Raktima Raychowdhury

Synergistic interaction between hypergastrinemia and Helicobacter infection in a mouse model of gastric cancer.

BACKGROUND & AIMS Hypergastrinemia occurs frequently in association with acid suppression and Helicobacter infection, but its role in the progression to gastric atrophy and gastric cancer has not been well defined. METHODS The effects of hypergastrinemia, and possible synergy with Helicobacter felis infection, were investigated in insulin-gastrin (INS-GAS) transgenic mice. RESULTS INS-GAS mice initially showed mild hypergastrinemia, increased maximal gastric acid secretion, and increased parietal cell number but later progressed to decreased parietal cell number and hypochlorhydria. Development of gastric atrophy was associated with increased expression of growth factors, heparin-binding epidermal growth factor and transforming growth factor alpha. At 20 months of age, INS-GAS mice showed no evidence of increased enterochromaffin-like cell number, but instead exhibited gastric metaplasia, dysplasia, carcinoma in situ, and gastric cancer with vascular invasion. Invasive gastric carcinoma was observed in 6 of 8 INS-GAS mice that were >20 months old. Helicobacter felis infection of INS-GAS mice led to accelerated (< or = 8 mo) development of intramucosal carcinoma (85%), with submucosal invasion (54%) and intravascular invasion (46%; P < or = 0.05). CONCLUSIONS These findings support the unexpected conclusion that chronic hypergastrinemia in mice can synergize with Helicobacter infection and contribute to eventual parietal cell loss and progression to gastric cancer.

Activation of Human Histidine Decarboxylase Gene Promoter Activity by Gastrin Is Mediated by Two Distinct Nuclear Factors

The human histidine decarboxylase gene is regulated by gastrin through a cis-acting element known as the gastrin response element (GAS-RE) that was initially localized to a site (+2 to +24) downstream of the transcriptional start site. Electrophoretic mobility shift assays using sequentially deleted DNA probes and nuclear extracts from AGS-B gastric cancer cells showed that the GAS-RE is actually composed of two overlapping binding sites (GAS-RE1, +1 to +19; and GAS-RE2, +11 to +27) that bind distinct nuclear factors. Reporter gene assays demonstrated that each element alone could confer gastrin responsiveness, but the presence of both elements was required for complete gastrin response. Stimulation of AGS-B cells with gastrin for 10–20 min resulted in a >2-fold increase in factor binding. The binding was inhibited by pretreatment of AGS-B cells with cycloheximide and the MEK1 inhibitor PD98059, indicating a requirement for protein synthesis and also indicating that activation occurs through the MEK/mitogen-activated protein kinase pathway. UV cross-linking and Southwestern blot analysis showed that GAS-RE1 bound a 52-kDa protein, whereas GAS-RE2 bound a 35-kDa protein. Hence, activation of histidine decarboxylase gene promoter activity by gastrin is most likely mediated by two separate nuclear factors.

Autoinduction of the trefoil factor 2 (TFF2) promoter requires an upstream cis-acting element.

Trefoil factor 2 (TFF2)/spasmolytic polypeptide (SP) is a highly stable peptide which is abundantly expressed and secreted by mucous cells of the stomach and which functions in gastric cytoprotection. Previous studies from our group have shown that TFF2 is an immediate early gene capable of regulating its own expression through activation of the TFF2 promoter. We therefore aimed to investigate the cis-acting elements mediating this response in AGS cells transfected with TFF2 promoter-reporter gene constructs, using a TFF2-expression system resembling physiologic paracrine conditions. TFF2 peptide expression was achieved through stable transfection of AGS cells with a TFF2-expression construct. Stimulation of transiently transfected cells with this TFF2-containing conditioned media resulted in a significant increase in TFF2 promoter activity. Promoter stimulation was blocked by an anti-TFF2 antibody, indicating that it was mediated specifically by TFF2. Deletion analysis of the TFF2 promoter led to the identification of a specific response element located between -191 and -174 upstream of the transcriptional initiation site. This region of the promoter, which was designated SPRE (for spasmolytic polypeptide response element), was sufficient to confer responsiveness in a heterologous promoter system. Mutational analysis and electrophoretic mobility shift assays (EMSA) showed that a GAG motif was responsible for mediating promoter activation in response to TFF2 stimulation. Since auto- and cross-induction of TFF2 promoter is likely to be a means of rapid amplification of TFF2 expression in the critical first minutes following mucosal injury, these results should lead to insight into the molecular events initiating epithelial restitution and healing.

Identification and characterization of a new gastrin response element (GAS-RE3) in the human histidine decarboxylase gene promoter

In human gastric cancer cells the human histidine decarboxylase gene is regulated by gastrin through two overlapping cis-acting elements known as gastrin response elements 1&2 (GAS-RE1, GAS-RE2) [J. Biol. Chem. 274 (1999) 20961]. Here, we report the identification and characterization of a third element GAS-RE3 that was localized to a region +28 to +48 downstream of the transcriptional start site (+1). Gastrin stimulation induced a rapid increase in binding to the element of a novel nuclear factor named gastrin response element-binding protein 3 (GAS-REBP3). Block mutations in the GAS-RE3 sequence (+38GTGCG(+42) to +38TAAGT(+42)) led to reduced promoter activity and decreased binding in EMSA. UV cross-linking studies and Southwestern blot analysis with wildtype and mutant GAS-RE3 showed that GAS-REBP3 was a approximately 110kDa protein. Thus, gastrin-mediated regulation of HDC gene expression appears to be mediated by a complex cis-acting element, which binds at least three distinct nuclear factors.