Team:Slovenia/PROJECT/oscillator/exp

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Chuck Norris facts:

oscillator

Contents

Selection of versatile genetic oscillator building blocks

It hass been previously demonstrated that besides in prokaryotic systems T7 RNA polymerase is functional also in mammalian cells (Stein and Moss, 1990, Slovenian iGEM team 2007). It is also highly processive and selective for the specific T7 promoter. As such T7 RNA polymerase seemed an ideal driving force for orthogonal oscillators. When selecting repressor proteins for our system we soon realized that there are not enough natural repressors with matched properties, which would enable testing repressilators with at least five repressors in the cycle. Therefore we explored the use synthetic DNA-binding proteins. Synthetic DNA binding proteins of same type should have similar affinity, folding, stability and degradation properties. Matching of those properties is essential for sustained oscillations.

At the end we decided to investigate the function of TAL repressor for Smollen oscillator and zinc fingers for repressilator. Repressor based on TAL effector was designed de novo and zinc fingers were selected from the literature. There is also a database on the internet with more than 700 experimentally tested [http://bindr.gdcb.iastate.edu:8080/ZiFDB/ zinc finger domains]. When selecting zinc fingers we tried to avoid those, which would interfere with the normal cellular functions. All selected zinc fingers have high affinity for predicted DNA site and on the other hand do not bind to similar sequences. Also check our page about selecting DNA binding proteins.

Another question was if it is possible to repress transcription from the T7 promoter. It was previously shown that T7 promoter can be repressed by binding of Lac repressor to the target sequence as far as 18 nucleotides downstream of T7 promoter (Lopez et al., 1998). We used same principle but incorporated TAL or zinc finger binding sequence downstream of the promoter instead of Lac operator. This approach provides practically unlimited number of promoters for with matched characteristics for driving expression of oscillator components. Our next milestone was to test the function of artificial repressors in the biological system.

Cloning strategy


For Smolen type of oscillator (nicknamed NICilator) we fused the Tet operator downstream of T7 promoter. TAL repressor was designed in a way to bind to the Tet operator This selection provided the possibility to use the natural Tet repressor in the NICillator as the positive control. Venus yellow fluorescent protein was used as a reporter, because of its short maturation time. To enhance degradation speed of the reporter CL1 and PEST sequences were tagged to its C-terminal end. This was intended to prevent excessive accumulation of fluorescent reporter which would prevent online measurement of oscillations. In order to examine how the stability of different components influences the oscillation period, we also made several combinations of repressor protein and T7 RNA polymerase with degradation tags. Small amount of T7 RNA polymerase under the control of constitutive cytomegalovirus promoter was included into the system to ensure the start of oscillations and their maintenance. Transcriptional terminator was placed at the end of all constructs.