Background & Aims-Guanylin, an endogenous gastrointestinal peptide, causes the translocation of NaCl from interstitial fluid to the intestinal lumen. The aim of this study was to examine whether changes in dietary salt intake lead to compensatory changes in expression of the guanylin signaling pathway.
Cytoplasmic, nitric oxide-activated guanylate cyclases are expressed in many regions of the mammaian brain and are thought to participate in functions as diverse as synaptogenesis and long-term potentiation. In this study, we have characterized cytoplasmic guanylate cyclases in the nervous system of an invertebrate, the American lobster. Cytoplasmic cyclase specific activity is higher in lobster nerve cord than in any other lobster tissue tested, and considerably higher than in typical rat tissues (cerebellum, lung, and liver). However, nitric oxide donors have minimal effects on lobster nerve cord cyclic GMP production, when applied either to intact tissue or to cytoplasmic extracts. Parallel immunocytochemical studies, using an anti-cyclic GMP antibody, reveal that only a small subset of lobster neurons responds to nitric oxide with a significant elevation of cyclic GMP levels. HPLC analysis of nerve cord cytoplasm reveals two chromatographically separable cyclases, a minor nitric oxide-sensitive form whose retention time is identical to that of the conventional mammalian enzyme and a more abundant nitric oxide-insensitive form that appears to be novel. The physiological function and phylogenetic distribution of this nitric oxide-insensitive enzyme, and the signaling mechanisms that regulate its activity, are not known.
Members of the receptor-guanylate cyclase (rGC) family possess an intracellular catalytic domain that is regulated by an extracellular receptor domain. GC-C, an intestinally expressed rGC, was initially cloned by homology as an orphan receptor. The search for its ligands has yielded three candidates: STa (a bacterial toxin that causes traveler's diarrhea) and the endogenous peptides uroguanylin and guanylin. Here, by performing Northern and Western blots, and by measuring [125I]STa binding and STa-dependent elevation of cGMP levels, we investigate whether the distribution of GC-C matches that of its endogenous ligands in the rat intestine. We establish that 1) uroguanylin is essentially restricted to small bowel; 2) guanylin is very low in proximal small bowel, increasing to prominent levels in distal small bowel and throughout colon; 3) GC-C messenger RNA and STa-binding sites are uniformly expressed throughout the intestine; and 4) GC-C-mediated cGMP synthesis peaks at the proximal and distal extremes of the intestine (duodenum and colon), but is nearly absent in the middle (ileum). These observations suggest that GC-C's activity may be posttranslationally regulated, demonstrate that the distribution of GC-C is appropriate to mediate the actions of both uroguanylin and guanylin, and help to refine current hypotheses about the physiological role(s) of these peptides.
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