Difference between revisions of "Team:MIT/Experiments/Promoters"

 
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<title> Promoter/Receptor Group Background </title>
 
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<h1 style="color:#f20253; text-align: center; font-size: 40px; line-height: 40px;">Synthetic Mammalian Promoter Engineering</h1>
 
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<h1 style="color:#FFFFFF; background-color:#F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: trebuchet MS"> How does endometriosis respond to hormones?</h1>   
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<p style="font-family: Verdana;"> Typical, healthy cells of the endometrium will respond in a coordinated fashion to the ovarian hormones, estrogen and progesterone, in order to create the cycles of cell turnover and growth characteristic of the menstrual cycle.  Endometriosis, however, is characterized by aberrant cellular responses to estrogen and progesterone that ultimately lead to the disease phenotype. </p>
<h1 style="background-color:#F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: Trebuchet MS"> How does endometriosis respond to hormones?</h1>   
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<img src="https://static.igem.org/mediawiki/2016/thumb/4/4f/T--MIT--KHB1177menstrual-cycle.jpeg/240px-T--MIT--KHB1177menstrual-cycle.jpeg" alt = 'menstrual cycle diagram' style='width: 250px: height = 250px; float:right;" margin: 0 1.5%;>
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<h2 style="text-decoration:underline; font-family: Trebuchet MS;"> Menstrual Cycle</h2>
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<p style="font-family: Verdana; float:left;"> The monthly menstrual cycle of a womens' uterus consists of the menstrual, proliferative, and secretory phases. In menstruation, the womens' uterine lining sheds as it removes the egg from the body. Then during the proliferative phase, the surplus of estrogen stimulates the re-growth of the edometrium, also know as the uterine lining. And lastly, during the secretory phase, the levels of estrogen drop some while progesterone becomes the dominant hormone allowing the endometrium to be susceptible to pregnancy. Overall, this cycle lasts a total of 28 days and is large classified by the peaks and drops of estrogen and progesterone. </p>
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<img src= "https://static.igem.org/mediawiki/2016/b/b7/T--MIT--healthydiseased.png" alt = 'Hormone response diagram' style="width:500px;height:534px; float:left;"  margin: 0 1.5%; class="rotate90">
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<h2 style="text-decoration:underline; font-family: Verdana;"> Estrogen Signaling Dysregulation</h2>
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<p style="font-family: Verdana;">Endometrial cells express endogenous estrogen receptors in two forms: ER-alpha and ER-beta. When a healthy cell senses estrogen, these two estrogen receptors will be activated and trigger downstream responses by binding to sequences in the genome known as <b>estrogen responsive elements (<a href ="http://parts.igem.org/Part:BBa_K2100000">EREs</a>)</b>. In diseased or endometriotic cells, estrogen signaling is pathologically upregulated leading to proliferation and migration of cells outside the uterus. [1]</p>
  
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<h2 style="text-decoration:underline; font-family: Verdana;"> Progesterone Resistance</h2>
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<p style="font-family:Verdana;"> Endometrial cells express endogenous progesterone receptors in two forms: PR-A and PR-B. When a healthy cell senses progesterone, its PR receptors are activated and trigger downstream responses by binding to different sites in the genome known as progesterone responsive elements <b>(<a href = "http://parts.igem.org/Part:BBa_K2100008">PREs</a>)</b>. However, in a diseased cell, while progesterone is present, it does not co-activate the progesterone receptors, and in turn does not result in any downstream effects. This disruption in the cell's normal response to progesterone is known as <i>progesterone resistance</i>. Research has implicated perturbations in key progesterone signaling intermediates such as HOXA10, FOX01, NFkB in causing progesterone resistance [1].
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<img src= "https://static.igem.org/mediawiki/2016/a/a7/T--MIT--KHB1177hormone-response.jpeg" alt = 'Hormone response diagram' style="width:250px;height:267px; float:left;"  margin: 0 1.5%; class="rotate90">
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<p style="font-family: Verdana;"> <b>Hence, we created sensors for estrogen signaling and progesterone signaling</b> that were transfected into a variety of cell lines. Functional estrogen and progesterone signaling sensors could label a cell having both pathologically upregulated estrogen signaling and pathologically downregulated progesterone signaling as diseased. </p>
<h2 style="text-decoration:underline; font-family: Trebuchet MS;"> Estrogen</h2>
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<p style="font-family: Verdana;">There are endogenous estrogen receptors in two forms: ER-alpha and ER-beta. When a healthy cell senses estrogen, the ER-alpha receptor is activated and triggers downstream responses by binding to different sites, such as an estrogen responsive element. Diseased cells respond in the same fashion as healthy cells. </p>
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<h2 style="text-decoration:underline; font-family: Trebuchet MS;"> Progesterone</h2>
 
<p style="font-family:Verdana;"> There are also endoegenous progesterone receptors in two forms: PR-A and PR-B. When a healthy cell senses progesterone, its PR receptors are activated and trigger downstream responses by binding to different sites, such as a progesterone responsive element. However, in a diseased cell, while progesterone is present, it does not co-activate the progesterone receptors, and in turn does not result in any downstream effects.
 
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<h1 style="background-color: #F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: Trebuchet MS"> How can our circuit detect hormones?</h1>   
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<h1 style="color:#ffffff; background-color: #F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: trebuchet MS"> How can our circuit detect hormones?</h1>   
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<img src= "https://static.igem.org/mediawiki/2016/c/c6/T--MIT--KHB1177tretoere.jpeg" alt = 'TRE to pERE promoters' style="width:400px;height:185px; float:right;"  margin: 0 1.5%; class="rotate90">
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<p style="font-family:Verdana;"> To create sensors for estrogen and progesterone signaling, our team decided to create synthetic mammalian promoters that could interact with the estrogen and progesterone receptors. We based our design off of the standard tetracycline inducible Tet-On and Tet-Off systems[2], which features the <b><a href="http://parts.igem.org/Part:BBa_K2100004">TRE_tight promoter</a></b>. Where <a href="http://parts.igem.org/Part:BBa_K2100004">the TRE_tight promoter</a> has tetO binding sites for the reverse tetracycline-controlled trans-activator (<a href=:http://parts.igem.org/Part:BBa_K2100025">rtTA</a>) to bind, we replaced them with binding sites for the estrogen receptor, <b><a href = "http://parts.igem.org/Part:BBa_K2100000">EREs</a></b>, and binding sites for the progesterone receptor, <b><a href = "http://parts.igem.org/Part:BBa_K2100008">PREs</a></b>. We preserved the same minimal promoter used in the <a href="http://parts.igem.org/Part:BBa_K2100004">TRE_tight promoter</a>, minCMV, derived from the cytomegalovirus.</p>
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<p> We expanded on this design by varying the binding sites for the estrogen receptor and progesterone receptor creating the constructs <a href = "http://parts.igem.org/Part:BBa_K2100000">pERE3</a>, <a href = "http://parts.igem.org/Part:BBa_K2100001">pERE5</a>, <a href = "http://parts.igem.org/Part:BBa_K2100002">pERE6</a>, <a href = "http://parts.igem.org/Part:BBa_K2100008">pPRE3</a>, <a href = "http://parts.igem.org/Part:BBa_K2100009">pPRE4</a> which contain the specified number of receptor binding sequence. We also created a hybrid construct that contains five binding sites for the estrogen receptor interspersed with five binding sites for the progesterone receptor.  </p>
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<img src= "https://static.igem.org/mediawiki/2016/c/c6/T--MIT--KHB1177tretoere.jpeg" alt = 'TRE to pERE promoters' style="width:250px;height:267px; float:left;" margin: 0 1.5%; class="rotate90">
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<h1 style="color:#ffffff;background-color: #F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: trebuchet MS"> Do our synthetic promoters work?</h1>
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<p>We demonstrated the <b>success of our progesterone and estrogen inducible mammalian promoters</b> in a variety of cell lines under different conditions: </p>
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<li><b><a href = "http://parts.igem.org/Part:BBa_K2100000">pERE3</a>, <a href = "http://parts.igem.org/Part:BBa_K2100001">pERE5</a>, <a href = "http://parts.igem.org/Part:BBa_K2100002">pERE6</a></b> demonstrated successful estrogen signaling sensing in MCF7.</li>
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<li><b><a href = "http://parts.igem.org/Part:BBa_K2100001">pERE5</a></b> demonstrated successful estrogen signaling sensing in ISH.</li>
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<li><b><a href = "http://parts.igem.org/Part:BBa_K2100000">pERE3</a></b> demonstrated successful estrogen signaling sensing in tHESC</li>
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<li><b><a href = "http://parts.igem.org/Part:BBa_K2100010">pHybrid</a></b> demonstrated successful estrogen signaling sensing in MCF7.</li>
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<li><b><a href = "http://parts.igem.org/Part:BBa_K2100010">pHybrid</a></b> demonstrated successful progesterone signaling sensing in tHESC.</li>
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<li><b><a href = "http://parts.igem.org/Part:BBa_K2100009">pPRE4</a></b> demonstrated limited success of progesterone signaling sensing in MCF7.</li>
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<center><img src= "https://static.igem.org/mediawiki/2016/e/ed/T--MIT--mcf7induction.png" alt = '' style="width:800px;height:409px;" margin: 0 1.5%; class="rotate90"></center>
An important aspect of synthetic biology is having inducible systems so that the output is not produced constitutively. Since progesterone is a key biomarker of endometriosis and also one of the two components of the menstural cycle. We wanted to use the sensing of progesterone as a way to inhibit our system. In contrast we wanted to use the sensing of estrogen to activate our system. Currently, there had been some research on hormone inducible promoters, but this is largely lacking in the field of synthetic biology. We decided to tackle this problem by developing our own synthetic promoter, which was based off of the key components of the commmonly used synthetic promoter, Tetracyclin Response Element promoter (TRE). We kept the basic promoter elements, but rather than having tetO responsive sites, we used progesterone and estrogen responsive elements (PRE's and ERE's respectively.
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<a href = "https://2016.igem.org/Team:MIT/Experiments/Promoters/Design-Descisions" ><p style="font-family:Verdana;"><small><i>Read more about our design desicions for our inducible promoters: pERE, pPRE, and pHybrid.</i></small></p></a>
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<h1 style="background-color: #F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: Trebuchet MS"> Do our synthetic promoters work?</h1>  
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<i><p>MCF7 cells above are transfected with our construct <a href="http://parts.igem.org/Part:BBa_K2100027">pEREx3 - eYFP</a>, which contains three binding sites for the estrogen receptor upstream of a minimal promoter and yellow fluorescent gene. Cytometry data demonstrated an 11 fold increase in the transcriptional activity of our promoters when transfected into the MCF7 cell line. Since our transfection efficiency was poor (< 10%) in several of the more difficult-to-transfect cell lines we worked with, we relied primarily on the cytometry data linked below to reach conclusions about the functionality of our promoter instead of the brightfield imaging shown here.</p></i>
<p style = "font-family:Verdana;"> SOme text goes here ya know.
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<center><img src ="https://static.igem.org/mediawiki/2016/1/11/T--MIT--mcf7e2sensing.png" alt = '' style="width:799px;height:247px;"  margin: 0 1.5%; class="rotate90"></center>
  
<a href ="https://2016.igem.org/Team:MIT/Experiments/Promoters/Experiment-Details"><p style="font-family:Verdana;"><small><i>Read more about our experiments testing the functionality of our promoters.</i></small></p> </a>
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<i><p>A sampling of some of the cytometry data used to confirm the function of our promoters in various cell lines. Shown here is cytometry data of promoter function in MCF7 - full extended results for all promoters linked below.</p></i>
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<h2 style="text-decoration:underline; font-family: Trebuchet MS;"> <center>MCF7 Induction of pEREx3 - eYFP</center></h2>
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<center><a href ="https://2016.igem.org/Team:MIT/Experiments/Promoters/Experiment-Details"><p style="font-family:Verdana;font-size:15px""><i>Read more about the extended series of experiments testing the functionality of our promoters.</i></p> </a></center>
<center><img src= "https://static.igem.org/mediawiki/2016/4/40/T--MIT--KHB1177flourescence-fakeimg.jpeg" alt = 'TRE to pERE promoters' style="width:700px;height:267px;"  margin: 0 1.5%; class="rotate90"></center>
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<h1 style="color:#ffffff;background-color: #F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: trebuchet MS"> How do our promoters behave in larger circuits?</h1>  
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<p style="font-family:Verdana;">The true test of a robust part is its consistent behavior in larger genetic circuits. So, after demonstrating the functionality of our estrogen and progesterone inducible promoters, we next sought to create larger genetic circuits with them. We built estrogen inducible promoter - repressor cascades, as well as estrogen inducible promoter - recombinase and only met with limited success when transfecting our genetic circuits into various cell lines.</p>
  
<h2 style="text-decoration:underline; font-family: Trebuchet MS;"> <center>tHESC Induction of pEREx3 - eYFP</center></h2>
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<center><img src= "https://static.igem.org/mediawiki/2016/c/cd/T--MIT--ererep.svg" alt = '' style="width:800px;height:412px;"  margin: 0 1.5%; class="rotate90"></center>
<center><img src= "https://static.igem.org/mediawiki/2016/4/40/T--MIT--KHB1177flourescence-fakeimg.jpeg" alt = 'TRE to pERE promoters' style="width:700px;height:267px; "  margin: 0 1.5%; class="rotate90"></center>
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<p><i>One of the larger genetic circuits we created for testing the behavior of our promoters in promoter-repressor cascades. (1) Estrogen diffuses into the cell and binds with the estrogen receptor. (2) Estrogen receptors will homodimerize with one another forming an activation complex. (3) Estrogen receptor will bind to our synthetic promoter (4) Production of repressor protein (5) Repressor binds to binding sites upstream of an <a href="http://parts.igem.org/Part:BBa_K2100039">eYFP</a> reporter (6) Transactivator <a href="http://parts.igem.org/Part:BBa_K2100020">Gal4-VP16</a> is constitutively produced (7) <a href="http://parts.igem.org/Part:BBa_K2100020">Gal4-VP16</a> binds to sites on pRep (8) <a href="http://parts.igem.org/Part:BBa_K2100005">eYFP</a> is produced as readout depending upon how active repressors are (9) Constituively active transfection marker <a href="http://parts.igem.org/Part:BBa_K2100012">hEF1a:mKate</a> allows us to bin and analyze the data.  </i></p>
  
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<center><a  href ="https://2016.igem.org/Team:MIT/Proof"><p style="font-family:Verdana;font-size:15px"><i>Read more about our proof of concept testing the functionality of our promoters in larger genetic circuits.</i></p> </a></center>
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<a href="https://2016.igem.org/Team:MIT/Experiments"><h1 style="color:#FFFFFF; background-color:#F20253;; -moz-border-radius: 15px; -webkit-border-radius: 15px; padding:15px; text-align: center; font-family: trebuchet MS"> Back to Experiments Home</h1></a>
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<p>References</p>
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<p>[1]Vercellini et al. <i>Nature Reviews Endocrinology</i> 10, 261
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<a href="http://www.nature.com/nrendo/journal/v10/n5/full/nrendo.2013.255.html">http://www.nature.com/nrendo/journal/v10/n5/full/nrendo.2013.255.html</a><br>
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[2] 'Introduction to Tet Systems' <i>The Jackson Laboratory</i> 2015 April 1.
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<a href = "https://www.jax.org/news-and-insights/2015/april/introduction-to-tet-expression-systems">https://www.jax.org/news-and-insights/2015/april/introduction-to-tet-expression-systems</a>
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Latest revision as of 02:34, 20 October 2016

Promoter/Receptor Group Background

Synthetic Mammalian Promoter Engineering

How does endometriosis respond to hormones?

Typical, healthy cells of the endometrium will respond in a coordinated fashion to the ovarian hormones, estrogen and progesterone, in order to create the cycles of cell turnover and growth characteristic of the menstrual cycle. Endometriosis, however, is characterized by aberrant cellular responses to estrogen and progesterone that ultimately lead to the disease phenotype.

Hormone response diagram

Estrogen Signaling Dysregulation

Endometrial cells express endogenous estrogen receptors in two forms: ER-alpha and ER-beta. When a healthy cell senses estrogen, these two estrogen receptors will be activated and trigger downstream responses by binding to sequences in the genome known as estrogen responsive elements (EREs). In diseased or endometriotic cells, estrogen signaling is pathologically upregulated leading to proliferation and migration of cells outside the uterus. [1]

Progesterone Resistance

Endometrial cells express endogenous progesterone receptors in two forms: PR-A and PR-B. When a healthy cell senses progesterone, its PR receptors are activated and trigger downstream responses by binding to different sites in the genome known as progesterone responsive elements (PREs). However, in a diseased cell, while progesterone is present, it does not co-activate the progesterone receptors, and in turn does not result in any downstream effects. This disruption in the cell's normal response to progesterone is known as progesterone resistance. Research has implicated perturbations in key progesterone signaling intermediates such as HOXA10, FOX01, NFkB in causing progesterone resistance [1].

Hence, we created sensors for estrogen signaling and progesterone signaling that were transfected into a variety of cell lines. Functional estrogen and progesterone signaling sensors could label a cell having both pathologically upregulated estrogen signaling and pathologically downregulated progesterone signaling as diseased.



How can our circuit detect hormones?


TRE to pERE promoters

To create sensors for estrogen and progesterone signaling, our team decided to create synthetic mammalian promoters that could interact with the estrogen and progesterone receptors. We based our design off of the standard tetracycline inducible Tet-On and Tet-Off systems[2], which features the TRE_tight promoter. Where the TRE_tight promoter has tetO binding sites for the reverse tetracycline-controlled trans-activator (rtTA) to bind, we replaced them with binding sites for the estrogen receptor, EREs, and binding sites for the progesterone receptor, PREs. We preserved the same minimal promoter used in the TRE_tight promoter, minCMV, derived from the cytomegalovirus.

We expanded on this design by varying the binding sites for the estrogen receptor and progesterone receptor creating the constructs pERE3, pERE5, pERE6, pPRE3, pPRE4 which contain the specified number of receptor binding sequence. We also created a hybrid construct that contains five binding sites for the estrogen receptor interspersed with five binding sites for the progesterone receptor.


Do our synthetic promoters work?


We demonstrated the success of our progesterone and estrogen inducible mammalian promoters in a variety of cell lines under different conditions:

  • pERE3, pERE5, pERE6 demonstrated successful estrogen signaling sensing in MCF7.
  • pERE5 demonstrated successful estrogen signaling sensing in ISH.
  • pERE3 demonstrated successful estrogen signaling sensing in tHESC
  • pHybrid demonstrated successful estrogen signaling sensing in MCF7.
  • pHybrid demonstrated successful progesterone signaling sensing in tHESC.
  • pPRE4 demonstrated limited success of progesterone signaling sensing in MCF7.

MCF7 cells above are transfected with our construct pEREx3 - eYFP, which contains three binding sites for the estrogen receptor upstream of a minimal promoter and yellow fluorescent gene. Cytometry data demonstrated an 11 fold increase in the transcriptional activity of our promoters when transfected into the MCF7 cell line. Since our transfection efficiency was poor (< 10%) in several of the more difficult-to-transfect cell lines we worked with, we relied primarily on the cytometry data linked below to reach conclusions about the functionality of our promoter instead of the brightfield imaging shown here.


A sampling of some of the cytometry data used to confirm the function of our promoters in various cell lines. Shown here is cytometry data of promoter function in MCF7 - full extended results for all promoters linked below.


Read more about the extended series of experiments testing the functionality of our promoters.


How do our promoters behave in larger circuits?

The true test of a robust part is its consistent behavior in larger genetic circuits. So, after demonstrating the functionality of our estrogen and progesterone inducible promoters, we next sought to create larger genetic circuits with them. We built estrogen inducible promoter - repressor cascades, as well as estrogen inducible promoter - recombinase and only met with limited success when transfecting our genetic circuits into various cell lines.

One of the larger genetic circuits we created for testing the behavior of our promoters in promoter-repressor cascades. (1) Estrogen diffuses into the cell and binds with the estrogen receptor. (2) Estrogen receptors will homodimerize with one another forming an activation complex. (3) Estrogen receptor will bind to our synthetic promoter (4) Production of repressor protein (5) Repressor binds to binding sites upstream of an eYFP reporter (6) Transactivator Gal4-VP16 is constitutively produced (7) Gal4-VP16 binds to sites on pRep (8) eYFP is produced as readout depending upon how active repressors are (9) Constituively active transfection marker hEF1a:mKate allows us to bin and analyze the data.

Read more about our proof of concept testing the functionality of our promoters in larger genetic circuits.

Back to Experiments Home

References


[1]Vercellini et al. Nature Reviews Endocrinology 10, 261 http://www.nature.com/nrendo/journal/v10/n5/full/nrendo.2013.255.html
[2] 'Introduction to Tet Systems' The Jackson Laboratory 2015 April 1. https://www.jax.org/news-and-insights/2015/april/introduction-to-tet-expression-systems