Difference between revisions of "Part:BBa K2020005"
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[[File:T--Aachen--Skim_Milk_plate_3.png|300px| Skim milk plates assay. Cells producing the native subtilisin (left) in comparison to cells producing the mutated protease (right) after incubation for 3 days at 30°C.]] | [[File:T--Aachen--Skim_Milk_plate_3.png|300px| Skim milk plates assay. Cells producing the native subtilisin (left) in comparison to cells producing the mutated protease (right) after incubation for 3 days at 30°C.]] | ||
− | The figure shows the '''skim milk | + | The figure shows the results of a '''skim milk assay'''. This assay utilizes the clearance of skim milk due to proteolysis to detect proteolytic activity. Here, cells producing the native subtilisin (left) in comparison to cells producing the mutated protease (right) after incubation for 3 days at 30°C can be seen. |
A clearance and therefore a proteolytic activity could be observed for both the native protease (as demonstrated for the BioBrick [[Part:BBa_K2020002|K2020002]]) and for the SDM 3 modified expression system. | A clearance and therefore a proteolytic activity could be observed for both the native protease (as demonstrated for the BioBrick [[Part:BBa_K2020002|K2020002]]) and for the SDM 3 modified expression system. | ||
− | As SDM 3 had been executed to exchange tyrosine in the pro-peptide cleavage site against tryptophan, a proteolytic activity could be assumed due to the clearance observed. Contrary to our former beliefs, it could now be deduced that exchanging tyrosine does not result in a change of activity. Consequently, tyrosine in the pro-peptide cleavage site is not essential for the activity of | + | As SDM 3 had been executed to exchange tyrosine in the pro-peptide cleavage site against tryptophan, a proteolytic activity could be assumed due to the clearance observed. Contrary to our former beliefs, it could now be deduced that exchanging tyrosine does not result in a change of activity. Consequently, tyrosine in the pro-peptide cleavage site is not essential for the activity of |
− | + | Thus, exchanging tyrosine against a photo-labile, non-canonical amino acid more precisely ONB-tyrosine will not influence the activity of the enzyme. | |
Latest revision as of 13:16, 29 November 2016
mutated expression system for subtilisin E in E. coli (Y77W)
Once introduced into Escherichia coli, this BioBrick is able to produce an inactive version of subtilisin E and simultaneously secret the enzyme into the periplasm of the cell. By performing a site-directed mutagenesis, tyrosine77 in the propeptide of the enzyme was exchanged against tryptophan. Therefore, the enzyme loses its proteolytic activity.
For the varification of the function of this part, a skim milk assay on agar plates containing IPTG and the needed antibiotics was performed. Therefore, we streaked out the cells containing the modified expression systems on these plates and incubated at 30°C for three days.
The figure shows the results of a skim milk assay. This assay utilizes the clearance of skim milk due to proteolysis to detect proteolytic activity. Here, cells producing the native subtilisin (left) in comparison to cells producing the mutated protease (right) after incubation for 3 days at 30°C can be seen.
A clearance and therefore a proteolytic activity could be observed for both the native protease (as demonstrated for the BioBrick K2020002) and for the SDM 3 modified expression system. As SDM 3 had been executed to exchange tyrosine in the pro-peptide cleavage site against tryptophan, a proteolytic activity could be assumed due to the clearance observed. Contrary to our former beliefs, it could now be deduced that exchanging tyrosine does not result in a change of activity. Consequently, tyrosine in the pro-peptide cleavage site is not essential for the activity of Thus, exchanging tyrosine against a photo-labile, non-canonical amino acid more precisely ONB-tyrosine will not influence the activity of the enzyme.
Usage and Biology
Subtilisin E is an alkaline serine protease which non-specifically digests proteins. It is naturally produced by Bacillus subtilis.
This composite part consists of the promoter BBa_R0010, the ribosome binding site BBa_B0034, the newly created BioBrick part BBa_K2020001 and the terminator BBa_B0010. BioBrick BBa_K2020001 is a composite part itself and includes the secretion tag pelB (BBa_J32015) and a subtilisin E gene optimized for E. coli codon usage (BBa_K2020000).
Subtilisin E has to autoprocess itself to become functional. At first, the enzyme exists as a precursor, namely the pre-pro-subtilisin. The pre-sequence serves as a recognition sequence for secretion across the cytoplasmic membrane and is cleaved off in the course of the process. The pro-peptide acts as an intramolecular chaperone and facilitates the folding of the protease. Folding is essential for the activity of an enzyme. Still, the maturation process of Subtilisin E is not completed, as the pro-peptide covers the substrate binding site and inhibits activity. However, enough proteolytic activity is achieved to autoprocess the IMC-domain and therefore cleave off the pro-peptide. Yet, the C-terminal end of the pro-peptide continues to block the substrate binding site. After the degradation of the pro-peptide, the substrate-binding site is cleared and the protease becomes effectively active.
This mutated version of the BioBrick BBa_K2020002 was created to prove that tyrosine77 in the propeptide cleavage-site of subtilisin E is essential for the activity of the enzyme.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal NgoMIV site found at 280
- 1000COMPATIBLE WITH RFC[1000]