Tailoring baker's yeast Saccharomyces cerevisiae for functional testing of channelrhodopsin.

Channelrhodopsin 2 (ChR2) and its variants are the most frequent tools for remote manipulation of electrical properties in cells via light. Ongoing attempts try to enlarge their functional spectrum with respect to ion selectivity, light sensitivity and protein trafficking by mutations, protein engineering and environmental mining of ChR2 variants. A shortcoming in the required functional testing of large numbers of ChR2 variants is the lack of an easy screening system. Baker's yeast, which was successfully employed for testing ion channels from eukaryotes has not yet been used for screening of ChR2s, because they neither produce the retinal chromophore nor its precursor carotenoids. We found that addition of retinal to the external medium was not sufficient for detecting robust ChR activity in yeast in simple growth assays. This obstacle was overcome by metabolic engineering of a yeast strain, which constitutively produces retinal. In proof of concept experiments we functionally express different ChR variants in these cells and monitor their blue light induced activity in simple growth assays. We find that light activation of ChR augments an influx of Na+ with a consequent inhibition of cell growth. In a K+ uptake deficient yeast strain, growth can be rescued in selective medium by the blue light induced K+ conductance of ChR. This yeast strain can now be used as chassis for screening of new functional ChR variants and mutant libraries in simple yeast growth assays under defined selective conditions.

Novel auto-selection systems for transformation selection of Saccharomyces cerevisiae in rich complex media.

The most widely used strategy for selection of yeast transformed with episomal plasmids comprises the use of auxotrophic yeast strains in combination with vectors containing complementing prototrophic marker genes. Another approach uses heterologous genes or cassettes which, if present in the vector, render the otherwise sensitive yeast strain resistant to antibiotics. In addition, auto-selection systems for Saccharomyces cerevisiae have been developed that eliminate the requirement for synthetic drop-out media or the use of antibiotics for transformation selection and subsequent plasmid maintenance in expression cultures. Here we describe a combination of host strain and vector system introducing a novel concept of auto-selection systems that allows for easy and robust propagation of host cells deleted in essential genes in supplemented media before being transformed with rescuing plasmids. With that, our approach is favorable over commonly used selection strategies and has major advantage over other auto-selection systems. Our approach complements the auto-selection toolbox already available for S. cerevisiae, thus contributing a novel system that enables the use of complex peptone-based media for protein expression and metabolic engineering approaches. We therefore expect that this new strategy will be of general interest to the yeast research community in academia and industry.