A network map of the gastrin signaling pathway

Abstract

Gastrin is the primary hormone that induces gastric acid secretion (Edkins 1906). In humans, the gene encoding for gastrin is located on chromosome 17q21 (Lund et al. 1986). This hormone is produced by the G-cells of the antrum of stomach as preprogastrin, which comprises of 101 amino acids and is cleaved between Ala-21 and Ser-22 to yield progastrin (Reeve et al. 1984). Progastrin is then sequentially cleaved by prohormone convertase and carboxypeptidase E to yield glycine-extended gastrins- a 35-amino acid gastrin-34-Gly (G34-Gly) or an 18-amino acid gastrin-17-Gly (G17-Gly) in endocrine cells (Varro et al. 1995; Lacourse et al. 1997). G34-Gly and G17-Gly are amidated at their carboxyl terminal groups by the enzyme peptidyl alpha-amidating mono-oxygenase to form amidated gastrin. Gastrin interacts with the membrane-bound G-protein coupled cholecystokinin receptor group consisting of Cholecystokinin A receptor (CCKAR) and Cholecystokinin B receptor (CCKBR). CCKAR possesses high affinity for cholecystokinin and has a negligible affinity for gastrin (Ferrand and Wang 2006; Dufresne et al. 2006). However, CCKBR has a high affinity for gastrin and their carboxyl amidated analogues. CCKBR is expressed in the brain, smooth muscle cells, and parietal cells (Kopin et al. 1992; Berna et al. 2007). In addition to this, gastrin has also been reported to interact with annexin 2, and thereby exerts proliferation effects in gastrointestinal cancers (Singh et al. 2007; Singh 2007; Sarkar et al. 2012). The release of gastrin is induced by gastrin-releasing peptide, a neurotransmitter which acts on its basolateral receptor in the G-cells. Binding of gastrin to CCKBR present in parietal and enterochromaffin-like (ECL) cells (Schmitz et al. 2001; Kulaksiz et al. 2000)induces gastric acid secretion by parietal cells as well as histamine release by ECL cells (Dockray et al. 2005). The released histamine reaches parietal cells by paracrine diffusion where it binds H2 receptors and induces gastric acid secretion. The secretion of gastric acid inhibits the release of gastrin hormone rendering a negative feedback control, further preventing excess acid secretion. In addition, low pH value in the stomach inhibits gastrin release through stimulating somatostatin secretion by antral D-cells (Bloom et al. 1974). Gastrin is a well-known growth factor for the gastrointestinal tract. Gastrin stimulates proliferation of gastric mucosal cells (Hansen et al. 1976), maturation of parietal cells and enterochromaffin-like cells (Jain and Samuelson 2006), and promotes islet differentiation in the pancreas (Wang et al. 1993). It has also been shown to stimulate proliferation of gastric (Ishizuka et al. 1992) and colon cancer cells (Watson et al. 1989). Gastrin modulates invasion (Wroblewski et al. 2002), apoptosis (Przemeck et al. 2008; Todisco et al. 2001) and migration (Noble et al. 2003) in epithelial cells. Both glycine-extended gastrin and amidated gastrin have been reported to induce angiogenesis (Clarke et al. 2006; Lefranc et al. 2004). Moreover, the hypergastrinemic state has been associated with diverse physiological disorders in humans and other mammals. These include atrophic gastritis (Lehy et al. 2000), pernicious anemia (Orlando et al. 2007), excess acid secretion leading to duodenal ulcer disease in Helicobacter pylori infection (Berna et al. 2006; Jensen 2002; Scarpignato et al. 1996) and gastrinoma (Kloppel and Anlauf 2007). Recently, a number of research groups have explored the feasibility of using gastrin to treat various diseases. Gastrin has been used in combination therapy with epidermal growth factor to increase beta-cell mass which reversed hyperglycemia in diabetic mice (Suarez-Pinzon et al. 2005). Gastrin-stimulated beta cell neogenesis when used in combination with glucagon-like peptide 1 in human pancreatic duct cell transplanted in immunodeficient diabetic mice (Suarez-Pinzon et al. 2008). Gastrins and their receptors have been suggested as potential targets to treat gastrointestinal and pancreatic cancers (Rengifo-Cam and Singh 2004). Gastrin has also been shown to have therapeutic promise as it inhibits the growth of cholangiocarcinoma cells by promoting apoptosis (Kanno et al. 2001). On account of the functional significance of different natural forms of gastrin, we have assembled signaling pathway reactions induced by them upon binding to gastrin receptor(s) in different human cell types. These manually curated signaling events are made available through NetPath (http://www.netpath.org/) (Kandasamy et al. 2010) in different formats for analysis by the scientific community.