Regulatory

Part:BBa_K3179003

Designed by: Jiaxian Xu   Group: iGEM19_SYSU-CHINA   (2019-10-13)


miR592-target

miR592-target is constructed bearing four repeats of miRNA 592, and each repeat added with ATG. Extra bases which can be devisable by three were added in order to separate ATGs.
This part, four repeating sequences complementary to miRNA592 on an mRNA, is a 4X miRNA target designed to target miRNA592. When miRNA592 reaches a certain concentration in the cell, it would combine with miR592-target and suppress the translation of mRNA. According to our design, miR592-target is designed to regulate the translation of mRNA with response parts. We integrate miR592-target with L7Ae so that L7Ae cannot be translated with miRNA592 existing in the cell.


Based on our analysis, we designed three different miRNA targets. We inserted it into the following miRNA detection plasmid (Figure 1a) to verify its independent ability to work and detect the expression of the corresponding miRNA in different HEK293. To verify whether the system causes tandem, we constructed three different plasmid contains 3 miRNA targets independently (miR-592, miR-663b and miR885-5p) were tested under different miRNA induction. After the plasmid is transcribed into the cell, the endogenous miRNA binds to the target on the mKate mRNA, blocking the expression of mKate, which cause a change in the value of mKate/EBFP that can be read by flow cytometry. The detection plasmids were tested under different miRNA induction.
By this method, we can compare the expression of the endogenous corresponding miRNA with the Positive Control which does not carry the miRNA target. At the same time, we transferred miR-592 mimetic, miR-885-5p and miR-663b inhibitors into corresponding cells to detect the regulation of the corresponding miRNA target by miR concentration, thus verifying the rationality and feasibility of single miRNA target design.
In the flow cytometry analysis (Fig. 1b, 2), we refer to the group with the lower affected group of mKate as the positive group, and the group with the larger influence of mKate as the negative group. We can identify a group of cells that are not obvious in the negative group (hexagonal circled part) in the positive group, and there is a significant difference in the ratio of cells between the positive group and the negative group in the interval of mKate/EGFP<0.4. Thus, we believe that miRNA targets can respond to changes in miRNA concentration.

Figure 1:Flow cytometry of miRNA detection plasmids


a. The detection plasmid is mainly composed of two fluorescent expression systems. The target of the target miRNA target is inserted into the 3'UTR sequence of mKate. If the miRNA target can work normally, the fluorescence ratio of mKate/EBFP can be changed. b. In the results, the positive group has a common cell population, which shows that all three miRNA targets work properly. At the same time, the concentration of endogenous miRNA corresponding to HEK293 can be displayed.

Figure 2: Density analysis of positive and unique cell populations revealed that the positive group had a deviation from the negative expression of mKate in the negative group



Usage and Biology

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


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