Scientists one step closer to re-writing world鈥檚 first synthetic yeast genome, unravelling the fundamental building blocks of life
Scientists have engineered a chromosome entirely from scratch that will contribute to the production of the world鈥檚 first synthetic yeast.
Researchers in the 91直播 Institute of Biotechnology (MIB) at The University of Manchester have created the tRNA Neochromosome 鈥� a chromosome that is new to nature.
It forms part of a wider project (Sc2.0) that has now successfully synthesised all 16 native chromosomes in Saccharomyces cerevisiae, common baker鈥檚 yeast, and aims to combine them to form a fully synthetic cell.
The international team has already combined six and a half synthetic chromosomes in a functional cell. It is the first time scientists have written a eukaryotic genome from scratch.
Yeasts are a common workhorse of industrial biotechnological processes as they allow valuable chemicals to be produced more efficiently, economically, and sustainably. They are often used in the production of biofuels, pharmaceuticals, flavours and fragrances, as well as in the more well-known fermentation processes of bread-making and beer-brewing.
Being able to re-write a yeast genome from scratch could create a strain that is stronger, works faster, is more tolerant to harsh conditions and has a higher yield.
The process also sheds light on the traditionally problematic genome fundamentals, such as how genomes are organised and evolved.
The findings of both projects, published as two research articles of the prestigious journals Cell and Cell Genomics respectively, are a culmination of 10 years of research from an international consortium of scientists led by Professor Patrick Cai and The University of Manchester, and mark a new chapter in engineering biology.
The University of Manchester鈥檚 research also features on the front covers of both journals.
鈥淭he potential benefits of this research are universal 鈥� the limiting factor isn鈥檛 the technology, it鈥檚 our imagination.鈥�
Prof Cai, Chair in Synthetic Genomics at The University of Manchester who is the international coordinator of Sc2.0 project, said: 鈥淭his is an exciting milestone when it comes to engineering biology. While we have been able to edit genes for some time, we have never before been able to write a eukaryote genome from scratch. This work is fundamental to our understanding of the building blocks of life and has the potential to revolutionise synthetic biology which is fitting as 91直播 is the home of the Industrial Revolution. Now, we鈥檙e at the forefront of the biotechnological revolution too.
鈥淲hat鈥檚 remarkable about this project is the sheer scale of collaboration and the interdisciplinarity involved in bringing it to fruition. We鈥檝e brought together not only our experts here in the MIB, but also experts from across the world in fields ranging from biology and genomics to computer science and bioengineering.
Dr Daniel Schindler, one of the two lead authors and group leader at the Max Planck Institute for Terrestrial Microbiology and the Center for Synthetic Microbiology (SYNMIKRO) in Marburg, added: "The international Sc2.0 is a fascinating, highly interdisciplinary project. It combines basic research to expand our understanding of genome fundamentals, but also paves the way for future applications in biotechnology and drives technology developments.
鈥淭he international and inclusive nature of the project has unleashed the science and seeded future collaborations and friendships. The 91直播 Institute of Biotechnology, with its excellent research environment and open space, has always facilitated this."
The tRNA neochromosome is used to house and organise all 275 nuclear tRNA genes from the yeast and will eventually be added to the fully synthetic yeast where the tRNA genes have been removed from the other synthesised chromosomes.
Unlike the other synthetic chromosomes of the Sc2.0 project, the tRNA neochromosome has no native counterpart in the yeast genome.
It was designed using AI assisted, computer-assisted design (CAD), manufactured with state-of-the-art roboticized foundries, and completed by comprehensive genome-wide metrology to ensure the high fitness of the synthetic cells.
Next, the researchers will work together to bring all the individual synthetic chromosomes together into a fully synthetic genome. The final Sc2.0 strain will not only be the world鈥檚 first synthetic eukaryote, but also the first one to be built by the international community.
鈥淭he potential benefits of this research are universal 鈥� the limiting factor isn鈥檛 the technology, it鈥檚 our imagination鈥�, says Prof Cai.