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When ''P. damnosus'' lives together with ''Saccharomyces'', a chemical is produced by ''P. damnosus'' that essentially "turns on" the GAF+ gene in ''Saccharomyces''. Not only does ''Sacch'' then have the ability to ferment other sugars at the same time as glucose, but it produces less alcohol. Viability over time is also increased in ''Sacch'' cells that express this gene versus those that don't. With wild fermentation of grapes, the GAF+ ''Sacch'' strains also prevented other fungi from thriving. It is theorized that this creates benefits for both microorganisms, which are often found together in the wild during fermentation of fruit; the bacteria isn't killed by higher alcohol levels, and the yeast has a broader food source. Furthermore, once a ''Saccharomyces'' cell expresses the gene, it will continue to pass this gene onto it's offspring. In winemaking, this is the cause of arrested wine fermentations due to the lower amount of alcohol produced (in the referenced study, the GAF- ''Sacch'' cells fermented out a must to 12% ABV wine, and the GAF+ ''Sacch'' cells fermented out an 8% ABV wine using the same must) <ref name="cross-kingdom"></ref>. However, the implications of this in sour beer brewing are much different and have yet to be further explored.
Of all the ''Lactobacillus'' strain that were studied for this behavior (''L. brevis'', ''L. hilgardii'', ''L. plantarum'', and ''L. kunkeei''), only ''L. kunkeei'' was shown to induce the GAF+ gene. Different species of bacteria of ''Staphylococcus'', ''Micrococcus'', ''Bacillus'', ''Listeria'', ''Paenibacillus'', ''Gluconobacter'', ''Sinorhizobium'', ''Escherichia'', ''Serriatia'', and all ''Pediococcus'' species tested also influenced the GAF+ gene in ''Saccharomyces'' <ref name="cross-kingdom"></ref>.
==See Also==