Team:Edinburgh/Plan

From 2008.igem.org

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(Primary Objective: The production of starch from cellulose)
(Secondary Objective: The synthesis of β-carotene)
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= Secondary Objective: The synthesis of β-carotene =
= Secondary Objective: The synthesis of β-carotene =
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Vitamin A deficiency results in night-blindness and an impaired immune system. A number of genes from ''Pantoea ananatis'' will be added to our bacterial cells, in essence transferring the beta-carotene synthesis pathway of ''P. ananatis'' to our chasis organism. These genes are ''crtE'' (geranyl diphosphate synthesase), ''crtB'' (phytoene synthase), ''crtI'' (phytoene desaturase) and ''crtY'' (lycopene beta-cyclase). We will also create BioBricks of the ''E. coli'' genes ''dxs'' and ''appY'', the addition of which should increase the yield of beta-carotene.
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β-carotene is the pigment that gives carrots their orange colour. It is produced as an intermediate of the lycopene synthesis pathway and is converted into vitamin A by the human body. We added a number of genes from ''Pantoea ananatis'' (formerly ''Erwinia ananas'') to ''E. coli'', in essence transferring the beta-carotene synthesis pathway of ''P. ananatis'' to our chasis organism. We also cloned two ''E. coli'' genes in order to upregulate the transgenic lycopene synthesis pathway.
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[https://2008.igem.org/Team:Edinburgh/Plan/Beta-Carotene Overview of the genes and pathway]

Revision as of 12:21, 29 October 2008

Contents

A chassis: E. coli vs. B. subtilis

We were initially torn between using Escherichia coli or Bacillus subtilis as a chassis for development of our system:

We decided that B. subtilis would have advantages in the case of our system working and industrialisation being an option. This was because of increased ease of transport (due to its stable spore-forming nature), its having a better characterised secretory system and being regarded in higher favour than E. coli by the general public (see section of ethical, legal and social implications). Another possibility for the future would be to port the system to yeast, Saccharomyces cerevisiae; this would be more difficult to achieve but might ultimately be more desirable as yeast is Generally Regarded As Safe for food use, and as a eukaryote, might be able to accumulate larger amounts of starch than bacteria.

However, for the labwork we decided to use E. coli JM109 as the chassis. This was due to the greater availability of tested registry parts for E. coli compared to B. subtilis, a higher level of understanding of the biochemistry of E. coli, and more in-house experience of engineering E. coli.

Primary Objective: The production of starch from cellulose

Firstly, why starch?

Although one of our aims is to provide a substrate for the biofuels industry, which can easily ferment glucose to ethanol, we decided to try to synthesise starch instead, even though this requires extra steps. The reason for this was a question of purification: glucose is soluble, and therefore difficult to purify from solution, as is glycogen. Starch on the other hand is highly insoluble making purification of this end product relatively straight forward. As well as this, glucose becomes inhibitory at high cellular concentrations. Starch, being insoluble, can accumulate at much higher quantities without disrupting the biochemistry of the cell.

The production of starch from cellulose requires two main steps:

  1. Cellulolysis
  2. Starch synthesis

Secondary Objective: The synthesis of β-carotene

β-carotene is the pigment that gives carrots their orange colour. It is produced as an intermediate of the lycopene synthesis pathway and is converted into vitamin A by the human body. We added a number of genes from Pantoea ananatis (formerly Erwinia ananas) to E. coli, in essence transferring the beta-carotene synthesis pathway of P. ananatis to our chasis organism. We also cloned two E. coli genes in order to upregulate the transgenic lycopene synthesis pathway.

Overview of the genes and pathway


System overview

Edinburgh Flowchart.jpg

References

Cellulose degradation

  • Lynd, L.R., Weimer, P.J., van Zyl, W.H., and Pretorius, I.S. 2002. Microbial Cellulose Utilization: Fundamentals and Biotechnology. Microbiology and Molecular Biology Reviews 66, 506-577.

Glycogen overproduction

  • Leung, P., Lee, Y.M., Greenberg, E., Esch, K., Boylan, S., and Preiss, J. 1986. Cloning and expression of the Escherichia coli glgC gene from a mutant containing an ADP-glucose pyrophsophorylase with altered allosteric properties. Journal of Bacteriology 167, 82-88.
  • Eydallin, G., Viale, A.M., Moran-Zorzano, M.T., Munoz, F.J., Montero, M., Baroja-Fernandez, E., and Pozueta-Romero, J. 2007. Genome-wide screening of genes affecting glycogen metabolism in Escherichia coli K-12. FEBS Letters 581, 2947-2953.
  • Dedhia, N., Chen, W., and Bailey, J.E. 1996. Design of expression systems for metabolic engineering: coordinated synthesis and degradation of glycogen. Biotechnology and Bioengineering 55, 419-426.
  • Fernandez-Banares, I., Clotet, J., Arino, J., and Guinovart, J.J. 1991. Glycogen hyperaccumulation in Saccharomyces cerevisiae RAS2 mutant - a biochemical study. FEBS Letters 290, 38-42.

Starch biosynthesis

  • Ball, S.G. and Morell, M.K. 2003. From bacterial glyogen to starch: understanding the biogenesis of the plant starch granule. Annual Reveiews in Plant Biology 54, 207-233.
  • Delatte T et al. 2005. Arabidopsis mutants Atisa1 and Atisa2 have identical phenotypes and lack the same multimeric isoamylase, which influences the branch point distribution of amylopectin during starch synthesis. Plant Journal 41, 815-830.
  • Wattebled F et al. 2005. Mutants of Arabidopsis lacking a chloroplastic isoamylase accumulate phytoglycogen and an abnormal form of amylopectin. Plant Physiology 138, 184-195.
  • Kubo A et al. 2005. Complementation of sugary-1 phenotype in rice endosperm with the wheat isoamylase1 in gene in supports a direct role for isoamylase1 amylopectin biosynthesis. Plant Physiology 137, 45-36.

Synthesis of carotenoids

  • Sandmann, G. 2006. Production of carotenoids by gene combination in Escherichia coli. pages 143-153 in 'Food Biotechnology', 2nd edition, eds. K. Shetty, G. Paliyath, A. Pometto and R.E. Levin, CRC Press, Taylor & Francis group, Boca Raton, FL.
  • Misawa, N., Nakagawa, N., Kobayashi, K., Yamano, S., Nakamura, K., and Harashima, K. 1990. Elucidation of the Erwinia uredovora carotenoid biosynthetic pathway by functional analysis of gene products expressed in Escherichia coli. Journal of Bacteriology 172, 6704-612.

Synthesis of limonene and other terpenes

  • Lucker, J., El Tamer, M.K., Schwab, W., Verstappen, F.W.A., van der Plas, L.H.W., Bouwmeester, H.J., and Verhoeven, H.H. 2002. Monoterpene biosynthesis in lemon (Citrus limon). European Journal of Biocehmistry 269, 3160-3171.
  • Reiling, K.K., Yoshikuni, Y., Martin, V.J.J., Newman, J., Bohlmann, J., and Keasling, J.D. 2004. Mono and diterpene production in Escherichia coli. Biotechnology and Bioengineering 87, 200-212.
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