Abstract
Robust preference for fermentative glucose metabolism has motivated domestication of the budding yeast Saccharomyces cerevisiae. This program can be circumvented by a proteinbased genetic element, the [GAR+] prion, permitting simultaneous metabolism of glucose and other carbon sources. Diverse bacteria can elicit yeast cells to acquire [GAR+], although the molecular details of this interaction remain unknown. Here we identify the common bacterial metabolite lactic acid as a strong [GAR+] inducer. Transient exposure to lactic acid caused yeast cells to heritably circumvent glucose repression. This trait had the defining genetic properties of [GAR+], and did not require utilization of lactic acid as a carbon source. Lactic acid also induced [GAR+]-like epigenetic states in fungi that diverged from S. cerevisiae ~200 million years ago, and in which glucose repression evolved independently. To our knowledge, this is the first study to uncover a bacterial metabolite with the capacity to potently induce a prion.
Figures
![Figure 1. Identification of the small molecule that induces [GAR+] in a concentration dependent manner. (A) S. gallinarum spotted next to yeast on GLY + GlcN (YP with 2% glycerol and 0.05% glucosamine) induced growth of naı̈ve S. cerevisiae in a spatially dependent manner. An extract prepared from a S. gallinarum conditioned medium induced [GAR+] with similar strength. Each panel shows two biological replicates of yeast colonies spotted in fivefold serial dilutions from saturated cultures. (Bacterial spots are undiluted.) (B) Multiple-reaction monitoring-mass spectrometry (m/z 89.0200, 43.1000) traces of pure lactic acid (top), the purified active fraction from S. gallinarum conditioned medium (middle) and a co-injection of active fraction spiked with pure lactic acid (bottom). Results indicate that lactic acid is present in the active fraction (see Materials and methods). Note that y-axis scale differs between the top two traces due to the difference of lactic acid concentration in the pure standard, but they are normalized here for ease of viewing. (C) Plating assay (see Materials and methods) showing that both L- and Disomers of lactic acid strongly induce [GAR+] in a concentration dependent manner. Plotted are the fraction of](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/6492c20d-237d-339b-8c12-119eeed6d6bd/thumbnail-66221a28-3c81-4272-bbcd-d7d88e0548ea-0.png)
![Figure 2. Lactic acid induced [GAR+] has the same prion-like features as spontaneous [GAR+]. (A) Dominance in crosses between [GAR+] strains and [gar ] strains is seen in colonies isolated from a GLY + GlcN plate (spontaneous [GAR+]), as well as those induced with 0.1% D-lactic acid (LA-induced [GAR+]). Five-fold serial dilutions are shown for three biological replicates; orange coloring indicates strains exhibiting the [GAR+] phenotype. (B) Lactic acid-induced cells can be cured of the [GAR+] phenotype with transient expression of a dominant negative Hsp70 variant (Ssa1-K69M or Hsp70DN). Single colonies were propagated alone or with a plasmid expressing Hsp70DN for ~125 generations, bottlenecked each ~25 generations. After verifying plasmid loss, colonies were again tested for their capacity to grow on GLY + GlcN medium. Each image shows five-fold serial dilutions for three biological replicates. (C) A strain with diminished expression of PMA1, pma1-DAmP, has reduced spontaneous [GAR+] acquisition and is not induced by lactic acid. Lactic acid-induction frequencies differ from those in Figure 1C due to strain background BY4741, which has a lower frequency of [GAR+] acquisition (Brown and Lindquist, 2009). Plotted as in Figure 1C. DOI: 10.7554/eLife.17978.007 The following figure supplements are available for figure 2:](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/6492c20d-237d-339b-8c12-119eeed6d6bd/thumbnail-07524f26-7aa9-442e-bf71-717267b54c05-1.png)
![Figure 3. Analysis of induction frequencies in deletion mutants of genes with roles in lactic acid metabolism. (A) Plating assay (see Materials and methods) measuring induction of [GAR+] at a low (left) or high concentration (right) of L-lactic acid. Strains are in the W303 background, and cell dilutions match those in Figure 1C. We note that annotations of DLD2 and DLD3 as D-lactate dehydrogenases have recently been challenged by data suggesting they are instead transhydrogenases (Becker-Kettern et al., 2016). Only DLD1 is required for yeast to grow on D-lactic acid as a sole carbon source. Plotted the same as in Figure 1C. B.) Plating assay measuring induction of [GAR+] by D-lactic acid. Otherwise as in (A). DOI: 10.7554/eLife.17978.010](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/6492c20d-237d-339b-8c12-119eeed6d6bd/thumbnail-bb13a328-5542-4f53-ad9b-d85a71f3e75a-2.png)
![Figure 4. Full induction by S. gallinarum or lactic acid requires the yeast transcription factor SOK2. (A) S. gallinarum spotted next to either wild type or sok2D yeast cells on GLY + GlcN, or control medium GLY. (B) Plating assay (see Materials and methods) comparing spontaneous and lactic acidinduced [GAR+] frequency in wild type and sok2D cells. Lactic acid-induction frequencies differ from those in Figure 1C due to strain background BY4741, which has a lower frequency of [GAR+] acquisition (Brown and Lindquist, 2009). Plotted the same as in Figure 1C. DOI: 10.7554/eLife.17978.011](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/6492c20d-237d-339b-8c12-119eeed6d6bd/thumbnail-e102e749-9eba-4549-8551-82e74ebb694e-3.png)
![Figure 5. The strength of the [GAR+] phenotype depends on the concentration of lactic acid used for induction. (A) Plating assay (see Materials and methods) showing that L-lactic acid strongly induced [GAR+] over a wide concentration range. Plotted the same as in Figure 1C. Ten-fold dilutions were used for plates lacking lactic acid and 10,000-fold dilutions were used for plates containing lactic acid (B) Single [GAR+] colonies were picked from two representative concentrations in (A), propagated (restreaked) on non-selective medium (GLY) for approximately 75 generations, and then re-spotted on GLY + GlcN in five-fold serial dilutions. Four biological replicates are shown for each induced group, and two for uninduced cells. Note the growth in the third spots (highest dilution) of 0.0625% L-LA induced cells on GLY + GlcN. DOI: 10.7554/eLife.17978.012](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/6492c20d-237d-339b-8c12-119eeed6d6bd/thumbnail-76e978fe-5ccb-4561-8898-a637fd04ce31-4.png)
![Figure 6. Induction, maintenance, and chaperone dependence of a lactic acid-induced [GAR+]-like state is conserved in the evolutionary distant yeast Dekkera bruxellensis. (A) Induction of a [GAR+]-like state in D. bruxellensis. [gar ] cells were plated on GLY + GlcN (containing 0.1–0.15% glucosamine) medium with or without 0.02% D-lactic acid. Control cells harbor spontaneous [GAR+]. For each of the treatment images, four biological replicates are shown, in five-fold serial dilutions. (B) Maintenance and chaperone dependence of the lactic acid-induced [GAR+]-like state in D. bruxellensis. Cells induced in A. were propagated non-selectively for ~75 generations by restreaking on YPD plates, then subsequently retested for maintenance of the prion phenotype on GLY + GlcN (0.1–0.15% glucosamine), with or without the Hsp70 inhibitor myricetin (50 mM). Four biological replicates are shown for each induced group, and two shown for the uninduced and propagated [gar ] cells. DOI: 10.7554/eLife.17978.013](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/6492c20d-237d-339b-8c12-119eeed6d6bd/thumbnail-afab5b97-b2bd-4495-b18a-41b031ebf69f-5.png)
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CITATION STYLE
Garcia, D. M., Dietrich, D., Clardy, J., & Jarosz, D. F. (2016). A common bacterial metabolite elicits prion-based bypass of glucose repression. ELife, 5(NOVEMBER2016). https://doi.org/10.7554/eLife.17978
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