Team:DTU Denmark/applications private securkey Dhjg1mab2ak47

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Revision as of 20:16, 18 October 2009

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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


Applications and perspectives

There are numerous potential applications for our genetic device, but here we have highlighted three key applications: an in vivo redox sensor, improved chemostat product formation and applications in cancer research.

i) Reporter gene expression regulated by the Rexivator – an in vivo redox sensor

The gene encoding green fluorescent protein (GFP) is widely used as a reporter gene in molecular biology. By placing the ROB promoter upstream of a GFP gene on a plasmid, and transforming the whole system into a yeast cell, GFP will be expressed at certain NAD+/NADH levels. When the Rexivator is bound to DNA, GFP expression will produce a visible and quantitatively measurable signal, which will be an indirect measure of the NAD+/NADH ratio.


The redox coupled system

Figure 2 – Schematic overview of overall approach.
After the design, synthesis and transformation of the NAD+/NADH sensor, online measurement of reporter gene expression will be measured and oscillative behaviour of the productivity will be evaluated and used for further optimization.


The measuring of cellular NAD+/NADH levels is usually a difficult process, especially due to fast changes in NAD+/NADH ratio that can occur when a sample is taken and exposed to slightly new conditions. With this sensor system, the quantitative measurement of the reporter gene will provide a fast and reliable way to determine the NAD+/NADH ratio in vivo. The plasmid can be transformed into a yeast strain allowing the NAD+/NADH ratio to be continuously monitored. As an example this plasmid can be used to study whether an engineered yeast strain has an altered NAD+/NADH ratio. The plasmid can be transformed into different yeast strains (e.g. wild type versus an engineered strain or two production strains) and the NAD+/NADH ratio can be compared.


ii) Product formation regulated by the Rexivator – an attempt to improve and prolong chemostat processes

When S. cerevisiae are grown continuously in a chemostat, the productivity of e.g. antibiotic or protein product gradually decreases [Personal correspondence with Novo Nordisk A/S]. This occurs during maximum production and is believed to be the result of metabolic adaption8 with reduced product formation as a consequence. The metabolic adaption is believed to occur because the cells are stressed by the extensive production. The cells will adapt to the new metabolic situation, which will gradually lead to lower production rates. This is highly undesirable in the biotech industry, as the chemostats will have to be restarted on a regular basis, which is costly and time consuming.


The redox coupled system

Figure 3 – Chemostat fermentation with Rexivator system
Chemostat oscillations in the NAD+/NADH ratio as a result of the Yeast metabolic cycle (A: top graph) lead to change in the Rex DNA binding activity (B: middle graph) leading to controlled bursts in product of reporter gene expression (C: lower graph).


A strategy to lower the effect of the metabolic adaption could be to couple the productivity with the yeast metabolic cycle (see grey box to the right). The NAD+/NADH poise oscillates in parallel with the yeast metabolic cycle. The synthesis of a given product will be put under control of the Rexivator, which will lead to periodic burst of gene expression and thus enzyme production (See figure 2). Consequently the cells will have time to recover periodically from the metabolic stress that occurs during the production phase. We believe that this will lead to a prolonged effective chemostat operation, and ultimately higher accumulation of product before a costly restart of the chemostat is required.

By using computer modelling and experimental data from literature we will determine when in the metabolic cycle, it is favorable to produce, and when to let the cells rest. These predictions will be used to adjust and tune the sensing system, so that it initiates gene expression at appropriate times. The production over an extended period of time will then be monitored in a chemostat fermentation, to test if the yield has improved before restart is required.


Yeast as a model organism for humans: Rexivator in cancer research

Yeast is used as a model organism for humans in many research projects. As an example, studies of the yeast cell cycle have paved the way for most of the knowledge about the cell cycle in mammalian cells. As yeast has been widely used as a model organism for studying cancer an integrated tool for detecting a significant change in the redox potential would ease this research, especially because a rising NADH level is seen as a hallmark of carcinogenesis. The prospect for a cancer drug based on a DNA vaccine transcribed only at abnormally high NADH concentrations killing the cell could also be facilitated by research in this field.

The yeast metabolic cycle

It has recently been shown by Tu et al. and Klevecz et al. that the expression of at least half of the genes monitored on a standard yeast gene chip will oscillate in a coordinated manner when grown under glucose limited conditions. The cells will shift between oxidative and reductive metabolism in a synchronized metabolic cycle with three phases: oxidative, reductive/building and reductive/ charging. As oxygen will only be consumed in the oxidative phase, the dissolved oxygen will oscillate. Many metabolites and cofactors including NADH and NAD+ will also oscillate during this cycle as NADH is converted to NAD+ when oxygen is consumed.

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