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Project Details

StressKit: A BioBrick library of Lac-repressed sigma-24, sigma-28, sigma-32 and sigma-38 promoters for Escherichia coli.

Background

Regulated gene expression is an essential part of the synthetic biologist's toolkit. The Registry of Standard Biological Parts contains a growing number of promoters whose expression can be controlled externally, using chemical signals such as IPTG and arabinose, or physical signals such as light or temperature shifts. In contrast to such specific sensors, bacteria have evolved 'generalized stress response systems' which subtly integrate several sources of information, and when necessary generate genome-wide changes in patterns of gene expression. This is achieved by the activation of 'alternative sigma factors' which displace the 'housekeeping sigma factor' from the RNAP holoenzyme, causing it to activate transcription at specific sigma-dependent promoters. We set out to design, construct, and validate a library of sigma-dependent promoters for Escherichia coli, with the following design specifications:

Physical specification: The promoters must conform to the BioBrick format, and expression must be quantifiable using an existing BioBrick fluorescent reporter. This ensures that our library can be used immediately in conjunction with Registry parts.
Functional specification: The promoters must be 'gated' by the LacI repressor, so they remain switched off unless a Lac inducer such as IPTG is present. In the presence of IPTG, the promoter must behave like a 'bare' sigma-factor-dependent promoter, expressing only under specific stress conditions.
Modularity: The entire library of promoters must have the same design format; each promoter must involve a minimal DNA region, and must not require any transcription factors apart from LacI and the relevant sigma factor; and the promoters must have minimal cross-talk. This ensures that that different sigma-dependent responses can be directly compared, and if necessary combined into the same device, with no additional components required.

Design of promoters as a fusion between a lac and sigma dependent promoter

σ Factors

Escherichia coli has seven sigma factors, of which we deal with four: sigma-24 mediates the unfolded-protein response; sigma-28 mediates flagellar biosynthesis; sigma-32 mediates the heat-shock response; and sigma-38 is involved in stationary-phase expression. We need not or cannot deal with the remaining three: sigma-70 is the housekeeping factor; sigma-19 mediates the iron-starvation response, but only two of its promoters are known; and sigma-54 mediates the nitrogen-starvation response, but all its promoters require an additional transcriptional activator.

Design of promoters as a fusion between a lac and sigma dependent promoter

Design Logic

Sigma factors drive transcription by binding to specific nucleotide signatures at the -10 and -35 boxes of their cognate promoters. We started our design process with the LacO promoter of Lutz and Bujard, which contains two LacI binding sites, and sigma-70 boxes. Using published experimental and bioinformatic data, we generated 'hybrid' promoters in which the sigma-70 boxes were partially replaced with alternative sigma boxes, with minimal disruption to the LacI binding sites. In this manner, we designed four hybrid promoters for each alternative sigma factor.

Design of promoters as a fusion between a lac and sigma dependent promoter

Part Construction and Experimental Validation

We generated the promoter regions along with the BioBrick prefix and suffix by total synthesis, and cloned them upstream of a YFP expression construct (BBa_E0430). To measure YFP expression, we use a spectrophotometer for population-averaged measurements, and a fluorescent microscope for single-cell measurements. We are currently characterizing the library of promoters against a standard control, the unmodified Lutz-Bujard LacO promoter.

Design of promoters as a fusion between a lac and sigma dependent promoter

@@ Line 11: / Line 11: @@
 =Project Details=
+StressKit: A BioBrick library of Lac-repressed sigma-24, sigma-28, sigma-32 and sigma-38 promoters for Escherichia coli.
-==Introduction==
+==Background==
 {|align=center width=80%
-|After months of brainstorming and evaluating a large number of other ideas, we defined our problem statement as follows,
+|Regulated gene expression is an essential part of the synthetic biologist's toolkit. The Registry of Standard Biological Parts contains a growing number of promoters whose expression can be controlled externally, using chemical signals such as IPTG and arabinose, or physical signals such as light or temperature shifts. In contrast to such specific sensors, bacteria have evolved 'generalized stress response systems' which subtly integrate several sources of information, and when necessary generate genome-wide changes in patterns of gene expression. This is achieved by the activation of 'alternative sigma factors' which displace the 'housekeeping sigma factor' from the RNAP holoenzyme, causing it to activate transcription at specific sigma-dependent promoters. We set out to design, construct, and validate a library of sigma-dependent promoters for Escherichia coli, with the following design specifications:
-<blockquote>''Is it possible to make bacteria respond to physical changes in a customizable way?''</blockquote>
+# Physical specification: The promoters must conform to the BioBrick format, and expression must be quantifiable using an existing BioBrick fluorescent reporter. This ensures that our library can be used immediately in conjunction with Registry parts.
+# Functional specification: The promoters must be 'gated' by the LacI repressor, so they remain switched off unless a Lac inducer such as IPTG is present. In the presence of IPTG, the promoter must behave like a 'bare' sigma-factor-dependent promoter, expressing only under specific stress conditions.
+# Modularity: The entire library of promoters must have the same design format; each promoter must involve a minimal DNA region, and must not require any transcription factors apart from LacI and the relevant sigma factor; and the promoters must have minimal cross-talk. This ensures that that different sigma-dependent responses can be directly compared, and if necessary combined into the same device, with no additional components required.
-First, we analyze the question piecewise. How exactly do bacteria adapt to physical changes in their environment? Typically, these physical parameters comprise of temperature, pH, salt concentration, oxidation potential and nutrient concentration. These stresses pose a challenge to the organisms' survival. The lead for the idea was when we came across heat shock and the response it elicits in ''lactococcus''. This phenomenon of temperature rise being related to DnaK levels was exactly the kind of system we wanted to develop on.
+!valign=top|[[Image:IITMpromoters.jpg|thumb|Design of promoters as a fusion between a lac and sigma dependent promoter]]
+|}
-How are bacteria able to selectively switch on expression of a small subset of proteins based on a change in temperature, or any other physical parameter? The very ability of bacteria to accomplish this points to a transduction mechanism. They must transduce physical changes into gene expression. In this light, it is interesting to know that &sigma; 32, a subunit of the RNA Polymerase Holoenzyme, twists into a functional conformation only on a rise in temperature. Further, this &sigma; subunit confers sequence selectivity to RNA Polymerase, directing it to different promoter sites. Without this &sigma; factor, RNA Polymerase has a very indiscriminate binding behaviour.
+==&sigma; Factors==
+{|align=center width=80%
+|Escherichia coli has seven sigma factors, of which we deal with four: sigma-24 mediates the unfolded-protein response; sigma-28 mediates flagellar biosynthesis; sigma-32 mediates the heat-shock response; and sigma-38 is involved in stationary-phase expression. We need not or cannot deal with the remaining three: sigma-70 is the housekeeping factor; sigma-19 mediates the iron-starvation response, but only two of its promoters are known; and sigma-54 mediates the nitrogen-starvation response, but all its promoters require an additional transcriptional activator.
-To deal with different environmental niches, bacteria employ a family of such &sigma; factors. They express different sets of proteins in an attempt to adapt to these varying conditions. The exact number of these factors changes from one species to another, with the more exotic ones having a larger number. This reflects on the degree of specialization of an organism to survive different conditions. For example, ''E. coli'' has 7 &sigma; subunits while ''S. coelicolor'' has over 60.
+!valign=top|[[Image:IITMpromoters.jpg|thumb|Design of promoters as a fusion between a lac and sigma dependent promoter]]
+|}
-E.Coli has a family of 7 &sigma; subunits to partition it's genome into various programs. This division is as follows,
-# &sigma;<sup>70</sup>, <tt>rpoD</tt>: Houskeeping genes
-# &sigma;<sup>54</sup>, <tt>rpoN</tt>: Activated on nitrogen starvation
-# &sigma;<sup>38</sup>, <tt>rpoS</tt>: Master regulator for a generalized stress response
-# &sigma;<sup>32</sup>, <tt>rpoH</tt>: Activated on increase in unfolded proteins
-# &sigma;<sup>28</sup>, <tt>rpoF</tt>: Initiates flagellar biosynthesis
-# &sigma;<sup>24</sup>, <tt>rpoE</tt>: Activated on rise of unfolded proteins in the cellular envelope
-# &sigma;<sup>19</sup>, <tt>FecI</tt>: Activated on iron starvation
-We used the database <tt>ecocyc.org</tt> to survey the genes being controlled by these different sigmas and how exactly are they induced. Identifying and isolating the promoters of these genes would be the next step. A library of promoters which would be expressed by these different sigmas would make for novel BioBricks.
-These new promoters would cover the different environmental stresses that E.Coli responds to. Being designed within the specifications set out by the parts registry, it would be extensible with all the existing devices. A point to appreciate is that these promoters, unlike <tt>pLac</tt>, are expressed without ''any'' external chemical for induction and yet are not constitutive. This sets it apart in a league of environmental context specific promoters without the need for external inducer.
+==Design Logic==
+{|align=center width=80%
+| Sigma factors drive transcription by binding to specific nucleotide signatures at the -10 and -35 boxes of their cognate promoters. We started our design process with the LacO promoter of Lutz and Bujard, which contains two LacI binding sites, and sigma-70 boxes. Using published experimental and bioinformatic data, we generated 'hybrid' promoters in which the sigma-70 boxes were partially replaced with alternative sigma boxes, with minimal disruption to the LacI binding sites. In this manner, we designed four hybrid promoters for each alternative sigma factor.
 !valign=top|[[Image:IITMpromoters.jpg|thumb|Design of promoters as a fusion between a lac and sigma dependent promoter]]
 |}
-==Promoter Design==
+==Part Construction and Experimental Validation==
 {|align=center width=80%
-|The promoter sequences of a number of genes regulated by the different &sigma;s were compiled. See the adjacent table for the list of genes that we obtained from <tt>ecocyc.org</tt> and other literature references.
+|We generated the promoter regions along with the BioBrick prefix and suffix by total synthesis, and cloned them upstream of a YFP expression construct (BBa_E0430). To measure YFP expression, we use a spectrophotometer for population-averaged measurements, and a fluorescent microscope for single-cell measurements. We are currently characterizing the library of promoters against a standard control, the unmodified Lutz-Bujard LacO promoter.
-Their mode of regulation was also looked into. Apart from being just selected for transcription by a &sigma; factor, genes are further regulated by both repressors and enhancers. On many occasions, transcription isn't possible without the presence of these regulatory elements. This poses an additional complexity in the isolation of a promoter segment as ''cis'' regulatory elements need to be incorporated. We had to circumvent this problem as it would greatly increase the length of our BioBricks. But more importantly, the exact region of these ''cis'' acting elements are not well documented.
-To resolve this, we looked into the structural requirements for &sigma; factor + RNA Polymerase, the holoenzyme, to bind DNA. Broadly, the sigmas fall into either a &sigma;<sup>70</sup> or a &sigma;<sup>54</sup> structural family. The &sigma;<sup>54</sup> family of &sigma; subunits cannot start transcription without an activating element. This activator has to structurally alter &sigma;<sup>54</sup>. This rules out its incorporation in our StressKit.
-For the remaining 6 &sigma;s, the binding pattern is similar to &sigma;<sup>70</sup>s. They involves base specific interactions only in the -10 and -35 box of the promoter, where +1 is taken to be the transcription start site. Under each category of &sigma;s, there are a number of genes (See TABLE) with different promoter sequences. These sequences were analyzed for a consensus sequence in the -10 and -35 region. This consensus sequence should give a good idea about the critical length of bases bound by the &sigma; factor.
-Now, we can enhance this promoter design by incorporating a easily accessible form of regulation; IPTG based induction. We took the <tt>pLac</tt> synthetic promoter designed by Bujard et al
-UNDER CONSTRUCTION
 !valign=top|[[Image:IITMpromoters.jpg|thumb|Design of promoters as a fusion between a lac and sigma dependent promoter]]
 |}

Team:IIT Madras/Project

From 2008.igem.org

Revision as of 14:16, 29 September 2008

Contents

Project Details

Background

σ Factors

Design Logic

Part Construction and Experimental Validation