The expulsion of another intestinal nematode, Nippostrongylus bra

The expulsion of another intestinal nematode, Nippostrongylus brasiliensis, also occurs independently of mMCP-1 (15,36). Our results hence confirm that, despite a number of common features in the host response to various gut parasites, differences in intestinal niches between parasites will bring along different excretion mechanisms (37,38). For instance, expelling the adult (sub)epithelial T. spiralis or N. brasiliensis may be expected to depend on different mechanisms

than the facilitation of egg passage through the intestinal wall in case of S. mansoni. Moreover, the maturing schistosome eggs actively release proteases (39) and several other proteins. Although the function of these proteins remains largely unknown, it is likely that they modulate the host’s immune response to promote egg excretion (40–43). This may reduce the significance of mast cell-derived Hydroxychloroquine research buy products, such as mMcp-1, in the process of egg excretion.

NVP-BKM120 order Alternatively, mucosal mast cell mediators other than mMCP-1 may play a role in the S. mansoni egg excretion. For example, tumour necrosis factor (TNF)-α, which is involved the pathology of schistostomiasis (44), is also released by MMC (9,45). In vitro, TNF-α increases intestinal TJs permeability by modifying the distribution and the expression levels of ZO-1 (46) and by altering the lipid composition in membrane microdomains of TJs (47,48). IL-1β, another cytokine released by MMC, (49,50) increases TJs permeability of Caco-2 monolayers which is accompanied by changes in the expression levels and distribution of occludin and claudin-1 (51). Other

mast cell mediators such as IL-4, IL-10 and IL-13 (52) also modulate TJs permeability, in vitro, via several specific mechanisms (53) and thus potentially participate in the impairment of the intestinal barrier observed in S. mansoni-infected mice. The peak time of S. mansoni egg excretion was accompanied by a decrease in electrical resistance and secretory capacity of the ileal tissue, which are, as far as we are aware, quantified here for the first time. The ileal resistance was reduced to 25% of control values, which is much lower than reported for infection with Heligmosomoides polygyrus, N. brasiliensis or T. spiralis (to 55%) (54) or, for instance, in response to chronic psychological stress (to 54%) (55) and acute pancreatitis (to 75%) MTMR9 (24). The relatively large reduction in the mucosal resistance is in accordance with the increase of the flux of NaFl (to about 150% of control) and might indicate a disturbed function also of the epithelial cells proper. This suggestion is strongly supported by our finding that spontaneous secretion of the tissues and also their maximal secretion capacity are 8 w p.i. reduced to 39% and 11% of control respectively. This contrasts with the increase in secretion reported in other models of inflammation, such as experimental acute pancreatitis (24) or chronic stress (55).

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