Polypeptide manufacturing Idea Approach.html

From 2009.igem.org

(Difference between revisions)

Revision as of 19:06, 21 October 2009

The idea & Approach

Usually for every polypeptide production, isolation and purification procedures have to be developed and optimized. For peptides high-yield expression in host such as bacteria is very difficult in form of a free polypeptide due to proteolytic degradation and difficult isolation due to small size. Examples of problematic production are also polypeptides toxic to their host where a lot of optimization is required to obtain small amounts of product. Our aim was to simplify and unify polypeptide manufacturing within the BioBrick system, enabling high-yield production of polypeptides regardless of their primary structure and properties.

We addressed this problem using ketosteroid isomerase (KSI) as a fusion partner of our constructs (Kuliopulos et al, 1994). Strong promoter such as T7 drives expression of KSI together with fused polypeptide biobrick to insoluble inclusion bodies. Inclusion bodies are stable against proteolysis and can be easily purified as the insoluble bacterial lysate may already consist of more than 80 % of fusion protein. We also introduced an acid-labile Asp-Pro bond between KSI and polypeptide biobrick to enable separation of polypeptide from KSI (Figure 1), without having to use aggressive and toxic chemicals, such as CNBr that may modify labile amino acid residues (Zorko et al, 2009). After acidic cleavage the released polypeptide is additionally purified by HPLC. This procedure enables simple high yield production and purification of versatile polypeptides and most importantly it occurs under the same denaturing conditions for every polypeptide.

'''Figure 1:''' Principle of a simple and uniform production of polypeptide biobricks. Polypeptide biobricks are produced as a fusion partner with insoluble ketosteroid isomerase (KSI) in form of inclusion bodies. The linker between KSI and polypeptide biobrick contains acid-labile bond Asp-Pro enabling easy cleavage by acid hydrolysis and separation of polypeptide biobrick from KSI. His-tag may aid in additional initial purification of inclusion bodies or removal of KSI segment in case that the polypeptide is also insoluble under the native conditions and detection of bacterial product by Western blot.

@@ Line 7: / Line 7: @@
 <br>
 <br>
-We addressed this problem using ketosteroid isomerase (KSI) as a fusion partner of our constructs (Kuliopulos et al, 1994). Strong promoter such as T7 drives expression of KSI together with fused polypeptide biobrick to insoluble inclusion bodies. Inclusion bodies are stable against proteolysis and can be easily purified as the insoluble bacterial lysate may already consist of more than 80 % of fusion protein. We also introduced an acid-labile Asp-Pro bond between KSI and polypeptide biobrick to enable separation of polypeptide from KSI (Figure 1), without having to use aggressive and toxic chemicals, such as CNBr that may modify labile amino acid residues (Zorko et al, 2009). After acidic cleavage the released polypeptide is additionally purified by HPLC. This procedure enables simple high yield production and purification of versatile polypeptides and most importantly it occurs under the same denaturing conditions for every polypeptide.
+We addressed this problem using ketosteroid isomerase (KSI) as a fusion partner of our constructs (Kuliopulos et al, 1994). Strong promoter such as T7 drives expression of KSI together with fused polypeptide biobrick to insoluble inclusion bodies. Inclusion bodies are stable against proteolysis and can be easily purified as the insoluble bacterial lysate may already consist of more than 80 % of fusion protein. We also introduced an acid-labile Asp-Pro bond between KSI and polypeptide biobrick to enable separation of polypeptide from KSI (''Figure 1''), without having to use aggressive and toxic chemicals, such as CNBr that may modify labile amino acid residues (Zorko et al, 2009). After acidic cleavage the released polypeptide is additionally purified by HPLC. This procedure enables simple high yield production and purification of versatile polypeptides and most importantly it occurs under the same denaturing conditions for every polypeptide.
 <br>
 <html>
 <center> <img src="https://static.igem.org/mediawiki/2009/2/2f/Manu_Figure_1.gif" align="center" width="600" height="437" border="0" />
 <br>
-Figure 1: Principle of a simple and uniform production of polypeptide biobricks. Polypeptide biobricks are produced as a fusion partner with insoluble ketosteroid isomerase (KSI) in form of inclusion bodies. The linker between KSI and polypeptide biobrick contains acid-labile bond Asp-Pro enabling easy cleavage by acid hydrolysis and separation of polypeptide biobrick from KSI. His-tag may aid in additional initial purification of inclusion bodies or removal of KSI segment in case that the polypeptide is also insoluble under the native conditions and detection of bacterial product by Western blot.
+'''Figure 1:''' Principle of a simple and uniform production of polypeptide biobricks. Polypeptide biobricks are produced as a fusion partner with insoluble ketosteroid isomerase (KSI) in form of inclusion bodies. The linker between KSI and polypeptide biobrick contains acid-labile bond Asp-Pro enabling easy cleavage by acid hydrolysis and separation of polypeptide biobrick from KSI. His-tag may aid in additional initial purification of inclusion bodies or removal of KSI segment in case that the polypeptide is also insoluble under the native conditions and detection of bacterial product by Western blot.
 </center>
 </html>
 <br>
 }}