Farnesol secretion as a possible driving force for maintaining Candida albicans as a diploid

Candida albicans is a pathogenic dimorphic fungus which is invariably found as a diploid in patients. C. albicans secretes the sesquiterpene farnesol both as a quorum sensing molecule which blocks the yeast to hypha conversion and as a virulence factor for pathogenicity. 20-25 μM farnesol kills other competing yeasts and fungi, often by triggering apoptosis, and yet wild type diploid C. albicans tolerates 300-500 μM farnesol. The recent availability of 10 haploid strains of C. albicans (5 mating type aand 5 mating type α) allowed us to compare their production of and sensitivity to farnesol. On average, the heterozygous diploid strains of C. albicans were 2.4 times more resistant to 20-40 μM farnesol than MTLa haploid cells and 4.6 times more resistant than MTLα haploid cells. Furthermore, the MTLa haploids produce approximately 10 times more farnesol than do the MTLα haploids. Prior work concluded that haploid strains exhibited such low fitness that C. albicans was thought to be an obligate diploid. We now suggest that increased farnesol secretion by the MTLa haploids and increased farnesol sensitivity of the MTLα haploids is a mechanism for maintaining the dominant heterozygous diploid status of C. albicans. This idea is based on the observation that the a-factor peptide pheromone is farnesylated but the α-factor pheromone is not farnesylated. Our working hypothesis is that farnesol is secreted in part via Ste6 and imported in part via Ste3, the proteins which export and import the farnesylated a-pheromone. We also examined whether farnesol was excreted in extracellular vesicles.

Amino acid-derived quorum sensing molecule alanine on the GIT tolerance of the lactobacillus strains in the co-cultured fermentation model

As the importance of gut microbiota in health is increasingly recognized, the interest in interventions that can modulate the microbiota and its interactions with its host has soared. The survival status of the probiotics in the gastrointestinal environment and the microbial interactions between the LAB have also received considerable attention. In the present research, the gastrointestinal environment tolerance, adhesion ability, and biofilm formation of the lactobacillus strains in the co-culture system were explored, through the real-time fluorescence-based quantitative PCR, UPLC-MS/MS metabolic profiling analysis and Live/Dead® BacLightTM cell staining methods. The results show that the co-culture system can promote the release of signal molecules and can effectively protect the liability of the Lactobacillus acidophilus in the gastrointestinal environment. Meanwhile, amino acid-derived quorum sensing molecule L-alanine (1 %) can effectively enhance the communication of the cells in the complex fermentation model, which leads to the increase of the liability of the L. acidophilus in the gastrointestinal environment.