Duke/Projects/efatf

From 2007.igem.org

(Difference between revisions)
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Experience in previous iGEM contests has shown that genetic circuits can be fickle, noisy and inhomogeneous, in contrast to electric circuits which are easily controllable but lack the breadth and variety of
Experience in previous iGEM contests has shown that genetic circuits can be fickle, noisy and inhomogeneous, in contrast to electric circuits which are easily controllable but lack the breadth and variety of
biological components. In order to enhance the controlability of genetic circuits, we are targeting the lifeblood of genetic circuits, the transcription factors, by attempting to guide their function with macroscopic inputs. '''The goal of this project is the creation of an electric-field activated transcription factor protein which will initialize transcription only in the presence of an applied, low-strength (10^3-10^5 V/m) alternating electric field.'''
biological components. In order to enhance the controlability of genetic circuits, we are targeting the lifeblood of genetic circuits, the transcription factors, by attempting to guide their function with macroscopic inputs. '''The goal of this project is the creation of an electric-field activated transcription factor protein which will initialize transcription only in the presence of an applied, low-strength (10^3-10^5 V/m) alternating electric field.'''
 +
 +
There exists an artificial sequence of amino acids that is more susceptible to chemical or conformational change in the presence of electric fields than those sequences of natural proteins, such that the proper application of an electric field to the susceptible protein will result in activation or inactivation of the function of only this protein.
The design aims to accomplish this goal by modifying the ‘flexible arm’ of the λcI repressor such that an applied electric field will stabilize the altered protein in an otherwise unfavorable binding with its operator site. λcI repressor This can be accomplished by screening a library of 'flexible arm' mutants, the results of which can be further screened using directed evolution techniques to yield the protein which matches the above specifications. As most proteins are fairly resistant to conformational perturbations due to electric fields , this project focuses on isolating those amino acid sequences which are particularly susceptible to electric fields.
The design aims to accomplish this goal by modifying the ‘flexible arm’ of the λcI repressor such that an applied electric field will stabilize the altered protein in an otherwise unfavorable binding with its operator site. λcI repressor This can be accomplished by screening a library of 'flexible arm' mutants, the results of which can be further screened using directed evolution techniques to yield the protein which matches the above specifications. As most proteins are fairly resistant to conformational perturbations due to electric fields , this project focuses on isolating those amino acid sequences which are particularly susceptible to electric fields.
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==Results==
==Results==
-
Below shows BBa_S03819 both with wild-type λcI proteins unbound to DNA (not present because they are not induced with IPTG) and bound to DNA (wild type λcI proteins are induced with IPTG and present). The red fluorescence along the edges of the uninduced λcI are a result of individual bacterial colonies on the plate with naturally low LacI concentrations, so there exists λcI in the cell; this is not a concern because in screening of the mutants the λcI is always induced (grown on plates with 0.4 uM IPTG), so whether or not the present mutant λcI's bind to DNA is the only screen. Therefore, it is clear the screen works as desired, by glowing red with bound λcI and yellow (which looks green) with unbound λcI.
+
Below shows BBa_S03819 (alpha) both with wild-type λcI proteins unbound to DNA (not present because they are not induced with IPTG) and bound to DNA (wild type λcI proteins are induced with IPTG and present). The red fluorescence along the edges of the uninduced λcI are a result of individual bacterial colonies on the plate with naturally low LacI concentrations, so there exists λcI in the cell; this is not a concern because in screening of the mutants the λcI is always induced (grown on plates with 0.4 uM IPTG), so whether or not the present mutant λcI's bind to DNA is the only screen. Therefore, it is clear the screen works as desired, by glowing red with bound λcI and yellow (which looks green) with unbound λcI.
[[Image:BBa_S03819plate.jpg]]
[[Image:BBa_S03819plate.jpg]]
 +
 +
We then attempted to test the apparatus for screening ability before concerning ourselves with the ability to apply large electric fields to bacteria; we did this by attempting to isolate a λcI which at 37C does not bind to DNA, but when heated to 45C would initiate transcription. We plated a plate of alpha_mut3 on a hot-plate set to 45C. Below is a cluster of colonies from the plate at the start of the heating, at 2 hours and at 3.5 hours. It is clear that the bacteria has a λcI which does not preferentially bind to DNA, but upon heating to 45C gains the free energy required to bind to DNA and initiate transcription.
 +
 +
[[Image:heatsensitive.jpg]]
 +
 +
Electric fields were then applied to colonies of bacteria with stainless steel electrodes coated in epoxy (to prevent conductance) attached to a function generator and placed 1 cm apart in a agar plate.
 +
 +
[[Image:electrictests.jpg]]
 +
 +
Preliminary tests with fields of 600V(peak-peak)/m at 1kHz, 10kHz, 100kHz, or 1MHz yielded no results (it wouldn't even kill the bacteria!). The heavy machinery was then brought in.
 +
 +
[[Image:electricsetup.jpg]]
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 +
The device above is a Bogen Model M06A vacuum tube audio amplifier. Originally designed to send low voltage audio signals to high voltage speakers, this device generously on loan from Dr. Rhett George is perfect to transform low  AC voltage signals into extremely high voltage signals as a result of the conditions necessary to operate vacuum tubes. It took our puny function generator signal (max voltage output 6Vp-p) and output 200Vp-p signals. Below is a picture of bacteria at various output voltage settings in the device, showing that the bacteria can survive in these settings, but probably not much more (and are probably becoming electrocompetent!)
 +
 +
[[Image:electricsurvive.jpg]]
 +
 +
As we recently acquired this hardware we are screening for electric field-sensitive proteins at lightning pace to present our findings during our presentation.

Revision as of 01:19, 27 October 2007

Contents

Electric field-activated transcription factor

Background and Motivation

Experience in previous iGEM contests has shown that genetic circuits can be fickle, noisy and inhomogeneous, in contrast to electric circuits which are easily controllable but lack the breadth and variety of biological components. In order to enhance the controlability of genetic circuits, we are targeting the lifeblood of genetic circuits, the transcription factors, by attempting to guide their function with macroscopic inputs. The goal of this project is the creation of an electric-field activated transcription factor protein which will initialize transcription only in the presence of an applied, low-strength (10^3-10^5 V/m) alternating electric field.

There exists an artificial sequence of amino acids that is more susceptible to chemical or conformational change in the presence of electric fields than those sequences of natural proteins, such that the proper application of an electric field to the susceptible protein will result in activation or inactivation of the function of only this protein.

The design aims to accomplish this goal by modifying the ‘flexible arm’ of the λcI repressor such that an applied electric field will stabilize the altered protein in an otherwise unfavorable binding with its operator site. λcI repressor This can be accomplished by screening a library of 'flexible arm' mutants, the results of which can be further screened using directed evolution techniques to yield the protein which matches the above specifications. As most proteins are fairly resistant to conformational perturbations due to electric fields , this project focuses on isolating those amino acid sequences which are particularly susceptible to electric fields.

Parts and setup

We constructed a genetic circuit as an apparatus to test whether the mutant λcI repressors would bind to DNA or not under a variety of conditions. We combined [http://partsregistry.org/Part:BBa_I5010 BBa_I5010] and [http://partsregistry.org/Part:BBa_I6036 BBa_I6036] with [http://partsregistry.org/Part:BBa_I12007 BBa_I12007] and [http://partsregistry.org/Part:BBa_I13507 BBa_I13507] to yield [http://partsregistry.org/Part:BBa_S03819 BBa_S03819], shown below, on an on an Amp resistant plasmid.

BBa S03819.jpg

BBa_S03819 contains the λcI promotor (I12007) and repressor (R0051) sequences, nearly identical parts derived from phage λ, which give the λcI repressor protein the ability to activate or repress transcription depending on where the two sequences are placed in relation to the target protein. Thus, BBa_S03819 turns bright RED when the λcI repressor is able bound to DNA (can initiate transcription at I12007 and represses transcription at R0051) and glows YELLOW when λcI repressor is unbound (does not repress transcription at R0051 and does not activate transcription at I12007).

BBa_S03819 was then PCR'd with primers 5’-ccttggatccatAAAGAGGAGAAATACTAGATGNNNNNNNNNAAGAAACCATTAACACAAGAGCAG-3’ or 5’-ccttggatccatAAAGAGGAGAAATACTAGATGNNNNNNNNNNNNNNNCCATTAACACAAGAGCAG-3’, primers with a BamHI restriction sites with random nucleic acid N sections to yield mutants of either the first three amino acids of the flexible arm or the first five amino acids of the flexible arm, respectively, with 5’-aaggggatccgtgctcagtatcttgttatcc-3’; the PCR product was then a linear library of BBa_S03819 mutated at λcI coding region. The three amino acid mutants (called in our lab 'mut3') and the five amino acid mutants ('mut5') were then digested with BamHI, ligated, transformed, and screened for DNA binding under a variety of conditions.

Results

Below shows BBa_S03819 (alpha) both with wild-type λcI proteins unbound to DNA (not present because they are not induced with IPTG) and bound to DNA (wild type λcI proteins are induced with IPTG and present). The red fluorescence along the edges of the uninduced λcI are a result of individual bacterial colonies on the plate with naturally low LacI concentrations, so there exists λcI in the cell; this is not a concern because in screening of the mutants the λcI is always induced (grown on plates with 0.4 uM IPTG), so whether or not the present mutant λcI's bind to DNA is the only screen. Therefore, it is clear the screen works as desired, by glowing red with bound λcI and yellow (which looks green) with unbound λcI.

BBa S03819plate.jpg

We then attempted to test the apparatus for screening ability before concerning ourselves with the ability to apply large electric fields to bacteria; we did this by attempting to isolate a λcI which at 37C does not bind to DNA, but when heated to 45C would initiate transcription. We plated a plate of alpha_mut3 on a hot-plate set to 45C. Below is a cluster of colonies from the plate at the start of the heating, at 2 hours and at 3.5 hours. It is clear that the bacteria has a λcI which does not preferentially bind to DNA, but upon heating to 45C gains the free energy required to bind to DNA and initiate transcription.

Heatsensitive.jpg

Electric fields were then applied to colonies of bacteria with stainless steel electrodes coated in epoxy (to prevent conductance) attached to a function generator and placed 1 cm apart in a agar plate.

Electrictests.jpg

Preliminary tests with fields of 600V(peak-peak)/m at 1kHz, 10kHz, 100kHz, or 1MHz yielded no results (it wouldn't even kill the bacteria!). The heavy machinery was then brought in.

Electricsetup.jpg

The device above is a Bogen Model M06A vacuum tube audio amplifier. Originally designed to send low voltage audio signals to high voltage speakers, this device generously on loan from Dr. Rhett George is perfect to transform low AC voltage signals into extremely high voltage signals as a result of the conditions necessary to operate vacuum tubes. It took our puny function generator signal (max voltage output 6Vp-p) and output 200Vp-p signals. Below is a picture of bacteria at various output voltage settings in the device, showing that the bacteria can survive in these settings, but probably not much more (and are probably becoming electrocompetent!)

Electricsurvive.jpg

As we recently acquired this hardware we are screening for electric field-sensitive proteins at lightning pace to present our findings during our presentation.