Difference between revisions of "Team:Cambridge-JIC/Description"
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| + | <p style="font-family:Open Sans; font-size:150%;">We have built a toolbox for chloroplast transformation. In our chosen organism Chlamydomonas reinhardtii (Chlamy) we have targeted all the transformation steps and improved each of them. We have built a library of tested parts optimised for Chlamydomonas or related chloroplasts. We built a gene gun which is less than 1/100 of commercial price and an incubator for our cells with many functions. Moreover we modelled the behaviour of transformed systems. Finally we designed a wetlab tool which could help achieve essential homoplasmy (transformation of all copies of chloroplast DNA) in one generation instead of 2-3 months of selection. Our design incorporated numerous discussions about biosafety and our library contains the relevant parts for practical implementation!</p> | ||
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Revision as of 18:03, 18 October 2016
We have built a toolbox for chloroplast transformation. In our chosen organism Chlamydomonas reinhardtii (Chlamy) we have targeted all the transformation steps and improved each of them. We have built a library of tested parts optimised for Chlamydomonas or related chloroplasts. We built a gene gun which is less than 1/100 of commercial price and an incubator for our cells with many functions. Moreover we modelled the behaviour of transformed systems. Finally we designed a wetlab tool which could help achieve essential homoplasmy (transformation of all copies of chloroplast DNA) in one generation instead of 2-3 months of selection. Our design incorporated numerous discussions about biosafety and our library contains the relevant parts for practical implementation!
I. Microalgal chlroplasts as an alternative expression system
Chloroplasts hold a massive potential as an alternative protein expression system, due to their outstanding expression yields, diversity of post-translational modifications and auto/mixotrophic lifestyles of plants and microalgae.
Various proteins have already been successfully expressed in chloroplasts, including:
- monoclonal antibodies
- antigens
- anti-toxins
- growth factors
Transgene expression in microalgae can total up to 30-50% of a cell’s dry biomass, as unlike in higher plants and mammals, metabolic energy in microalgae is not directed towards maintaining complex differentiated structures.
II. Microalgae chloroplasts as a model for higher plants
Research in C. reinhardtii chloroplasts can help achieve the following aims:
- increase yields of oils for biofuels
- elucidate photosynthetic machinery
- improve C fixation to combat the international food crisis
Due to extensive evolutionary conservation of the chloroplast genome, research in the chloroplasts of microalgae, such as Chlamydomonas reinhardtii, is likely to be applicable to studies of other plants. On the other hand, Chlamydomonas reinhardtii is much easier to grow and maintain than higher plants, such as Marchantia polymorpha.
III. Bottlenecks of chloroplast engineering
Chloroplasts engineering is currently underexplored due to:
- Time issues — it takes 2-3 months to achieve homoplasmy, as state where all chloroplast genome copies have been transformed and when experimental results can be obtained
- Experimental cost — chloroplasts can be reliably transformed almost exclusively by biolistic devices, and commercial biolistic devices are very expensive.
- Lack of modular chloroplast genetic parts available — research is more time-consuming and cumbersome.
IV. Our solutions
Our project aims to tackle most bottlenecks and democratise algal biotechnology:
- Library of chloroplast parts for C. reinhardtii — to facilitate the assembly of synthetic constructs using Phytobricks standard
- Open-source biolistics device — for cheaper chloroplasts transformations
- Open source microalgae growth facility — to growth algae in an affordable way
- Novel Cas9 strategy — to accelerate the process of achieving homoplasmy
- Modelling of Cas9 dynamics — to predict the time our Cas9 stategy would take to transform all copies of a chloroplast’s genome
References
1. Wannathong T et al., New tools for chloroplast genetic engineering allow the synthesis of human growth hormone in the green alga Chlamydomonas reinhardtii, Appl Microbiol Biotechnol (2016) 100:5467–5477
2. De Las Rivas J et al., Comparative Analysis of Chloroplast Genomes: Functional Annotation, Genome-Based Phylogeny, and Deduced Evolutionary Patterns, Genome Res. 2002. 12: 567-583
Viitanen P V et al., Metabolic Engineering of the Chloroplast Genome Using the Echerichia coli ubiC Gene Reveals That Chorismate Is a Readily Abundant Plant Precursor for p-Hydroxybenzoic Acid Biosynthesis, Plant Physiol. 2004 Dec; 136(4): 4048–4060.
