Difference between revisions of "Part:BBa K3927002"

(Characterization)
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===Characterization===
 
===Characterization===
 
<b> Characterization of activation module </b>
 
<b> Characterization of activation module </b>
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https://static.igem.org/mediawiki/parts/6/67/T--NUS_Singapore--3C120-CYC-LacO_activity_without_LacI_module.png
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<i>Figure 4: RFU of 3C120-CYC-LacO promoter controlling fluorescent protein mKO with concurrent EL222 expression, in either dark or blue light for 6 hours, compared to wildtype yeast</i>
  
 
Figure 4 demonstrates 3C120-CYC-LacO is successfully activated in blue light when housed in S.cerevisiae constitutively expressing NLS-VP16-EL222, demonstrating increased mKO expression compared to wildtype yeast when cultured in blue light.
 
Figure 4 demonstrates 3C120-CYC-LacO is successfully activated in blue light when housed in S.cerevisiae constitutively expressing NLS-VP16-EL222, demonstrating increased mKO expression compared to wildtype yeast when cultured in blue light.
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Figure 5 represents the expression values in RFU over time for 3C120-CYC-LacO in S.cerevisiae constitutively expressing NLS-VP16-EL222 in either darkness, full blue light or half hour on-half hour off cycles of blue light. 50% cycles of blue light showed a more gradual response than 100% blue light, demonstrating the ability of 3C120-CYC-LacO to be activated in a dose-dependent manner.
 
Figure 5 represents the expression values in RFU over time for 3C120-CYC-LacO in S.cerevisiae constitutively expressing NLS-VP16-EL222 in either darkness, full blue light or half hour on-half hour off cycles of blue light. 50% cycles of blue light showed a more gradual response than 100% blue light, demonstrating the ability of 3C120-CYC-LacO to be activated in a dose-dependent manner.
 +
 
Figure 6 shows the growth curve of S.cerevisiae constitutively expressing NLS-VP16-EL222 and harbouring a plasmid containing 3C120-CYC-LacO in in either darkness, full blue light or half hour on-half hour off cycles of blue light. Data represents minimal difference in cells with an active promoter, 50% active promoter(dose dependent activity is established by Figure 5) or inactive promoter in terms of growth, and thus this part does not directly impose a metabolic burden on the cell.
 
Figure 6 shows the growth curve of S.cerevisiae constitutively expressing NLS-VP16-EL222 and harbouring a plasmid containing 3C120-CYC-LacO in in either darkness, full blue light or half hour on-half hour off cycles of blue light. Data represents minimal difference in cells with an active promoter, 50% active promoter(dose dependent activity is established by Figure 5) or inactive promoter in terms of growth, and thus this part does not directly impose a metabolic burden on the cell.
  

Revision as of 02:16, 18 October 2021


3C120-CYC-LacO

This part encodes for a truncated CYCp core promoter with three C120 repeats replacing the native upstream activating sequence, and a lacO sequence downstream of the TATA box.

Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal XbaI site found at 203
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 185
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal XbaI site found at 203
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal XbaI site found at 203
  • 1000
    COMPATIBLE WITH RFC[1000]

Description

3C120-CYC-LacO is the implementation of an abstracted, hypothetical synthetic promoter developed by the NUS iGEM team 2021 for tight, blue light regulated expression in S.cerevisiae.

Usage

This part is a blue light inducible promoter, therefore requires blue light for this promoter to be induced. Additionally, it requires part BBa_K3927000 / BBa_K3570021 (NLS-VP16-EL222) and part BBa_K3927006 (yeast LacI) to function.

Design

Our team was motivated to develop a new framework for optogenetic promoters, spurred on by the need to increase inducible expression, but confronted by the dilemma that single layer methods, such as adding additional activation motifs or optimizing the TATA box, were usually accompanied by increased leakiness of the promoter. Taking inspiration from the tightly regulated, yet powerful native promoter GAL1p , it was decided that a combination of conditionally activiating and suppression motifs were required to achieve the desired outcome of both high expresssion and low leakiness. The design that was conceptualized included an artificial upsteam activated module, a core promoter and a reprssion module downstream of the core promoter, drawing from the architecture of native yeast promoters[1].

T--NUS_Singapore--results_tab7_1.png Figure 1: Circuit design for the modular promoter 3C120-CYC-LacO. The abstracted modules include a core promoter, a blue light activated module, and a module for repressing promoter activity

In darkness, the repression module prevents leakiness, and in the presence of blue light, a secondary, trans-regulatory repression module represses the primary repressor module, allowing the blue light activated module to power the core promoter. In this way, highly active activation modules could be coupled to the core promoter without the issue of increasining leakiness(Figure 1). This modularity also meant that activation and repression of the promoter could be controlled separately, allowing for AND gate logic, where represson module could be linked to an alternative response(Figure 2).

T--NUS_Singapore--3C120-CYC-LacO_architecture.png

Figure 2: 3C120-CYC-LacO can either be used to tighten expression of a single blue light input by linking LacI to a secondary, blue light repressed module, or can be coupled to alternative

To implement this design, the NUS iGEM team 2021 decided to further improve the optogenetic system in part BBa_K3570005 designed by the Toulouse iGEM team 2020. The part depends on the expression of an NLS-VP16-EL222 fusion transcription factos, which dimerizes in blue light and binds to C120 repeats[2], activating a core CYC1 promoter element in close proximity(Figure 1). Thus, our chosen activation module a 3x repeat of the C120 motif. For the primary repression module, a Lac operon sequence was chosen, at it has been demonstrated to be a functional repressor of synthetic promoters in yeast[3]. This was inserted downstream of the TATA box in the core CYC1 promoter element.

T--NUS_Singapore--EL222_blue_light_activated_transcription_system.png Figure 3: EL222 blue light activated transcription system.

For the primary repression module, a Lac operon sequence was chosen, at it has been demonstrated to be a functional repressor of synthetic promoters in yeast[3]. This was inserted downstream of the TATA box in the core CYC1 promoter element.

Characterization

Characterization of activation module

T--NUS_Singapore--3C120-CYC-LacO_activity_without_LacI_module.png

Figure 4: RFU of 3C120-CYC-LacO promoter controlling fluorescent protein mKO with concurrent EL222 expression, in either dark or blue light for 6 hours, compared to wildtype yeast

Figure 4 demonstrates 3C120-CYC-LacO is successfully activated in blue light when housed in S.cerevisiae constitutively expressing NLS-VP16-EL222, demonstrating increased mKO expression compared to wildtype yeast when cultured in blue light.

Figure 5 represents the expression values in RFU over time for 3C120-CYC-LacO in S.cerevisiae constitutively expressing NLS-VP16-EL222 in either darkness, full blue light or half hour on-half hour off cycles of blue light. 50% cycles of blue light showed a more gradual response than 100% blue light, demonstrating the ability of 3C120-CYC-LacO to be activated in a dose-dependent manner.

Figure 6 shows the growth curve of S.cerevisiae constitutively expressing NLS-VP16-EL222 and harbouring a plasmid containing 3C120-CYC-LacO in in either darkness, full blue light or half hour on-half hour off cycles of blue light. Data represents minimal difference in cells with an active promoter, 50% active promoter(dose dependent activity is established by Figure 5) or inactive promoter in terms of growth, and thus this part does not directly impose a metabolic burden on the cell.