Difference between revisions of "Part:BBa K1555000:Experience"
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| − | CopA, the principal copper effluxATPase in Escherichia coli, is induced by elevated copper in the medium.[1] CopA promoter is active in the presence of copper ion. | + | CopA, the principal copper effluxATPase in Escherichia coli, is induced by elevated copper in the medium.[1] CopA promoter is active in the presence of copper ion.We intended to character copA promoter independently. Therefore , we utilized RiboJ which was placed between promoter and protein coding sequence to eliminate the interference of two different parts. Output ( fluorescence) depended only on the activity of copA promoter when be induced, and not the sequence at the part junction. RiboJ can reliably maintain relative promoter strengths. |
First experiment: | First experiment: | ||
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| − | + | Improvement: | |
| − | We | + | We concluded that RiboJ helps reduce the leakage of copA promoter greatly. After adding copper ions, the expression of green-fluorescent protein increased steadily. So, copA promoter with RiboJ can balance the expression of target protein in Escherichia coli. |
Reference: | Reference: | ||
Revision as of 06:46, 21 October 2016
This sensor can be activated in low copper concentration and it's truely useful.
2h 0mg/L copper ion 
2h 1mg/L copper ion
Applications of BBa_K1555000
This year we add the RiboJ(a section of functional RNA used to buffer synthetic circuits from genetic context) between the copA pomoter and the RBS(B0030) as an improvement.Also we used GFP as the reporter( BBa_K2088015 copA+riboJ+B0030+GFP+B0015).For more details please check BBa_K2088015.
Experience of NAU-CHINA-2016 iGEM team--Kejian Shi
Experimental Design
Overview
CopA, the principal copper effluxATPase in Escherichia coli, is induced by elevated copper in the medium.[1] CopA promoter is active in the presence of copper ion.We intended to character copA promoter independently. Therefore , we utilized RiboJ which was placed between promoter and protein coding sequence to eliminate the interference of two different parts. Output ( fluorescence) depended only on the activity of copA promoter when be induced, and not the sequence at the part junction. RiboJ can reliably maintain relative promoter strengths.
First experiment:
We test copA promoter in BL21(DE3),DH5α. By measuring fluorescence intensity in cells by flow cytometer,we got data to analyze sensitivity and specificity of copA promoter.
Results:
In our experiment, copA promoter was induced by different concentration of copper ion (37.5umol/L、50umol/L、62.5umol/L、75umol/L) . That fluorescence intensity in cell increase firstly and decreasewith small oscillations.(Fig.3A,B) At 4-5th hour fluorescence intensity in cell increases dramatically. Dose response curves was fitted to twice induction within 9 hours. CopA promoter has relative leaky basal expression by comparing the negative control’s output and basal leakage of copA promoter in E. coli expression systems(Fig.4). In comparison of two graphs A、B, we can obviously find that the degradation of protein is much faster in DH5α than that in BL21(DE3),because BL21(DE3 ) has a deficiency of protease. In the group of 0μmol/L Cu2+, the fluorescence shows a trend of falling firstly then rising(Fig.3C). Actually, the fluorescence which produced by the leakage of copA will not change. The change quantity comes from the different growth periods of the E.coli. We added 40ul bacterial fluid into new medium with inductionto start measuring. So bacteria will go through a period of growing from growth period to maturation period, so as to the change of the fluorescence.Maturation period is great period for the expression of protein.
Second experiment:
We placed insulator RiboJ between copA promoter and RBS.(Fig.5)
Result:
We use 50μmol/L copper ion to induce copA promoter.A device without RiboJ has an unstable Fluorescent quantity. At fourth hour, the fluorescence intensity in cells rose sharply. By contrast,a device with RiboJ response to copper ion and express GFP gradually. (Fig 6A) In addition,a device without RiboJ has high leakage with fluctuation. However, a device with RiboJ has low and stable leakage. (Fig 6B)
Improvement: We concluded that RiboJ helps reduce the leakage of copA promoter greatly. After adding copper ions, the expression of green-fluorescent protein increased steadily. So, copA promoter with RiboJ can balance the expression of target protein in Escherichia coli.
Reference: [1] Outten FW, Outten CE, Hale J, O'Halloran TV. Transcriptional activation of an Escherichia coli copper efflux regulon by the chromosomal MerR homologue, cueR. Journal of Biological Chemistry 2000;275:31024-9.
User Reviews
UNIQa5b35f1cee98b0a7-partinfo-00000000-QINU
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HSiTAIWAN |
Detecting Copper in Chinese medicineObjectiveMeasure the E. coli fluorescence intensity in different copper ion concentration with 3μg/ml Chinese medicine. Methods Copper ion solution with different copper ion concentration (0, 3, 9, 27ppm) is added into E. coli DH5α with Plasmids encoding GFP under copper promoter(part: BBa_K1555000).
every 30 minutes. ResultsThis part is still specific to copper in Chinese medicine, so we can apply it in Chinese medicine examination.
DiscussionSince E. coli expresses stronger fluorescence in higher copper concentration, this is a relevant promoter to detect the existence and measure the amount of copper. ReviewThis part works great! HSiTAIWAN iGEM team 2016 used this part to detect copper ions in Chinese Medicine. The results were as expected. The reporter performed well without being interfered by complex substances. This part performed in an expected pattern and is an useful reporter. |
