Difference between revisions of "Part:BBa K4886002"
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+ | ===(4) Carbon source selection for engineered C. tyrobutyricum=== | ||
+ | Due to limited experimental conditions, it was not possible to directly measure specific emissions of CO2 We estimated the value of carbon dioxide being fixed from the yield of the obtained product butyric acid, based on the principle of carbon conservation. The experimental results show that the introduction of the NOG pathway increases the production of butyric acid by 9.5% compared to the control group. Therefore, assuming that the global demand for butyric acid production is 80,000 tons, the formula calculates that the carbon dioxide emissions can be reduced by approximately 6,941 tons. The detailed calculation is shown in the following PDF file. | ||
+ | CO2 emission reduction models.pdf | ||
+ | Target 3 (Test) Carbon source selection for engineered C. tyrobutyricum | ||
+ | To find the best carbon source to grow the engineered C. tyrobutyricum, we compared the growth of Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS) on different carbon sources, including glucose, fructose and xylose. Fermentation experiment found that both strains had better growth than the native strain (control) on all the carbon sources, and fructose was the best carbon source for the growth of Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS), Figure 5. | ||
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+ | HPLC was used to compare the product yields and carbon source consumption of the strains cultured on different carbon sources for 45h (Table 2). The yields of acetic acid in Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS) were both higher than the control when cultured on fructose, indicating a low flow in NOG pathway. In Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS) cultured on xylose, the yields of acetic acid were both lower than the control, and the xylose consumption was higher than the control. Considering both the product yields of butyric acid and acetic acid and the consumption of carbon source, xylose was the best carbon source for NOG pathway in the engineered strains. | ||
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+ | These experimental results of carbon source selection showed that engineered C. tyrobutyricum with NOG pathway had an enhanced ability to utilize xylose, which is more beneficial to the utilization of cheap substrates like plant straw in subsequent industrial applications of the strain. | ||
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+ | <div class="unterschrift"><b>Note: a) Glucose,b) Fructose, c) Xylose</b> | ||
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+ | <div class="unterschrift"><b>Figure 5 Growth of Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS) cultured on glucose, fructose and xylose</b> | ||
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+ | <b>Table 2 Metabolite level in Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS) cultured on different carbon sources for 45h </b> | ||
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<!-- Uncomment this to enable Functional Parameter display | <!-- Uncomment this to enable Functional Parameter display |
Revision as of 12:16, 12 October 2023
Pthl-F/Xpk(QS)
It is a part that is responsible for expressing F/Xpk from Bifidobacterium adolescentis ATCC 15703 with Pthl promotor. It consists of Pthl sequence (BBa_K3443002), strong ribosomal binding site (RBS) sequence (BBa_K103015), F/Xpk sequence (BBa_K4886000) and terminator sequence (BBa_K3585002). F/Xpk is a gene that encodes phosphoketolase. Phosphoketolase is an enzyme with both the Fpk and Xpk activity. It catalyzes the conversion of fructose-6-phosphate (F6P) to erythrose-4-phosphate (E4P) and acetyl-phosphate (AcP), and the conversion of xylulose-5-phosphate (X5P) to glyceraldehydes-3-phosphate (G3P) and AcP.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal AgeI site found at 808
- 1000COMPATIBLE WITH RFC[1000]
Results
(1)Plasmid construction
We used Pthl-adhE2 from BBa_K4408008 as the template and X-pMTL-F and X-pMTL-R as primers to obtain a X-Pthl vector (5461bp) by amplification. We used the Bifidobacterium adolescentis ATCC 15703 genome as a template to amplify the phosphoketolase gene [FXpk(QS)] fragment (2478bp). The vector and fragment were confirmed by gel electrophoresis (Figure 2 and 3). The FXpk(QS) fragment was ligated to the X-Pthl linear vector, using Gibson assembly. The plasmid was then transformed into E.coli JM109. After colony PCR for the transformed bacterial colonies, positive colonies were inoculated, and plasmids were extracted. The recombinant plasmid pMTL-Pthl-FXpk(QS) obtained was confirmed by gene sequencing.
(2 )Transfection of C. tyrobutyricum and its growth
(3)Product yield of the transfected strain
Table 2 Metabolite level in Ct(Pthl F/Xpk-BD) and Ct(Pthl F/Xpk-QS) cultured on different carbon sources for 45h