Team:DTU Denmark/genetic design

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Theoretical background


The redoxilator

- Introduction
- Results
- Applications and perspectives


The USERTM assembly standard

- Principle
- Proof of concept
- Manual


USERTM fusion primer design software

- Abstract
- Instructions
- Output format

The project


Genetic design

We have designed and physically constructed a genetic system that couples the intracellular NAD+/NADH level to the gene expression of a reporter protein. The system has potentially many applications including in vivo online monitoring of the redox poise, production optimization and cancer research with yeast as a model organism (see Applications).

The NAD+/NADH ratio is sensed by a system originating in Streptomyces coellicolor. In S. coellicolor the protein REX is a repressor and controls the gene expression of multiple genes by recognizing and binding to a specific DNA-sequence termed ROP (Rex operator). NAD+ and NADH compete to associate with Rex, but only a REX:NAD+ association can bind the ROP DNA-sequence (Brekasis and Paget, 2003).

In S. coellicolor REX DNA binding represses expression of target genes, by physically hindering RNA-polymerases from binding the promoter. As the transcription machinery of eukaryotes is different and more complicated, there are no guarantee that repression will be effective in eukaryotes. REX has therefore been fused to a eukaryotic transcriptional activator, a widely used technique applied for the investigation of the GAL proteins and other systems (Sadowski et al. 1988). The REX-activator fusion-protein is able to bind the ROB sequence placed upstream of a minimal eukaryotic promoter that only supports transcription upon activation. A certain NAD+/NADH ratio will activate the Redoxilator to recognize the ROB promoter, resulting in transcription of the reporter gene.


The redox coupled system

The redox coupled system

Gene design and redox regulation
A: The Rex gene has been fused to an activator domain and is transcribed constitutively, leading to constant concentration of the Rex-activator protein in the cell. The ROB sequence and a minimal promoter is followed by a reporter gene, which is only be transcribed when the REX-activator fusion protein is bound to the promoter. B: The REX-activator only binds the ROB DNA sequence under the condition of having NAD+ bound. Under these circumstances the fused activator domain summons the RNA polymerase and the reporter gene is transcribed


Design specifications
The genetic system consists of two synthetic genes: one coding for the REX-activator fusion protein, and one coding for a yeast optimized GFP gene under control of ROB fused to a minimal promoter. With this system GFP is only be expressed when REX-Activator is bound to ROB, which occurs at high NAD+/NADH levels.

Simplified schematic representation of the synthetic genetic system on the DNA-level. The individual parts are described below.

The genetic elements and the requirements they need to fulfill are listed in the following table. The detailed description of the used genetic elements will not be made publicly available due to IP rights. The elements have been selected solely on their properties, and are from a variety of organisms - several of them are biobricks. All elements are codon optimized for S. cerevisiae


The genetic elements are from a variety of organisms.


Modelling
To guide the design process, and to simulate how our genetic device would operate in vivo, we performed thorough mathematical modelling of the relation between the input and output of our system (the detailed model is available here). The model predicts how the GFP-concentration in a transformed cell relates to the internal NAD+/NADH level (indicative of the redox state).
The model takes the following into account: i) transcription factor activation,
ii) promoter activation,
iii) synthesis and degradation of mRNA and finally,
iv) synthesis, dilution and degradation of GFP.

transcription factor activation, promoter activation, synthesis and degradation of mRNA and finally synthesis, dilution and degradation of GFP. This model formed the basis of the genetic design of the The redoxilator. Importantly it provided understanding of the influence of each of the parameters when designing the system, e.g. that in order to achieve fast response time a fast degradable GFP was needed as reporter. However, since many parameters specific for this system are not yet available, the model is not expected to make exact predictions but to ease the understanding of the design "principles"


Description and requirements of the genetic elements
constituting the Redoxilator device.

Genetic element

Required function

Constitutive promoter

Constitutive expression of REX-Activator fusion protein

Kozak sequence

Ribosome start-codon recognition and enhanced initiating of translation

REX

REX (redox regulator) that binds to ROP at high NAD+/NADH ratio

Linker

To couple two protein domains without disrupting their individual functions

Activator domain

Protein domain able to activate transcription in eukaryotes in proximity of a minimal promoter.

Nuclear Localization Sequence (NLS)

Translocation of the REX-Activator protein to the nucleus

Terminator 1

Sequence that terminates transcription

 

 

ROB

DNA sequence that REX binds at high NAD+/NADH ratio

Minimal promoter

Promoter devoid of regulatory motifs. Only expression if an activator is bound upstream.

GFP

The amount of green fluorescent protein can be quantitatively measured.

Degradation signal

Ensures fast degradation of GFP

Terminator 2

Terminates transcription. Different from terminator 1 to avoid direct repeats, which can cause the DNA to loop out.


References
[Brekasis and Paget, 2003] Brekasis, D. and Paget, M. S. B. (2003). A novel sensor of nadh/nad+ redox poise in streptomyces coelicolor a3(2). EMBO J, 22(18):4856–4865.
[Sadowski et al., 1988] Sadowski, I., Ma, J., Triezenberg, S., and Ptashne, M. (1988). Gal4-vp16 is an unusually potent transcriptional activator. Nature, 335(6190):563–564.


Synthetic Biology

“Synthetic Biology is an art of engineering new biological systems that don’t exist in nature.”

-Paras Chopra & Akhil Kamma

In nature, biological molecules work together in complex systems to serve purposes of the cell. In synthetic biology these molecules are used as individual functional units that are combined to form tailored systems exhibiting complex dynamical behaviour. From ‘design specifications’ generated from computational modelling, engineering-based approaches enables the construction of such new specified gene-regulatory networks. The ultimate goal of synthetic biology is to construct systems that gain new functions, and the perspectives of the technology are enormous. It has already been used in several medical projects2 and is predicted to play a major role in biotech-production and environmental aspects.

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