Rational metabolic engineering of oilseed fatty acid composition
Lead Research Organisation:
Rothamsted Research
Department Name: UNLISTED
Abstract
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Technical Summary
Objective: To modify the oil composition of a target plant species in a predictable manner
There is continued interested in using vegetable oils for a range of different applications, including nutrition, industrial uses (e.g. lubricants) and more recently as biofuels (i.e. biodiesel). Considerable progress has been made over the last ten years in taking forward earlier biochemical models for plant lipid biosynthesis, predominantly through the use of genetic and metabolic engineering approaches. This has resulted in a framework model for the underlying biosynthetic routes for any given fatty acid, further underpinned by the molecular characterisation of the genes encoding the primary biosynthetic activities. However, a plethora of transgenic experiments indicate that our understanding of lipid synthesis and accumulation is at best partial, as witnessed by the relatively few examples of heterologous fatty acids accumulating to high levels in transgenic plants. For example, plants engineered to synthesis long chain polyunsaturated fatty acids such as those found in fish oils fail to efficiently accumulate these compounds, instead accumulating to high levels biosynthetic intermediates.
Therefore, the primary aim of this project is to identify (via biochemistry, reverse genetics and transgenesis) the endogenous factors which contribute to the channelling of fatty acids from their site of synthesis, through various stages of modification through to their ultimate site of deposition (triacyglcerols in seeds, but also membrane lipids). The identification of such factors (most likely to representing acyl-exchange enzymes) will allow the refining of our model of plant lipid synthesis and deposition and facilitate genetic interventions (GM or non-GM) to modify seed oil composition for any particular desired end-use.
There is continued interested in using vegetable oils for a range of different applications, including nutrition, industrial uses (e.g. lubricants) and more recently as biofuels (i.e. biodiesel). Considerable progress has been made over the last ten years in taking forward earlier biochemical models for plant lipid biosynthesis, predominantly through the use of genetic and metabolic engineering approaches. This has resulted in a framework model for the underlying biosynthetic routes for any given fatty acid, further underpinned by the molecular characterisation of the genes encoding the primary biosynthetic activities. However, a plethora of transgenic experiments indicate that our understanding of lipid synthesis and accumulation is at best partial, as witnessed by the relatively few examples of heterologous fatty acids accumulating to high levels in transgenic plants. For example, plants engineered to synthesis long chain polyunsaturated fatty acids such as those found in fish oils fail to efficiently accumulate these compounds, instead accumulating to high levels biosynthetic intermediates.
Therefore, the primary aim of this project is to identify (via biochemistry, reverse genetics and transgenesis) the endogenous factors which contribute to the channelling of fatty acids from their site of synthesis, through various stages of modification through to their ultimate site of deposition (triacyglcerols in seeds, but also membrane lipids). The identification of such factors (most likely to representing acyl-exchange enzymes) will allow the refining of our model of plant lipid synthesis and deposition and facilitate genetic interventions (GM or non-GM) to modify seed oil composition for any particular desired end-use.
Planned Impact
unavailable
Organisations
People |
ORCID iD |
| Johnathan Napier (Principal Investigator) |
Publications
Venegas-CalerĂ³n M
(2010)
An alternative to fish oils: Metabolic engineering of oil-seed crops to produce omega-3 long chain polyunsaturated fatty acids.
in Progress in lipid research
Napier JA
(2010)
As simple as ACB--new insights into the role of acyl-CoA-binding proteins in Arabidopsis.
in The New phytologist
Zadravec D
(2011)
ELOVL2 controls the level of n-6 28:5 and 30:5 fatty acids in testis, a prerequisite for male fertility and sperm maturation in mice.
in Journal of lipid research
Beaudoin F
(2009)
Functional characterization of the Arabidopsis beta-ketoacyl-coenzyme A reductase candidates of the fatty acid elongase.
in Plant physiology
Tavares S
(2011)
Metabolic engineering of Saccharomyces cerevisiae for production of Eicosapentaenoic Acid, using a novel {Delta}5-Desaturase from Paramecium tetraurelia.
in Applied and environmental microbiology
Lu C
(2011)
New frontiers in oilseed biotechnology: meeting the global demand for vegetable oils for food, feed, biofuel, and industrial applications.
in Current opinion in biotechnology
Bourdenx B
(2011)
Overexpression of Arabidopsis ECERIFERUM1 promotes wax very-long-chain alkane biosynthesis and influences plant response to biotic and abiotic stresses.
in Plant physiology
Napier JA
(2010)
Tailoring plant lipid composition: designer oilseeds come of age.
in Current opinion in plant biology
| Description | We have developed GM plants which make omega-3 fish oils |
| Exploitation Route | By infringing our IP? |
| Sectors | Agriculture Food and Drink |
| Description | Developing GM plants with the capacity to make novel oils, including fish oils |
| First Year Of Impact | 2009 |
| Sector | Agriculture, Food and Drink |
| Impact Types | Societal Economic |