Team:TU Munich/Project/Light Switchable Promoter


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Light-Switchable Promoter

Responsible: Jeffery Truong

The so-called "Reinheitsgebot" or "Bavarian Beer Purity Law" forbids the use of any ingredients other than water, barley and hops. Hence, to be able to control the expression of our pathways in yeast, a promoter which does not rely on any chemical additive.

The light switchable promoter, does not only comply with these needs, it is also easy, cheap and very precisely applicable. Furthermore, as the expression of the downstream gene can be upregulated as well as downregulated by variation of red light and far red light ratio respectively.

Therefore it allows high spatio-temporal control over the genes downstream of the promoter.

Background and Principles

This system bases on the yeast two-hybrid system which was originally created for exploring protein-protein interactions. One candidate of a potential protein-interaction pair is fused to the DNA-binding domain of a transcription factor and the other candidate to the activation domain of a transcription factor. If the proteins candidates are really physically interacting with each other, this event will starts the transcription of downstream reporter genes, e. g. LacZ or an auxotrophic marker.

Reverse Yeast-Two Hybrid Based Light-Switchable Promoter System

This basic principle is utilized in the yeast light-switchable promoter system. But in contrast to yeast-two hybrid, we already know the interaction partners (PhyB and PIF3). The photoconvertible binding of PhyB to PIF3 is used, to recover the physical contiguity of the DNA binding domain and the transcriptional activation domain under defined conditions (red light).

Fig. 1 Principle of light-dependent switching of gene-expression.

This light-inducible system contains two proteins, phytochrome B (PhyB) and phytochrome interacting factor 3 (PIF3). PhyB and PIF3 will just form a heterodimer, if PhyB is exposed to red light. Exposition under red light leads to a conformation change of PhyB to its active form (Pfr-form); the Pfr form of PhyB now can bind PIF3. PhyB comprises a light-absorbing chromophore phycocyanobilin, which gives PhyB the ability to undergo a photoconversion to the active Pfr form (red light exposition) or back to its ground-state Pr (far-red light exposition or darkness).

GAL4 Based Light-Switchable Promoter System

In our first case we create two constitutively expressed fusion proteins, the first one is PhyB fused to GAL4DBD for the DNA binding part (BBa_K801040 and the second one is PIF3 fused to GAL4AD for the transcriptional activating part (BBa_K801039). This system allows us to control spatio-temporally the expression of our genes coded on pTUM104 and driven by the GAL1 promoter (The TATA-box of pGAL1 is preceded by binding elements for GAL4). To prevent interference with the endogenous GAL4 system of yeast, we are using the Y190 S. cerevisiae strain, which has an GAL4/GAL80 deletion.

One great advantage of the GAL4 based system is that we can use all our constructs which we have first cloned downstream of a GAL1 promoter without further cloning steps! But the disadvantage is that we have to use a yeast strain carrying a GAL4/GAL80 deletion.

If you want to use a supermarket yeast or a brewing strain you have to use the LexA based light-switchable promoter system, described in the next section.

LexA Based Light-Switchable-Promoter System

In contrast to the GAL4 based light-switchable promoter system there is no need for KO of GAL4/GAL80 genes in yeast with a LexA based light-switchable promoter system. The difference is that we use LexA, a prokaryotic DNA binding protein, for the DNA binding part of our light-switchable promoter system, instead of GAL4DBD. LexA does not interfere with the endogenous yeast metabolism and signaling system because it only recognizes a special prokaryotic DNA sequence, the so-called LexA operator (=LexA binding site). LexA binding sites can be used upstream of a minimal promoter (=TATA box) to be utilized as a cis-acting regulatory element.

In this case the genes, which we want to control by light, have to be cloned downstream of a synthetic promoter containing a minimal promoter, preceded by multiple LexA binding sites, e. g. BBa_K165031.

In distinction from the GAL4 based system there is no necessity for a special strain carrying an GAL4/80 deletion, so theoretically every yeast strain can be used for this system.

Biosynthesis of Phycocyanobilin

Phycocyanobilin undergoes a Z-E isomerization to its active form in case of red light and an E-Z isomerization to its inactive form in case of far-red light. The half-life of its active form Pfr is ~30 min, so continuous red light exposition is not necessary. A great advantage is that light-sensitive odorant and flavorings will not be destroyed. Once phycocyanobilin is not naturally available in yeast one have to add the tetrapyrrole light-absorbing chromophore phycocyanobilin to the medium to get a functional light-switchable promoter system. But it also possible to bring the capability of phycocyanobilin synthesis in yeast by metabolic engineering. From heme, which is endogenous in yeast, there are only two steps of biosynthesis away from phycocyanobilin. The first step of phycocyanoblin is catalyzed by a heme oxygenase, the second step by a phycocyanobilin:ferredoxin oxidoreductase.

Fig. 2: Biosynthesis pathway of phycocyanobilin from heme to phycocyanobilin (PCB).
Fig. 3: Cavity of PCB binding pocket of PhyB, predicted by I-TASSER. The next most homologue protein is illustrated in cyan, the cyanobacterial phytochrome CPH1 2VEA. The golden ribbon indicates the predicted structure of PhyB. The sulfhydryl group of the Arabidopsis chromophore-binding cysteine residue is co-ordinated with the position of the ethylidene moiety on the chromophore sufficiently closely and in the correct conformation to form the thioether bond by which the chromophore is known to be covalently attached.

Induction Setup

An array of 10 LEDs with emission peak at 660 nm [1] were attached into the molds of the packaging of 2 ml cuvettes and soldered together on the rear side of the packaging. As the cuvettes are the very ones that will later be used for illumination of the cells, the use of the packaging as LED matrix will allow quick removal during measurements and enhance accuracy of results.

Literature suggest pulsed illumination of the cells with a pulse duration of 10  and a pulse frequency of 1 pulse every 10 minutes. The LEDs are actuated with an Arduino UNO microcontroller that realizes the suggested protocol. The use of a microcontroller will allow us to easily test differrent pulse lengths and frequencys.


Components of the Light-Switchable Promoter Systems

Two fusion proteins will be needed for a light-switchable promoter system. The first one is PIF3 fused to GAL4AD (BBa_K801039), the second one is GALDBD (GAL4 based) or LexA (LexA based) fused to PhyB (BBa_K801040 or BBa_K801041).

For PhyB and PIF3 we didn't used the whole protein coding sequence for our fusions. For PhyB we used the first 908 N-terminal amino acids which has been mapped to be sufficient for reversible photoconversion. Also for PIF3 only the first 100 N-terminal amino acids has been taken for our fusions due to the fact that they has been mapped to be only necessary for light-switchable binding to PhyB.

We successfully created all fusion proteins for a light-switchable promoter system based on GAL4 and LexA and even created a TEF1 promoter driven expression battery for all our components, for each type of the system (GAL4 and LexA based).

Simplified cloning scheme for the GAL4 (A) and the LexA (B) based gene expression battery.
  • Fusion protein for the first component (GAL4/LexA based):

BBa_K801039: SV40NLS-GAL4AD-Linker-PIF3

  • Fusion protein for the second component (GAL4 based):

BBa_K801040: SV40NLS-PhyB-Linker-GAL4DBD

  • Fusion protein for the second component (LexA based):

BBa_K801041: SV40NLS-PhyB-Linker-LexA

  • TEF1 promoter driven gene expression battery for all parts of the GAL4 based light-switchable-promoter system:

BBa_K801042: pTEF1_SV40NLS-GAL4AD-Linker-PIF3_tTEF1_pTEF1_SV40NLS-PhyB-Linker-GAL4DBD_tTEF1

  • TEF1 promoter driven gene expression battery for all parts of the LexA based light-switchable-promoter system:

BBa_K801043: pTEF1_SV40NLS-GAL4AD-Linker-PIF3_tTEF1_pTEF1_SV40NLS-PhyB-Linker-GAL4LexA_tTEF1

Components for Reporter Systems

GAL4 Based Reporter Rystems

For the GAL4 based light-switchable promoter system we have endogenous reporters in the Y190 S. cerevisiae strain.

The first one is an auxotrophic reporter for HIS3, an imidazoleglycerol-phosphate dehydratase, which catalyzes the sixth step in histidine biosynthesis. HIS3 is driven by a synthetic promoter with upstream GAL4 responsive elements. If plated on or inoculated in histidine deficient medium, there should be no growth of yeast, if they will be incubated in darkness or far-red light conditions. But under red light conditions the auxotrophy is reverted by expression of HIS3 due to the recruitment of GAL4AD through PhyB-PIF3 interaction.

The second reporter is LacZ, a beta-galactosidase, which will be controlled by pGAL1. Beta-galactosidase will be only expressed, if the light-switchable promoter system is switched on by red light.

LexA Based Reporter Systems

For the LexA based light-switchable promoter system we have to transfect yeast with a second plasmid coding for the reporter construct because there is no endogenous reporter system like for the GAL4 based system. Furthermore we didn't used the GAL4/GAL80 deletion strain Y190 in contrast to the GAL4 based system, since there is no need for the deletion because there is no interference between the prokaryotic LexA system the endogenous yeast signaling and the metabolism pathways.

We've successfully cloned a luciferase from Renilla reniformis (BBa_J52008) downstream of a minimal CYC1 promoter preceded by LexA binding sites (BBa_K165031).

Extraction of PCB

Since there is no endogenous phycocyanobilin (PCB) in yeast, we have to add it to the medium first for our first proof-of-concept experiments. Later, we can implement the enzymes for the biosynthesis of phycocyanobilin (BBa_I15008 and BBa_K181000) also in the finished gene expression batteries for our light-switchable promoter systems(BBa_K801042 and BBa_K801043).

  • Phycocyanobilin is extracted by methanolysis of dried Spirulina platensis. For detailed information please see our methods section
  • The extracted phycocyanobilin is resuspended in DMSO and is kept at -20 °C until use.
  • Absorption Spectrum for concentration determination.
Absorption spectrum of the extracted phycocyanobilin

TUM12 formula PCBconc determination.jpg

Sample of the phyocyanobilin colloid


  • [Chen et al., 2005] Chen, M., Tao, Y., Lim, J., Shaw, A., and Chory, J. (2005). Regulation of phytochrome B nuclear localization through light-dependent unmasking of nuclear-localization signals. Curr Biol, 15(7):637–42.
  • [Kikis et al., 2009] Kikis, E. A., Oka, Y., Hudson, M. E., Nagatani, A., and Quail, P. H. (2009). Residues clustered in the light-sensing knot of phytochrome B are necessary for conformer-specific binding to signaling partner PIF3. PLoS Genet, 5(1):e1000352.
  • [Levskaya et al., 2009] Levskaya, A., Weiner, O. D., Lim, W. A., and Voigt, C. A. (2009). Spatiotemporal control of cell signalling using a light-switchable protein interaction. Nature, 461(7266):997–1001.
  • [Mendelsohn, 2002] Mendelsohn, A. R. (2002). An enlightened genetic switch. Nat Biotechnol, 20(10):985–7.
  • [Shimizu-Sato et al., 2002] Shimizu-Sato, S., Huq, E., Tepperman, J. M., and Quail, P. H. (2002). A light-switchable gene promoter system. Nat Biotechnol, 20(10):1041–4.
  • [Khanna et al., 2004] Khanna, R., Huq, E., Kikis, E. A., Al-Sady, B., Lanzatella, C., and Quail, P. H. (2004). A novel molecular recognition motif necessary for targeting photoactivated phytochrome signaling to specific basic helix-loop-helix transcription factors. Plant Cell, 16(11):3033–44.
  • [Gambetta and Lagarias, 2001] Gambetta, G. A. and Lagarias, J. C. (2001). Genetic engineering of phytochrome biosynthesis in bacteria. Proc Natl Acad Sci U S A, 98(19):10566–71.
  • [Ni et al., 1999] Ni, M., Tepperman, J. M., and Quail, P. H. (1999). Binding of phytochrome B to its nuclear signalling partner PIF3 is reversibly induced by light. Nature, 400(6746):781–4.
  • [Van Criekinge and Beyaert, 1999] Van Criekinge, W. and Beyaert, R. (1999). Yeast two-hybrid: State of the art. Biol Proced Online, 2:1–38.
  • [Wertman and Mount, 1985] Wertman, K. F. and Mount, D. W. (1985). Nucleotide sequence binding specificity of the LexA repressor of Escherichia coli K-12. J Bacteriol, 163(1):376–84.