <i>E. coli</i> wich transcribes for a small polypeptide that results in cell death by elimination of vital cell wall functions if over expressed. The hokD gene is located in the <i>E. coli</i> chromosome as part of the relB operon. It’s gene product shows 40% homology to the polypeptide encoded by the hok (host killing) gene and induces the same characteristic cell deaths when over expressed [2]. It has been shown that the hokD gene can be used to design efficient suicide functions to contain bacteria growth. The efficiency of the containment system hereby is limited only by the mutation rate of the designed construct and the reduced growth rate resulting from a low basal level of <i>hokD</i>-expression [3, 4]. To avoid unwanted cell death due to basal expression we want to design a suicide backbone in wich hokD is under control of a T3 promotor (<i>phi4.3</i>) but the expression of T3-polymerase itself is controlled by an AraC-repressed pBad-promotor (BBa_K808000). In the presence of glucose the AraC repressor tightly inhibits the expression of T3-Polymerase and expression of hokD is inhibited so that the bacteria can grow with normal growth rate under controlled conditions [5]. In case of a release into the environment and upon depletion of glucose T3-polymerase is produced and the basal expression level of the T3 promotor results in expression of hokD and inhibits the proliferation of the bacteria.</p></div><div id="c263" class="csc-default"><div class="csc-textpic csc-textpic-center csc-textpic-above csc-textpic-equalheight"><div class="csc-textpic-imagewrap" data-csc-images="1" data-csc-cols="2"><div class="csc-textpic-center-outer"><div class="csc-textpic-center-inner"><figure class="csc-textpic-image csc-textpic-last"><a href="index.php?eID=tx_cms_showpic&amp;file=246&amp;md5=d9b3918498f7db5ec1aafd19de808606d7fc6952&amp;parameters%5B0%5D=YTo0OntzOjU6IndpZHRoIjtzOjQ6IjgwMG0iO3M6NjoiaGVpZ2h0IjtzOjQ6IjYw&amp;parameters%5B1%5D=MG0iO3M6NzoiYm9keVRhZyI7czo0MToiPGJvZHkgc3R5bGU9Im1hcmdpbjowOyBi&amp;parameters%5B2%5D=YWNrZ3JvdW5kOiNmZmY7Ij4iO3M6NDoid3JhcCI7czozNzoiPGEgaHJlZj0iamF2&amp;parameters%5B3%5D=YXNjcmlwdDpjbG9zZSgpOyI%2BIHwgPC9hPiI7fQ%3D%3D" onclick="openPic('index.php?eID=tx_cms_showpic&amp;file=246&amp;md5=d9b3918498f7db5ec1aafd19de808606d7fc6952&amp;parameters%5B0%5D=YTo0OntzOjU6IndpZHRoIjtzOjQ6IjgwMG0iO3M6NjoiaGVpZ2h0IjtzOjQ6IjYw&amp;parameters%5B1%5D=MG0iO3M6NzoiYm9keVRhZyI7czo0MToiPGJvZHkgc3R5bGU9Im1hcmdpbjowOyBi&amp;parameters%5B2%5D=YWNrZ3JvdW5kOiNmZmY7Ij4iO3M6NDoid3JhcCI7czozNzoiPGEgaHJlZj0iamF2&amp;parameters%5B3%5D=YXNjcmlwdDpjbG9zZSgpOyI%2BIHwgPC9hPiI7fQ%3D%3D','thePicture','width=438,height=600,status=0,menubar=0'); return false;" target="thePicture"><img src="fileadmin/_processed_/csm_SafetySchaubild_afa1fc3d19.png" width="510" height="700" alt=""></a><figcaption class="csc-textpic-caption">Fig. 1: Schematics of our envisioned killing switch.</figcaption></figure></div></div></div></div></div><div id="c257" class="csc-default"><p>To evaluate the basal and induced expression levels of our suicide backbone we will first engineered a test backbone (pSB1C3-YAT) in which hokD is replaced by eYFP (BBa_E0030) (Fig. 2). By measuring the fluorescence level under different glucose and arabinose concentrations we are able to determine whether our construct is regulated enough to prevent unwanted cell death and the efficiency of containment after induction.</p></div><div id="c376" class="csc-default"><div class="csc-textpic csc-textpic-center csc-textpic-above csc-textpic-equalheight"><div class="csc-textpic-imagewrap" data-csc-images="1" data-csc-cols="2"><div class="csc-textpic-center-outer"><div class="csc-textpic-center-inner"><figure class="csc-textpic-image csc-textpic-last"><a href="index.php?eID=tx_cms_showpic&amp;file=364&amp;md5=d7da9f47c56f5682340a3d0a3acb6dcd31959263&amp;parameters%5B0%5D=YTo0OntzOjU6IndpZHRoIjtzOjQ6IjgwMG0iO3M6NjoiaGVpZ2h0IjtzOjQ6IjYw&amp;parameters%5B1%5D=MG0iO3M6NzoiYm9keVRhZyI7czo0MToiPGJvZHkgc3R5bGU9Im1hcmdpbjowOyBi&amp;parameters%5B2%5D=YWNrZ3JvdW5kOiNmZmY7Ij4iO3M6NDoid3JhcCI7czozNzoiPGEgaHJlZj0iamF2&amp;parameters%5B3%5D=YXNjcmlwdDpjbG9zZSgpOyI%2BIHwgPC9hPiI7fQ%3D%3D" onclick="openPic('index.php?eID=tx_cms_showpic&amp;file=364&amp;md5=d7da9f47c56f5682340a3d0a3acb6dcd31959263&amp;parameters%5B0%5D=YTo0OntzOjU6IndpZHRoIjtzOjQ6IjgwMG0iO3M6NjoiaGVpZ2h0IjtzOjQ6IjYw&amp;parameters%5B1%5D=MG0iO3M6NzoiYm9keVRhZyI7czo0MToiPGJvZHkgc3R5bGU9Im1hcmdpbjowOyBi&amp;parameters%5B2%5D=YWNrZ3JvdW5kOiNmZmY7Ij4iO3M6NDoid3JhcCI7czozNzoiPGEgaHJlZj0iamF2&amp;parameters%5B3%5D=YXNjcmlwdDpjbG9zZSgpOyI%2BIHwgPC9hPiI7fQ%3D%3D','thePicture','width=723,height=600,status=0,menubar=0'); return false;" target="thePicture"><img src="fileadmin/_processed_/csm_pSB1C3-Yat_Map_6a00e234d8.png" width="301" height="250" alt=""></a><figcaption class="csc-textpic-caption">Fig. 2: Map of the planned test-plasmid (pSB1C3-YAT)</figcaption></figure></div></div></div></div></div><div id="c261" class="csc-default"><div class="csc-header csc-header-n6"><h1>References</h1></div><p>1.&nbsp;&nbsp; &nbsp;Berg, P., et al., Summary statement of the Asilomar conference on recombinant DNA molecules. Proc Natl Acad Sci U S A, 1975. 72(6): p. 1981-4.<br />2.&nbsp;&nbsp; &nbsp;Gerdes, K., et al., Mechanism of postsegregational killing by the hok gene product of the parB system of plasmid R1 and its homology with the relF gene product of the E. coli relB operon. Embo j, 1986. 5(8): p. 2023-9.<br />3.&nbsp;&nbsp; &nbsp;Knudsen, S.M. and O.H. Karlstrom, Development of efficient suicide mechanisms for biological containment of bacteria. Appl Environ Microbiol, 1991. 57(1): p. 85-92.<br />4.&nbsp;&nbsp; &nbsp;Knudsen, S., et al., Development and testing of improved suicide functions for biological containment of bacteria. Appl Environ Microbiol, 1995. 61(3): p. 985-91.<br />5.&nbsp;&nbsp; &nbsp;Saida, F., et al., Expression of highly toxic genes in E. coli: special strategies and genetic tools. Curr Protein Pept Sci, 2006. 7(1): p. 47-56.</p></div><!--TYPO3SEARCH_end-->
+
 
 +
<!--TYPO3SEARCH_begin-->
 +
<h1 class="csc-firstHeader">The Scaffold Idea</h1>
 +
 
 +
<p><span style="line-height: 18px; ">The steric proximity of enzymes can cause higher yield and production rates of final goods in metabolic processes. Different catalysation cascades can be found in nature that show intermediates that are transported to their next destination through channels or enzymes that are located closely to each other (Huang et al. 2001). This leads to an increased local concentration of metabolites near the enzymes und is especially useful in case of unstable or toxic intermediates of a reaction. To make use of such possibilities in synthetic biology, the Keasling Lab developed a construction of an easily and universally applicable protein scaffold. Its potency was proven in two examples with an up to 77-fold increase in yield (Dueber et al. 2009). The scaffold consists of three protein binding domains that may be linked by any number and in any order (figure 1). The scaffold can interlink with enzymes through domain-specific tags that are added to the catalytic proteins. The scaffold offers regulatory options for the stoichiometry of enzymes in steric proximity and may thereby counteract bottlenecks and excessive production of intermediates.</span></p>
 +
 
 +
<div class="contentcenter">
 +
<div class="contentcenter">
 +
<img src="https://static.igem.org/mediawiki/parts/a/aa/Scaffold_skizze.png" alt="" width="460px">
 +
</div>
 +
<br />
 +
<p>Figure 1: The scaffold molecule consists of three different interaction-domains, that can be freely combined (x, y, z). Chosen enzymes get attached to the scaffold through a tag complementary to the specific desired binding domains. This arrangement creates a production chain which generates higher yields.</p>
 +
</div>
 +
 
 +
<p>As far as we know, there have not been any successful attempts to clarify the structure of the scaffold molecule. NMR-structures of the separate parts (binding domains: GBD, PDZ, SH3) are known and were used to predict a homology-modeling based structure using PHYRE2 (figure 2).
 +
</p>
 +
 
 +
<div class="contentcenter">
 +
        <div class="contentcenter">
 +
            <img src="https://static.igem.org/mediawiki/parts/e/e6/Scaffold.png" alt="" width="550px">
 +
        </div>
 +
<p>Figure 2: 3D-structure of the protein scaffold, created with PHYRE2 based on structure-homology-modeling.</p>
 +
</div>
 +
 
 +
<p>The use of a scaffold protein might lead to a significant increase of yield of the anthocyanidin that we successfully produced in <i>E. coli</i> in our 2014 iGEM project. Since especially DFR of the enzymatic cascade shows only a relatively small turnover rate and also catalyzes several side reactions, it might be the limiting step for the overall production rate of our pathway. For this reason, we tried to establish a method to produce and characterize the scaffold for a further usage as a regulatory device and an improvement of our metabolic network. &nbsp;</p>
 +
 
 +
 
 +
<p align="justify">We tried to establish a system for the covalent crosslinking of our scaffold using the thiole group of a cysteine. Cysteine is not present in the sequence of the scaffold protein and therefore enables regiospecific coupling reactions. Cysteines belong to the naturally occurring amino acids and are of great significance for protein folding. Two cysteins can form a disulfide bond that leads to structural constraints while the folding-process of a protein takes place. Cysteines are a popular target for chemical modifications of proteins and bioconjugation due to their unique reactivity among amino acids. Generally, cysteine is one of the most used amino acid residue for protein modifications. Proteins can be provided with a virtually unlimited variety of modifications using coupling reagents as maleimids, haloacetamids etc. A frequent utilization of such free cysteine residues is protein immobilization on resin particles or the labeling of proteins with fluorophors. Bioconjugation of proteins with fluorophors is of great use for binding studies. Mainly, proteins with only one accessible cysteine residue are of interest for coupling reactions since a regioselective reaction is not possible if multiple cystein residues are present in a reactive and accessible form.</p>
 +
 
 +
 
 +
<div class="contentcenter">
 +
<div class="contentcenter">
 +
<img src="https://static.igem.org/mediawiki/parts/5/51/Scaffold_%28Fig3%29.png" alt="" height="123" width="600"></a></figure></div><div class="csc-textpic-text">
 +
</div>
 +
<p>Figure 3: Mechanism of an immobilization reaction. A free cysteine residue of a protein reacts with the maleimide function on the surface of a resin particle.</p>
 +
</div>
 +
 
 +
<div>
 +
</br>
 +
<p align="justify">We improved already existing scaffold domain Biobricks for the construction of scaffold proteins by introducing <i>Bgl</i>II and <i>BamH</i>I restriction sites flanking the domain sequence. Additionally, C-terminal linker domains consisting of glycine and serine residues were added to the scaffold domain. New scaffold sequences can be constructed by standard cloning approaches (see Figure 4). As usual, a backbone is ligated with an insert to create the desired sequence. For example a new scaffold protein consisting of two domains can be constructed by ligating a backbone vector including the desired N-terminal scaffold domain with an insert containing the desired C-terminal domain.  For this, the backbone has to be digested with the restriction enzymes <i>BamH</i>I and <i>Pst</i>I cleaving the plasmid downstream of the first domain. In contrast, the insert has to be extracted from its vector by digestion with <i>Bgl</i>II and <i>Pst</i>I. The overlap sequcences of the <i>Bgl</i>II and <i>BamH</i>I restriction sites are complementary. Thus, the insert can be ligated behind the first domain into the backbone. The scar sequence resulting from a combination of a <i>Bgl</i>II with <i>BamH</i>I restriction site cannot be recognized by nether of the enzymes. Therefore, a single ligation creates a new scaffold BioBrick immediately, which is again flanked by a <i>Bgl</i>II and BamH</i>I sequence. Of course, more sophisticated scaffold BioBricks can therefore be constructed from composite BioBricks containing more than one domain or again by iterative cloning of single domains behind an initial domain.</p>
 +
<img
 +
style="width: 820px; height: 800px;" alt=""
 +
src="https://static.igem.org/mediawiki/parts/0/0c/Cloning_scheme_101011.png"></p>
 +
<div class="contentcenter">
 +
<p>Figure 4: Cloning scheme for the construction of scaffold proteins. To assemble domains for the construction of a new scaffold protein, the backbone containing the N-terminal domain(s) can be digested with <i>BamH</i>I and <i>Pst</i>I and the C-terminal domain(s) can be cut from the plasmid with <i>Bgl</i>II and <i>Pst</i>I. The ligation of the two DNA fragments creates a new BioBrick, which can also be used for the construction of new scaffold proteins. Further scaffold proteins can be elongated by adding domains through the C-terminal <i>BamH</i>I site. The variability of the scaffold proteins can be increased by assembly of different domains.</p>
 +
</div>
 +
 
 +
 
 +
<h1>References</h1>
 +
<p>Xinyi Huang, Hazel M. Holden, and Frank M. Raushel, "Channeling of substrates und intermediates in enzyme-catalyzed reactions". Annual review of biochemistry, 70: 149 - 180, 2001.</p>
 +
<p>John E. Dueber, Gabriel C. Wu, G. Reza Malmirchegini, Tae Seok Moon, Christopher J. Petzold, Adeeti V. Ullal, Kristala L.J. Prather, und Jay D. Keasling, "Synthetic protein scaffolds provide modular control over metabolic flux". Nature biotechnology, 27: 753 - 759, 2009.</p>
 +
 
 +
 
 +
</div>
 +
 
 +
<!--TYPO3SEARCH_end-->
</div>
</div>
-
</html>
+
 +
 +
</body>
 +
</hmtl>

Latest revision as of 02:30, 18 October 2014

Home

The Scaffold Idea

The steric proximity of enzymes can cause higher yield and production rates of final goods in metabolic processes. Different catalysation cascades can be found in nature that show intermediates that are transported to their next destination through channels or enzymes that are located closely to each other (Huang et al. 2001). This leads to an increased local concentration of metabolites near the enzymes und is especially useful in case of unstable or toxic intermediates of a reaction. To make use of such possibilities in synthetic biology, the Keasling Lab developed a construction of an easily and universally applicable protein scaffold. Its potency was proven in two examples with an up to 77-fold increase in yield (Dueber et al. 2009). The scaffold consists of three protein binding domains that may be linked by any number and in any order (figure 1). The scaffold can interlink with enzymes through domain-specific tags that are added to the catalytic proteins. The scaffold offers regulatory options for the stoichiometry of enzymes in steric proximity and may thereby counteract bottlenecks and excessive production of intermediates.


Figure 1: The scaffold molecule consists of three different interaction-domains, that can be freely combined (x, y, z). Chosen enzymes get attached to the scaffold through a tag complementary to the specific desired binding domains. This arrangement creates a production chain which generates higher yields.

As far as we know, there have not been any successful attempts to clarify the structure of the scaffold molecule. NMR-structures of the separate parts (binding domains: GBD, PDZ, SH3) are known and were used to predict a homology-modeling based structure using PHYRE2 (figure 2).

Figure 2: 3D-structure of the protein scaffold, created with PHYRE2 based on structure-homology-modeling.

The use of a scaffold protein might lead to a significant increase of yield of the anthocyanidin that we successfully produced in E. coli in our 2014 iGEM project. Since especially DFR of the enzymatic cascade shows only a relatively small turnover rate and also catalyzes several side reactions, it might be the limiting step for the overall production rate of our pathway. For this reason, we tried to establish a method to produce and characterize the scaffold for a further usage as a regulatory device and an improvement of our metabolic network.  

We tried to establish a system for the covalent crosslinking of our scaffold using the thiole group of a cysteine. Cysteine is not present in the sequence of the scaffold protein and therefore enables regiospecific coupling reactions. Cysteines belong to the naturally occurring amino acids and are of great significance for protein folding. Two cysteins can form a disulfide bond that leads to structural constraints while the folding-process of a protein takes place. Cysteines are a popular target for chemical modifications of proteins and bioconjugation due to their unique reactivity among amino acids. Generally, cysteine is one of the most used amino acid residue for protein modifications. Proteins can be provided with a virtually unlimited variety of modifications using coupling reagents as maleimids, haloacetamids etc. A frequent utilization of such free cysteine residues is protein immobilization on resin particles or the labeling of proteins with fluorophors. Bioconjugation of proteins with fluorophors is of great use for binding studies. Mainly, proteins with only one accessible cysteine residue are of interest for coupling reactions since a regioselective reaction is not possible if multiple cystein residues are present in a reactive and accessible form.

Figure 3: Mechanism of an immobilization reaction. A free cysteine residue of a protein reacts with the maleimide function on the surface of a resin particle.


We improved already existing scaffold domain Biobricks for the construction of scaffold proteins by introducing BglII and BamHI restriction sites flanking the domain sequence. Additionally, C-terminal linker domains consisting of glycine and serine residues were added to the scaffold domain. New scaffold sequences can be constructed by standard cloning approaches (see Figure 4). As usual, a backbone is ligated with an insert to create the desired sequence. For example a new scaffold protein consisting of two domains can be constructed by ligating a backbone vector including the desired N-terminal scaffold domain with an insert containing the desired C-terminal domain. For this, the backbone has to be digested with the restriction enzymes BamHI and PstI cleaving the plasmid downstream of the first domain. In contrast, the insert has to be extracted from its vector by digestion with BglII and PstI. The overlap sequcences of the BglII and BamHI restriction sites are complementary. Thus, the insert can be ligated behind the first domain into the backbone. The scar sequence resulting from a combination of a BglII with BamHI restriction site cannot be recognized by nether of the enzymes. Therefore, a single ligation creates a new scaffold BioBrick immediately, which is again flanked by a BglII and BamHI sequence. Of course, more sophisticated scaffold BioBricks can therefore be constructed from composite BioBricks containing more than one domain or again by iterative cloning of single domains behind an initial domain.

Figure 4: Cloning scheme for the construction of scaffold proteins. To assemble domains for the construction of a new scaffold protein, the backbone containing the N-terminal domain(s) can be digested with BamHI and PstI and the C-terminal domain(s) can be cut from the plasmid with BglII and PstI. The ligation of the two DNA fragments creates a new BioBrick, which can also be used for the construction of new scaffold proteins. Further scaffold proteins can be elongated by adding domains through the C-terminal BamHI site. The variability of the scaffold proteins can be increased by assembly of different domains.

References

Xinyi Huang, Hazel M. Holden, and Frank M. Raushel, "Channeling of substrates und intermediates in enzyme-catalyzed reactions". Annual review of biochemistry, 70: 149 - 180, 2001.

John E. Dueber, Gabriel C. Wu, G. Reza Malmirchegini, Tae Seok Moon, Christopher J. Petzold, Adeeti V. Ullal, Kristala L.J. Prather, und Jay D. Keasling, "Synthetic protein scaffolds provide modular control over metabolic flux". Nature biotechnology, 27: 753 - 759, 2009.