Activation of gastrin transcription in pancreatic insulinoma cells by a CACC promoter element and a 70-kDa sequence-specific DNA-binding protein

K-ras and B-raf gene mutations are not associated with gastrin- and CCK2-receptor mRNA expression in human colorectal tumour tissues

BACKGROUND

Colorectal cancer is a multistep process caused by genetic alterations in cell growth regulatory genes such as K-ras and B-raf. It has been assumed that mutations in the K-ras gene induce gastrin gene expression and that gastrin stimulates the growth of colorectal cancer in an autocrine fashion by coexpressing gastrin and cholecystokinin (CCK)2 receptors. The aim of this study was to examine a possible association of K-ras and B-raf gene mutations with gastrin and CCK2 receptor mRNA expression in human colon and rectum tumour biopsy specimens.

METHODS

K-ras and B-raf gene mutations as well as gastrin and CCK2 receptor mRNA expression in 50 colon and 46 rectum biopsies, respectively, were determined using molecular biology methods.

RESULTS

K-ras mutations occurred in 44% colon and 30% rectum and B-raf mutations in 16% colon and 4% rectum tumours, respectively. Gastrin mRNA was expressed in 64% colon and 61% rectum tumours, whereas CCK2 receptor mRNAs was expressed in 32% colon and 13% rectum tumours. K-ras or B-raf gene mutations and simultaneous gastrin mRNA expression was observed in 40% colon and 17% rectum tumours, respectively. Co-expression of gastrin and CCK2 receptor mRNA occurred in 20% colon and 9% rectal tumours.

CONCLUSIONS

The results do not support the hypothesis that K-ras and B-raf gene mutations have an impact on gastrin- and CCK-receptor mRNA expression in colorectal tumour tissues.

Gastrin is a target of the beta-catenin/TCF-4 growth-signaling pathway in a model of intestinal polyposis

Mutations in the adenomatous polyposis coli (APC) tumor suppressor gene occur in most colorectal cancers and lead to activation of beta-catenin. Whereas several downstream targets of beta-catenin have been identified (c-myc, cyclin D1, PPARdelta), the precise functional significance of many of these targets has not been examined directly using genetic approaches. Previous studies have shown that the gene encoding the hormone gastrin is activated during colon cancer progression and the less-processed forms of gastrin are important colonic trophic factors. We show here that the gastrin gene is a downstream target of the beta-catenin/TCF-4 signaling pathway and that cotransfection of a constitutively active beta-catenin expression construct causes a threefold increase in gastrin promoter activity. APC(min-/+) mice overexpressing one of the alternatively processed forms of gastrin, glycine-extended gastrin, show a significant increase in polyp number. Gastrin-deficient APC(min-/+) mice, conversely, showed a marked decrease in polyp number and a significantly decreased polyp proliferation rate. Activation of gastrin by beta-catenin may therefore represent an early event in colorectal tumorigenesis and may contribute significantly toward neoplastic progression. The identification of gastrin as a functionally relevant downstream target of the beta-catenin signaling pathway provides a new target for therapeutic modalities in the treatment of colorectal cancer.

Developmental biology of gastrin and somatostatin cells in the antropyloric mucosa of the stomach

Gastrin is a hormone regulating gastric acid secretion and the growth of the gastrointestinal epithelium. It is expressed by endocrine tumors and by adenocarcinomas of the gastroenteropancreatic region and may represent an autocrine tumor growth factor. Gastrin is also implicated in the genesis of peptic ulcer disease both in conjunction with H. pylori infections and with gastrin-producing tumors. The secretion and expression of gastrin are under the paracrine control of somatostatin, produced by D cells situated in close contact with gastrin-producing G cells. D cells also contain neuronal nitric oxide synthase and appear to regulate apoptosis of G cells by paracrine release of nitric oxide. Both G and D cells are derived from a common multihormonal precursor cell present in the regenerative (isthmus) region of the gastric units. The precursor cells have been suggested to undergo asymmetrical divisions resulting in gastrin- and somatostatin-producing daughter cells that remain in paracrine contact during their migration into the glands. The precursor cells also give rise to the third main antropyloric endocrine cell type; the serotonin-producing EC cell. The maturation of all of these cell types is regulated by a number of transcription factors containing homeobox motifs (Pdx-1, Pax 4 and 6, Isl-1, Nkx6.1). Many of these also regulate the development of the central nervous system and the pancreas. The use of different combinations of these factors for regulating the expression of different hormones may explain the phenomenon of abberant hormone expression during development and carcinogenesis and the occurrence of multihormonal cells.

Composite action of three GC/GT boxes in the proximal promoter region is important for gastrin gene transcription

The proximal region of the human gastrin gene promoter contains three GC/GT boxes at positions -140 to -134 bp, -108 to -102 bp and -67 to -61 bp. In this study we have examined the significance of the three elements, and their role in Sp1 and Sp3 mediated gastrin transcription. In AGS cells, mutation of each of the boxes caused a moderate decrease in promoter activity from 33 to 63%, whereas double or triple mutations reduced activity to 3-12%. In Drosophila cells Sp1 activated the promoter, mainly through the distal GC box. Similarly, co-transfection of heterologous promoter constructs revealed that only the distal GC box increased activation by Sp1. The effect of Sp3 was cell-line dependent, since Sp3 inhibited the gastrin promoter activity in AGS cells and caused a synergistic activation of the Sp1 stimulated gastrin promoter in Drosophila cells. Both effects were dependent on the C-terminal DNA binding domain of Sp3. The results indicates that the combined effect of the GC/GT boxes and the ratio between Sp1 and Sp3 are important for gastrin gene expression.

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.

RIN ZF, a novel zinc finger gene, encodes proteins that bind to the CACC element of the gastrin promoter

Expression of gastrin, a gut hormone and growth factor, has tissue-specific transcriptional regulation and can be induced in some tumors. Previous studies have shown that a CACC cis-regulatory element is important for transcriptional activation in pancreatic insulinoma cells. To identify CACC-binding proteins, a lambda phage cDNA library derived from a rat insulinoma cell line, RIN 38A, was screened by a Southwestern method. A novel member of the Cys2-His2 zinc finger gene family was cloned and designated RIN ZF, having a cDNA sequence of 3.8 kilobases. One full-length and a shorter splice variant were sequenced and had predicted protein masses of 91.6 and 88.7 kDa. Expression of both splice forms were ubiquitous in fetal and adult rat tissues. Recombinant RIN ZF protein exhibited sequence-specific binding to the gastrin CACC element in a gel mobility shift assay. In transient transfections, both splice variants appeared to have only weak activating effects on gastrin-luciferase reporter gene transcription. Furthermore, RIN ZF coexpression with Sp1 appeared to block the strongly activating effects of Sp1 mediated through the CACC element. These findings suggest that a novel set of zinc finger proteins may help regulate gastrin gene expression by interfering with Sp1 transactivation.

The transcriptional silencer protein NRF: a repressor of NF-kappa B enhancers

NF-kappa B/rel proteins are present in most cell types. In concert with other transcriptional factors they regulate a variety of genes which contribute to a wide spectrum of physiological activities like inflammation and apoptosis. An excellent example of this combinatorial regulation takes place in the IFN-beta promoter. In this promoter the fundamental regulatory elements are assembled within less than 100 base pairs including a NF-kappa B/rel enhancer and a negative regulatory element, called NRE. NRE is a member of a new class of transcriptional repressor sequences with a silencing capacity targeted to the NF-kappa B/rel enhancer. NRF is a novel transcriptional factor that binds to NRE. NRF belongs to a major class of transcriptional repressors that interact with specific promoter elements and repress transcription by separable repression domains. Such molecules have been termed active repressors, because they act by inhibitory protein-protein interaction and not simply by steric hindrance.

RAP1-like binding activity in islet cells corresponds to members of the Sp1 family of transcription factors

Deletion and mutational analyses of the gastrin promoter have identified a binding site for the yeast transcription factor RAP1 relevant for transcriptional activation in islet cells. We here report that the mammalian transcription factors binding to this site in islet cells are the Sp transcription factor members Sp1 and Sp3. Furthermore, functional analyses revealed Sp1- and Sp3-mediated transcriptional activation of gastrin. These data reveal that the zinc finger proteins Sp1 and Sp3 do have similar binding specificities as the multifunctional yeast RAP1 protein.

Transient transcriptional activation of gastrin during sodium butyrate-induced differentiation of islet cells

Transient expression of pancreatic gastrin corresponds to a period of rapid islet cell development. After birth gastrin expression silencing is coincidental with islet cell terminal differentiation, while persistent expression is accompanied with nesidioblastosis and reexpression observed in islet cell tumors. Experiments with transgenic animals suggested that gastrin might act synergistically with growth factors to stimulate islet cell development. The present study intended to establish an in vitro cell culture model to analyse the molecular events controlling gastrin gene activation and repression dependent on islet cell differentiation. Sodium butyrate, a proliferation-arresting compound has previously been shown to differentiate insulinoma cells while increasing insulin production. The present paper demonstrates concomitant transient increase in gastrin mRNA, intracellular and secreted gastrin during sodium butyrate treatment. Increased gastrin expression was due to activation or derepression of gastrin promoter activity as revealed by promoter analyses. This in vitro model mimics the expression pattern of gastrin and insulin observed during fetal islet cell development and provides an excellent tool to analyse the molecular mechanisms controlling gastrin gene activation and selective repression during islet cell differentiation.

A distal Sp1-element is necessary for maximal activity of the human gastrin gene promoter

Studies of transgenic mice have shown that transcriptional control of the gastrin gene exhibits significant species differences. Transfection of the human gastrin promoter in murine cells have depicted proximal Sp1, E-box and CACC elements as the major determinants of transcription. We have examined cis-regulatory elements of the human promoter on a human gastrin expressing cell line and find that a distal -135 to -142 Sp1 element is necessary for maximal activity. Alignment of the mouse and human promoters shows that the proximal human Sp1 and CACC elements are not conserved, whereas the E-box element is retained. The distal Sp1 element is present in mouse but exhibits a C to T transition in the core that is likely to reduce binding affinity of Sp1. We conclude that gastrin gene transcription is regulated by distinct elements in man and rodents.

The LIM-homeodomain protein Isl-1 segregates with somatostatin but not with gastrin expression during differentiation of somatostatin/gastrin precursor cells

The gastric epithelium is renewed from stem cells in the isthmus of the gastric glands. We describe that the two neuroendocrine peptides gastrin and somatostatin are coexpressed by isthmic stem cells. Bromodeoxyuridine labeling indicates that the coexpressing cells divide and differentiate into gastrin and somatostatin cells, which remain in paracrine contact during most of their migration down into the gland. The coexpressing cells display nuclear immunoreactivity for the transcription factors Isl-1 and CREB, which have been implicated in somatostatin gene expression. Differentiated gastrin cells lack Isl-1 reactivity and show variable staining for CREB while differentiated somatostatin cells display Isl-1 and CREB reactivity.

Mutually exclusive interactions between factors binding to adjacent Sp1 and AT-rich elements regulate gastrin gene transcription in insulinoma cells

The gastrin gene is transiently expressed in fetal pancreatic islets during islet neogenesis but then switched off after birth when islet cells become fully differentiated. Previous studies identified a cis-regulatory sequence between -109 and -75 in the human gastrin promoter which binds islet cell-specific activators and a nonspecific repressor and thus may act as a molecular switch. The present study identified another cis-regulatory sequence (-163ACACTAAATGAAAGGGCGGGGCAG-140) which bound two islet nuclear proteins in a mutually exclusive manner, as defined by gel shift competition, methylation interference, and DNase I foot-printing assays. The general transactivator Sp1 recognized the downstream GGGCGGGG sequence, but Sp1 binding was prevented when another islet factor bound to the adjacent AT-rich sequence (CTAAATGA). This gastrin AT-rich element is nearly identical to the binding site (ATAAATGA) for the islet-specific transcription factor beta TF-1. However, the gastrin AT-binding factor appeared to differ from beta TF-1 in its gel mobility shift pattern. Transfections of rat insulinoma cells revealed that mutations which blocked binding to the AT-rich element but allowed Sp1 binding up-regulated transcriptional activity. These results suggest that the gastrin AT-binding factor blocks transactivation by Sp1 and may have a role in the repression of gastrin transcription seen at the end of islet differentiation.