(A) Mitochondrial fragmentation was detected in cells cultured in

(A) Mitochondrial fragmentation was detected in cells cultured in 15% ethanol using 10 nM Mitotracker Green. (B) Intracellular ROS accumulation was detected in cells cultured in 22% ethanol with 5 μg/ml of dihydrorhodamine 123. (C) Activated caspase-like enzymatic activity was detected in S. boulardii cells cultured in 22% ethanol using

a FLICA apoptosis detection kit according to the manufacturer’s specifications. At least three independent IBET762 cultures were tested and compared. The differences in staining patterns were deemed statistically significant by the Student’s Selleckchem AMN-107 t-test (p<0.05) Studies have reported that only between 1-3% of live S. boulardii yeast is recovered in human feces after oral administration [27, 28] as the acidic conditions disrupt cell wall function and cause morphological alterations that lead to cell death C646 manufacturer [27, 29]. However, the nature of this cell death in acidic environments remains unclear. To determine the type of cell death experienced by S. boulardii cells in an acidic environment, we began by determining the viability of S. boulardii in low pH conditions. Our results show that S. boulardii cells have an increased viability in acidic conditions as compared to their S. cerevisiae

counterpart. After six hours in 50 mM HCl media, W303α cells showed almost no viability, while S. boulardii cells were more than 70% viable (Figure 3). This confirms the findings of others who have shown that S. boulardii cells are more resistant to acidic conditions than their S. cerevisiae cousins [21]. Figure 3

S. boulardii cells are more viable in 50 mM HCl than their S. cerevisiae counterparts. S. boulardii (Florastor) and S. cerevisiae (W303α) were cultured in rich YPD media overnight and resuspended in fresh media and allowed to reach exponential phase. They were then oxyclozanide resuspended in water or water containing 50 mM HCl and allowed to grow at room temperature for the indicated times, serially diluted onto YPD plates, and cultured at 30°C for 2 days. At least three independent cultures were tested and compared. The differences in viabilities were deemed statistically significant by the Student’s t-test (p<0.05) To determine if the S. boulardii cells were undergoing PCD in the acidic environment, we repeated our cell death assays with cells cultured in 75 mM HCl (pH 1.5), a scenario that mimics the conditions in the stomach [48]. DHR staining revealed that 92% of the S. boulardii cells cultured in an acidic environment contained ROS as compared to cells grown in rich YPD media (Figure 4A). FLICA staining also showed that 90% of the S. boulardii cells in the HCl solution, but only 1% of the control cell population had activated caspase-like activity (Figure 4B). Figure 4 S. boulardii undergoes programmed cell death in an acidic environment. S.

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