COOH-terminal 26-amino acid residues of progastrin are sufficient for stimulation of mitosis in murine colonic epithelium in vivo.

Transgenic mice (hGAS) that overexpress human progastrin are more susceptible than wild-type mice (FVB/N) to the induction of colonic aberrant crypt foci (ACF) and adenomas by the chemical carcinogen azoxymethane. We have previously shown significantly increased levels of colonic mitosis in hGAS compared with FVB/N mice after gamma-radiation. To investigate whether the effects of progastrin observed in hGAS colon require the presence of other forms of circulating gastrin, we have crossed hGAS (hg(+/+)) with gastrin knockout (G(-/-)) mice to generate mice that express progastrin and no murine gastrin (G(-/-)hg(+/+)). After azoxymethane, G(-/-)hg(+/+) mice developed significantly more ACF than control G(-/-)hg(-/-) mice (which do not express any forms of gastrin). G(-/-)hg(+/+) mice also exhibited significantly increased colonic mitosis both before and after exposure to 8 Gray Gy gamma-radiation or 50 mg/kg azoxymethane compared with G(-/-)hg(-/-). Treatment of G(-/-)hg(-/-) mice with synthetic progastrin (residues 21-101 of human preprogastrin) or G17 extended at its COOH terminus corresponding to the COOH-terminal 26-amino-acid residues of human preprogastrin (residues 76-101, G17-CFP) resulted in continued colonic epithelial mitosis after gamma-radiation, whereas glycine-extended gastrin-17 and the COOH-terminal tryptic fragment of progastrin [human preprogastrin-(96-101)] had no effect. Immunoneutralization with an antibody against G17-CFP before gamma-radiation significantly decreased colonic mitosis in G(-/-)hg(+/+) mice to levels similar to G(-/-)hg(-/-). We conclude that progastrin does not require the presence of other forms of gastrin to exert proliferative effects on colonic epithelia and that the portion of the peptide responsible for these effects is contained within amino acid residues 76-101 of human preprogastrin.

Regulation of parietal cell migration by gastrin in the mouse.

Recent studies suggest that gastrin regulates parietal cell maturation. We asked whether it also regulates parietal cell life span and migration along the gland. Dividing cells were labeled with 5'-bromo-2'-deoxyuridine (BrdU), and parietal cells were identified by staining with Dolichos biflorus lectin. Cells positive for D. biflorus lectin and BrdU were reliably identified 10-30 days after BrdU injection in mice in which the gastrin gene had been deleted by homologous recombination (Gas-KO) and wild-type (C57BL/6) mice. The time course of labeling was similar in the two groups. The distribution of BrdU-labeled parietal cells in wild-type mice was consistent with migration to the base of the gland, but in Gas-KO mice, a higher proportion of BrdU-labeled cells was found more superficially 20 and 30 days after BrdU injection. Conversely, in transgenic mice overexpressing gastrin, BrdU-labeled parietal cells accounted for a higher proportion of the labeled pool in the base of the gland 10 days after BrdU injection. Gastrin, therefore, stimulates movement of parietal cells along the gland axis but does not influence their life span.

Activated platelets adherent to an intact endothelial cell monolayer bind flowing neutrophils and enable them to transfer to the endothelial surface.

We have investigated the role that platelets may play in promoting adhesion of neutrophils to morphologically intact endothelium. Immortalized human microvascular endothelial cells (HMEC-1) were grown to confluence in a glass capillary (microslide) and incorporated in a flow-based assay that allowed video-microscopic quantitation of adhesive interactions of perfused, isolated neutrophils (wall shear rate 140 s(-1)). Platelets (with or without stimulation with thrombin) were first sedimented onto the HMEC-1 cells and formed discrete attachments covering <1% of the surface area. When neutrophils were perfused over the platelet-treated HMEC-1 cells, many short-lived adhesive interactions were seen (lasting approximately 0.3 seconds), whereas none were seen for monolayers without platelets. Few of these interactions converted to stationary adhesion, and only small numbers of neutrophils remained attached after a period of washout unless they were pre-stimulated with formyl peptide (fMLP; 10(-7) mol/L). Then about 30% of adhesive interactions by activated neutrophils were seen to transform to a stationary adhesion, and numerous adherent cells remained after a period of washout. Studies with function-blocking antibodies showed that capture of the neutrophils was dependent on P-selectin exposed on platelets. Initial immobilization was mediated predominantly by the beta2-integrin CD11b/CD18 expressed by neutrophils, but CD11a/CD18 also appeared to play a role in prolonged attachment. Visually, adhesion first occurred at sites occupied by platelets, but some activated neutrophils migrated onto the endothelial cells. These studies indicate that even small numbers of platelets that have adhered to morphologically intact endothelium have the potential to capture flowing neutrophils and facilitate their immobilization at the vessel wall and so promote inflammatory and thrombotic intercellular interactions.