Eady in the GIT and/or liver and/or systemic circulation.

Eady in the GIT and/or liver and/or systemic circulation. The Table 2. Length of villi (mm) and crypt depth (mm) in duodenum, jejunum and ileum after 3 weeks feeding a control diet or feed contaminated with DON, either or not supplemented with an adsorbing agent. Results are presented as mean values and standard deviations of fifteen villi or crypts measured from 8 chickens per treatment group.Control Duodenum Villus height Crypt depth Jejunum Villus height Crypt depth Ileum Villus height Crypt depth 596630aaAdsorbing agent DONDON+ adsorbing agent1734626aa1773643ca1449631bb1789639c 12868a 1509643c 10967c 744663b 119618ab1343637a 12068a1521639c 116610a 773663bb1184648b 10168b 616638aaa,b mean values within a row with unlike superscript letters are significantly different (p#0.05). doi:10.1371/journal.pone.0069014.tsum of the concentration of the co-contaminants fumonisin B1 and B2 of 0.901 mg/kg was much lower than the European guidance value of 20 mg/kg in poultry feed [29]. Thus, the co-contamination with fumonisins can be considered as negligible. In our study, three weeks feeding DON at 7.54 mg/kg feed reduced the villus height and the crypt depth both in the duodenum and the jejunum. Reduced villi in the duodenal and jejunal segment of the small intestine were also observed in broiler chickens after 6 weeks feeding a diet of 10 mg/kg DON [30]. Yunus et al. (2012) observed a linear correlation between increasing levels of DON and the decrease in villus height in both the mid-duodenum and mid-jejunum [31]. Possible explanation for these histological changes can be a direct irritant effect of the mycotoxin or suppression of mitosis or protein synthesis [18,31]. In order to maintain an effective barrier function, the intestinal epithelium needs to regenerate continuously. Mature cells migrate along the Title Loaded From File crypt-villus axis towards the villus-top, in the mean time these cells become differentiated cells [32]. DON can be responsible for a reduced cell PHCCC site proliferation [33?5]. This can be an explanation for the reduced crypt depth observed during our trial. A decreased crypt depth in the mid-duodenum in broiler after chronic exposure to DON (12 mg/kg) has been reported earlier [31]. Interestingly, the adsorbing agent resulted in longer villi over the entire length of the small intestine. These longer villi seen in our study in the chickens receiving the adsorbing agent, can be responsible for the higher oral bioavailabilities of xenobiotics as observed in our previous study [12]. Several studies both in vitro and in vivo already reported that DON is able to alter intestinal permeability. Intestinal physiology can even be affected by DON in the absence of clinical signs [36]. The function of the tight junctions can be evaluated by measurements of the transepithelial electrical resistance (TEER) and of the paracellular efflux of macromolecules [37]. These techniques, however, do not give information which specific protein of the tight junctions is affected [38]. Therefore, a qRTPCR method was applied in our study to evaluate the effects of DON on the different specific proteins of the tight junctions, namely CLDN1, CLDN5, ZO1 and ZO2. An important advantage of this technique is the generation of quantitative results, which makes it possible to detect small differences which could otherwise be missed when using immunofluorescence. Moreover, due to the lack of suitable commercial avian antibodies, no effects at the protein level could be studied. Th.Eady in the GIT and/or liver and/or systemic circulation. The Table 2. Length of villi (mm) and crypt depth (mm) in duodenum, jejunum and ileum after 3 weeks feeding a control diet or feed contaminated with DON, either or not supplemented with an adsorbing agent. Results are presented as mean values and standard deviations of fifteen villi or crypts measured from 8 chickens per treatment group.Control Duodenum Villus height Crypt depth Jejunum Villus height Crypt depth Ileum Villus height Crypt depth 596630aaAdsorbing agent DONDON+ adsorbing agent1734626aa1773643ca1449631bb1789639c 12868a 1509643c 10967c 744663b 119618ab1343637a 12068a1521639c 116610a 773663bb1184648b 10168b 616638aaa,b mean values within a row with unlike superscript letters are significantly different (p#0.05). doi:10.1371/journal.pone.0069014.tsum of the concentration of the co-contaminants fumonisin B1 and B2 of 0.901 mg/kg was much lower than the European guidance value of 20 mg/kg in poultry feed [29]. Thus, the co-contamination with fumonisins can be considered as negligible. In our study, three weeks feeding DON at 7.54 mg/kg feed reduced the villus height and the crypt depth both in the duodenum and the jejunum. Reduced villi in the duodenal and jejunal segment of the small intestine were also observed in broiler chickens after 6 weeks feeding a diet of 10 mg/kg DON [30]. Yunus et al. (2012) observed a linear correlation between increasing levels of DON and the decrease in villus height in both the mid-duodenum and mid-jejunum [31]. Possible explanation for these histological changes can be a direct irritant effect of the mycotoxin or suppression of mitosis or protein synthesis [18,31]. In order to maintain an effective barrier function, the intestinal epithelium needs to regenerate continuously. Mature cells migrate along the crypt-villus axis towards the villus-top, in the mean time these cells become differentiated cells [32]. DON can be responsible for a reduced cell proliferation [33?5]. This can be an explanation for the reduced crypt depth observed during our trial. A decreased crypt depth in the mid-duodenum in broiler after chronic exposure to DON (12 mg/kg) has been reported earlier [31]. Interestingly, the adsorbing agent resulted in longer villi over the entire length of the small intestine. These longer villi seen in our study in the chickens receiving the adsorbing agent, can be responsible for the higher oral bioavailabilities of xenobiotics as observed in our previous study [12]. Several studies both in vitro and in vivo already reported that DON is able to alter intestinal permeability. Intestinal physiology can even be affected by DON in the absence of clinical signs [36]. The function of the tight junctions can be evaluated by measurements of the transepithelial electrical resistance (TEER) and of the paracellular efflux of macromolecules [37]. These techniques, however, do not give information which specific protein of the tight junctions is affected [38]. Therefore, a qRTPCR method was applied in our study to evaluate the effects of DON on the different specific proteins of the tight junctions, namely CLDN1, CLDN5, ZO1 and ZO2. An important advantage of this technique is the generation of quantitative results, which makes it possible to detect small differences which could otherwise be missed when using immunofluorescence. Moreover, due to the lack of suitable commercial avian antibodies, no effects at the protein level could be studied. Th.