Introducing carbon assimilation in yeasts using photosynthetic directed endosymbiosis.

Conversion of heterotrophic organisms into partially or completely autotrophic organisms is primarily accomplished by extensive metabolic engineering and laboratory evolution efforts that channel CO2 into central carbon metabolism. Here, we develop a directed endosymbiosis approach to introduce carbon assimilation in budding yeasts. Particularly, we engineer carbon assimilating and sugar-secreting photosynthetic cyanobacterial endosymbionts within the yeast cells, which results in the generation of yeast/cyanobacteria chimeras that propagate under photosynthetic conditions in the presence of CO2 and in the absence of feedstock carbon sources like glucose or glycerol. We demonstrate that the yeast/cyanobacteria chimera can be engineered to biosynthesize natural products under the photosynthetic conditions. Additionally, we expand our directed endosymbiosis approach to standard laboratory strains of yeasts, which transforms them into photosynthetic yeast/cyanobacteria chimeras. We anticipate that our studies will have significant implications for sustainable biotechnology, synthetic biology, and experimentally studying the evolutionary adaptation of an additional organelle in yeast.

Engineering artificial photosynthetic life-forms through endosymbiosis.

The evolutionary origin of the photosynthetic eukaryotes drastically altered the evolution of complex lifeforms and impacted global ecology. The endosymbiotic theory suggests that photosynthetic eukaryotes evolved due to endosymbiosis between non-photosynthetic eukaryotic host cells and photosynthetic cyanobacterial or algal endosymbionts. The photosynthetic endosymbionts, propagating within the cytoplasm of the host cells, evolved, and eventually transformed into chloroplasts. Despite the fundamental importance of this evolutionary event, we have minimal understanding of this remarkable evolutionary transformation. Here, we design and engineer artificial, genetically tractable, photosynthetic endosymbiosis between photosynthetic cyanobacteria and budding yeasts. We engineer various mutants of model photosynthetic cyanobacteria as endosymbionts within yeast cells where, the engineered cyanobacteria perform bioenergetic functions to support the growth of yeast cells under defined photosynthetic conditions. We anticipate that these genetically tractable endosymbiotic platforms can be used for evolutionary studies, particularly related to organelle evolution, and also for synthetic biology applications.

Dissection and enhancement of prebiotic properties of yeast cell wall oligosaccharides through metabolic engineering.

Saccharomyces boulardii is a yeast clinically used for treating various symptoms of gastrointestinal dysbiosis. Despite their genomic relatedness, S. boulardii has a distinctive cell wall oligosaccharide composition compared to baker's yeast S. cerevisiae, such as higher mannan content. Here we explore the beneficial effects of S. boulardii cell wall oligosaccharides through metabolic engineering. We increased the production of guanosine diphosphate (GDP)-mannose, the substrate for cell wall mannan biosynthesis, by perturbing glycolysis flux and overexpressing the enzymes in the GDP-mannose biosynthesis pathway. Combined with overexpression of a cell wall mannoprotein and dolichol phosphate mannose synthase, the cell wall mannan content of S. boulardii increased up to 52%. The identical engineering resulted in marginal changes in the S. cerevisiae cell wall. S. boulardii showed a higher adhesive capacity against Salmonella enterica Typhimurium than S. cerevisiae, and yeast-bacteria sedimentation rates were positively correlated with cell wall mannan contents. Besides, S. boulardii biomass selectively proliferated Bacteroides thetaiotaomicron over Clostridioides difficile more efficiently than S. cerevisiae, and the selectivity was further enhanced by amplifying the cell wall mannan. Collectively, we report the important prebiotic roles of cell wall oligosaccharides in the protective functions of S. boulardii and present a unique metabolic engineering approach to modulate the functions.