TY - JOUR
T1 - Laxative treatment with polyethylene glycol decreases microbial primary bile salt dehydroxylation and lipid metabolism in the intestine of rats
AU - van der Wulp, Mariette Y. M.
AU - Derrien, Muriel
AU - Stellaard, Frans
AU - Wolters, Henk
AU - Kleerebezem, Michiel
AU - Dekker, Jan
AU - Rings, Edmond H. H. M.
AU - Groen, Albert K.
AU - Verkade, Henkjan J.
PY - 2013/10
Y1 - 2013/10
N2 - Polyethylene glycol (PEG) is a frequently used osmotic laxative that accelerates gastrointestinal transit. It has remained unclear, however, whether PEG affects intestinal functions. We aimed to determine the effect of PEG treatment on intestinal sterol metabolism. Rats were treated with PEG in drinking water (7%) for 2 wk or left untreated (controls). We studied the enterohepatic circulation of the major bile salt (BS) cholate with a plasma stable isotope dilution technique and determined BS profiles and concentrations in bile, intestinal lumen contents, and feces. We determined the fecal excretion of cholesterol plus its intestinally formed metabolites. Finally, we determined the cytolytic activity of fecal water (a surrogate marker of colorectal cancer risk) and the amount and composition of fecal microbiota. Compared with control rats, PEG treatment increased the pool size (+51%; P <0.01) and decreased the fractional turnover of cholate (-32%; P <0.01). PEG did not affect the cholate synthesis rate, corresponding with an unaffected fecal primary BS excretion. PEG reduced fecal excretion of secondary BS and of cholesterol metabolites (each P <0.01). PEG decreased the cytolytic activity of fecal water [54 (46-62) vs. 87 (85-92)% erythrocyte potassium release in PEG-treated and control rats, respectively; P <0.01]. PEG treatment increased the contribution of Verrucomicrobia (P <0.01) and decreased that of Firmicutes (P <0.01) in fecal flora. We concluded that PEG treatment changes the intestinal bacterial composition, decreases the bacterial dehydroxylation of primary BS and the metabolism of cholesterol, and increases the pool size of the primary BS cholate in rats.
AB - Polyethylene glycol (PEG) is a frequently used osmotic laxative that accelerates gastrointestinal transit. It has remained unclear, however, whether PEG affects intestinal functions. We aimed to determine the effect of PEG treatment on intestinal sterol metabolism. Rats were treated with PEG in drinking water (7%) for 2 wk or left untreated (controls). We studied the enterohepatic circulation of the major bile salt (BS) cholate with a plasma stable isotope dilution technique and determined BS profiles and concentrations in bile, intestinal lumen contents, and feces. We determined the fecal excretion of cholesterol plus its intestinally formed metabolites. Finally, we determined the cytolytic activity of fecal water (a surrogate marker of colorectal cancer risk) and the amount and composition of fecal microbiota. Compared with control rats, PEG treatment increased the pool size (+51%; P <0.01) and decreased the fractional turnover of cholate (-32%; P <0.01). PEG did not affect the cholate synthesis rate, corresponding with an unaffected fecal primary BS excretion. PEG reduced fecal excretion of secondary BS and of cholesterol metabolites (each P <0.01). PEG decreased the cytolytic activity of fecal water [54 (46-62) vs. 87 (85-92)% erythrocyte potassium release in PEG-treated and control rats, respectively; P <0.01]. PEG treatment increased the contribution of Verrucomicrobia (P <0.01) and decreased that of Firmicutes (P <0.01) in fecal flora. We concluded that PEG treatment changes the intestinal bacterial composition, decreases the bacterial dehydroxylation of primary BS and the metabolism of cholesterol, and increases the pool size of the primary BS cholate in rats.
KW - cholate
KW - enterohepatic circulation
KW - bile salt
KW - microbiota
KW - DEOXYCHOLIC-ACID FORMATION
KW - FECAL WATER
KW - ENTEROHEPATIC CIRCULATION
KW - GASTROINTESTINAL CANCER
KW - CHOLESTEROL SATURATION
KW - CHRONIC CONSTIPATION
KW - INDUCED INCREASE
KW - COLON-CANCER
KW - TRANSIT
KW - BACTERIA
U2 - 10.1152/ajpgi.00375.2012
DO - 10.1152/ajpgi.00375.2012
M3 - Article
SN - 0193-1857
VL - 305
SP - G474-G482
JO - American Journal of Physiology-Gastrointestinal and Liver Physiology
JF - American Journal of Physiology-Gastrointestinal and Liver Physiology
IS - 7
ER -