Difference between revisions of "Part:BBa K3331012"
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Figure 2 EPS biosynthetic pathway | Figure 2 EPS biosynthetic pathway | ||
− | ===2. Construction and validation of EPS synthesis plasmid 4 | + | ===2. Construction and validation of EPS synthesis plasmid 4=== |
Based on the work of the XJTU-2020 team, we selected the pgmA from E.coli (GenBank: CP041425.1) and galU gene from E.coli (GenBank: CP104721.1) which proved highest EPS production in previous study. LacI-Plac promoter fragment, pgmA and galU amplified from previous EE plasmid, were ligated into the backbone pSB1K3 by Golden Gate Assembly (Figure 3). Several clones were obtained after assembly and transformation, yet it is difficult to extract recombinant plasmid after several attempts. So another high copy number vector backbone pSEVA341 was employed, and the recombinant plasmid successfully constructed and verified by colony PCR as shown in Figure 4, and further confirmed by sequencing. The iGEM ID for plasmid 4 is BBa_K4182009. | Based on the work of the XJTU-2020 team, we selected the pgmA from E.coli (GenBank: CP041425.1) and galU gene from E.coli (GenBank: CP104721.1) which proved highest EPS production in previous study. LacI-Plac promoter fragment, pgmA and galU amplified from previous EE plasmid, were ligated into the backbone pSB1K3 by Golden Gate Assembly (Figure 3). Several clones were obtained after assembly and transformation, yet it is difficult to extract recombinant plasmid after several attempts. So another high copy number vector backbone pSEVA341 was employed, and the recombinant plasmid successfully constructed and verified by colony PCR as shown in Figure 4, and further confirmed by sequencing. The iGEM ID for plasmid 4 is BBa_K4182009. |
Revision as of 04:11, 14 October 2022
E.coli galU+E.coli pgmA
This part can increase the yield of EPS. The yield of EPS can be significantly increased by overexpressing two key enzymes galU and pgmA at the same time. The part galU is from Escherichia coli YJ4. The part pgmA is from Escherichia coli str. K-12 substr. MG1655 Reference: Levander Fredrik et al. Applied and environmental microbiology,2002,68(2).
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Overview
In order to increase the production of exopolysaccharides (EPSs), we altered the levels of enzymes in the central metabolism. We selected and overexpressed two key enzymes, galU and pgmA at the same time. And we found we successfully enhance the production of EPSs in E.coli.DH5α
Characterization
The test plasmid was constructed by Golden Gate Assembly and was confirmed by colony PCR. The length of E.coli galU fragment is 981bp, and the length of E.coli pgmA is 1770bp. The following results showed successful constructions.
Our strain was cultured in ampicillin-resistant LB medium with strictly control variables. We stop the culture after 24 hours of culture. We measure the expression of EPS and the level of gene transcription during this period. RT-qPCR was conducted to test their expressions. And we can see these two genes were transcribed successfully.
Anthrone sulfuric acid method was used to detect EPS yields. Compared with the blank strain, the EPS yield of the engineering strain increased by 106.4%. The results of this study clearly show that it is possible to enhance the production of EPSs in DH5α by altering the expression of this part.
We also measured the growth of DH5α transferred into the plasmid by enzyme labeling instrument. We measure the OD value of bacteria every hour under the wavelength of 600nm and fit the results. It was compared with the blankDH5α and the growth curve was drawn.
Improvement from XJTU-China-2022 iGEM
Profile
Name
A circuit for efficient exopolysaccharide synthesis
Base Pairs
6356
Usage&Biology
Our EPS synthesis circuit was constructed based on the previous work by team 2020-XJTU-China (BBa_K3331012)by the promoter and replicon optimization for the enhanced EPS synthesis. It contains the key enzymes GalU and PmgA under the regulation of LacI-Ptrc promoter. The EPS synthesis circuit was as below:
Figure 1 EPS synthesis circuit
1. Introduction to extracellular polysaccharide synthesis
Figure 2 shows the EPS biosynthetic pathway: Glucose can be converted to glucose-1-phosphate via EMP pathway or by enzyme phosphoglucose mutase (PgmA), and then UDP is synthesized by UDP glucose pyrophosphorylase (GalU) and served as precursor of EPS. Fredrik at al reported that the overexpression of pgmA and galU genes in Streptococcus thermophiles enhanced the EPS production from 0.17 g/mol to 0.31 g/mol. The same strategy was also employed in our study and the team 2020-XJTU-China. (https://2020.igem.org/Team:XJTU-China/Engineering)
Figure 2 EPS biosynthetic pathway
2. Construction and validation of EPS synthesis plasmid 4
Based on the work of the XJTU-2020 team, we selected the pgmA from E.coli (GenBank: CP041425.1) and galU gene from E.coli (GenBank: CP104721.1) which proved highest EPS production in previous study. LacI-Plac promoter fragment, pgmA and galU amplified from previous EE plasmid, were ligated into the backbone pSB1K3 by Golden Gate Assembly (Figure 3). Several clones were obtained after assembly and transformation, yet it is difficult to extract recombinant plasmid after several attempts. So another high copy number vector backbone pSEVA341 was employed, and the recombinant plasmid successfully constructed and verified by colony PCR as shown in Figure 4, and further confirmed by sequencing. The iGEM ID for plasmid 4 is BBa_K4182009.
Figure 3: PCR fragments used for construction of plasmid 4
Figure 4: Colony PCR verification of plasmid 4
3.Improvements compared to 2020-XJTU-China team
As shown in the Figure 5, compared to the EE plasmid constructed by team 2020-XJTU-China, our EPS synthesis plasmid were constructed with replicon optimization from medium-copy-number pMB1ori (15-20 copies) of EE plasmid to high-copy-number pRO1600 ori (100-150 copies) of pSEVA341 vector, and promoter optimization from low efficient P43 promoter to inducible high efficient PlacUV5. The optimization leads to the increased transcriptional levels for both galU and pgmA gene as shown in Figure 13. After IPTG induction, the expression levels of galU and pgmA gene were 3.4 and 2.8 fold compared to that of EE plasmid, demonstrating the improvement after promoter and replicon optimization.
Figure 5: Optimization of plasmid 4 compared to EE plasmid (BBa_K3331012 Vs BBa_K4182009)
Figure 6 RT-qPCR result of plasmid 4 compared to previous EE plasmid (IPTG was induced at a concentration of 1mM for 6h at 37℃.)
4.Determination of EPS content
Anthrone-sulfuric acid colorimetry is a fast and convenient sugar fixation method. Under strong acidic conditions, anthrone can be associated with free or polysaccharides present in hexose, pentose and hexoclonic acid to generate blue-green glycal derivatives, and sugar content can be determined by the different color of glycal product, whose maximum absorption peak at 620 nm. In this experiment we can quantitatively compare the EPS content of engineered bacteria by this method. First, we used glucose at concentrations of 0, 0.2, 0.4, 0.6, and 0.8 (units of mg/ml) as standard solutions to determine the standard curve at 620 nm. (Figures 7 and 8)
Figure 7-8: Standard curve using glucose as a standard solution and their different colors.
In order to avoid the influence of the sugar in LB medium, we purified the the intracellular EPS by alcohol precipitation and re-dissolved in water. The EPS content was detected by anthrone-sulfuric acid method and the results are shown in Figure 9.
Figure 9: 620 nm detection S of three strains harboring EE plasmid or plasmid 4. (calculated as the ratio of absorbance to liquid concentration), *indicating that there are significant differences in this sample compared to EE (based on T-TEST).
Compared with the previous EE plasmid, the EPS yield of the engineering bacteria with plasmid 4 has been significantly improved by about 3 fold (P<0.05), demonstrating the construction of plasmid 4 is successful and effective, and also confirming our improvement.
References
[1]Rafael Silva-Rocha, Esteban Martínez-García, Belén Calles, Max Chavarría, Alejandro Arce-Rodríguez, Aitor de las Heras, A. David Páez-Espino, Gonzalo Durante-Rodríguez, Juhyun Kim, Pablo I. Nikel, Raúl Platero, Víctor de Lorenzo, The Standard European Vector Architecture (SEVA): a coherent platform for the analysis and deployment of complex prokaryotic phenotypes, Nucleic Acids Research, Volume 41, Issue D1, 1 January 2013, Pages D666–D675, https://doi.org/10.1093/nar/gks1119
[2]Jorge Alonso-Gutierrez, Rossana Chan, Tanveer S. Batth, Paul D. Adams, Jay D. Keasling, Christopher J. Petzold, Taek Soon Lee, Metabolic engineering of Escherichia coli for limonene and perillyl alcohol production, Metabolic Engineering, Volume 19,2013, Pages 33-41, ISSN 1096-7176,https://doi.org/10.1016/j.ymben.2013.05.004.
[3]Figurski, D.H. and Helinski, D.R. (1979) Replication of an origin-containing derivative of plasmid RK2 dependent on a plasmid function provided in trans. Proc. Natl Acad. Sci. USA, 76, 1648–1652.
[4]Santos,P.M., Di Bartolo,I., Blatny,J.M., Zennaro,E. and Valla,S.(2001) New broad-host -range promoter probe vectors based on the plasmid RK2 replicon. FEMS Microbiol. Lett., 195, 91–96.
[5]LEVANDER F, SVENSSON M, RåDSTRöM P. Enhanced Exopolysaccharide Production by Metabolic Engineering of Streptococcus thermophilus [J]. Applied and Environmental Microbiology, 2002, 68(2): 784-90.