Combinatorial assembly of large biochemical pathways into yeast chromosomes for improved production of value-added compounds.

Abstract

Saccharomyces cerevisiae as a eukaryotic organism is particularly suitable as microbial cell factory because it has interesting features such as membrane environments for supporting membrane-associated enzymes and its capability for post-translational modifications of enzymes from plants. However, S. cerevisiae does not readily express polycistronic transcriptional units, which represents a significant challenge for constructing large biochemical pathways in budding yeast. In the present study, we developed a novel approach for rapid construction of large biochemical pathways into yeast chromosomes. Our approach takes advantage of antibiotic selection for combinatorial assembly of large pathways into the δ-sites of retrotransposon elements of yeast chromosomes. As proof-of-principle, a five-gene isobutanol pathway and an eight-gene mevalonate pathway were successfully assembled into yeast chromosomes in one-step fashion. To our knowledge, this is the first report to exploit δ-integration coupled with antibiotic selection for rapid assembly of large biochemical pathways in budding yeast. We envision our new approach could serve as a generalized technique for large pathway construction in yeast-a method that would be of significant interest to the synthetic biology community.