Abdominal obesity, insulin resistance, and colon carcinogenesis are increased in mutant mice lacking gastrin gene expression.

BACKGROUND: The authors recently reported that gastrin gene knockout (GAS-KO) mice had an increased risk for colon carcinogenesis in response to azoxymethane (AOM) compared with their wild type (WT) littermates. In the current report, the authors discuss the predisposition of GAS-KO mice to develop obesity and metabolic hormonal changes that may contribute to their increased risk of colon carcinogenesis. METHODS: The weight and deposition of fat was monitored in the mice over a 14 month period, using magnetic resonance imaging and nuclear magnetic resonance techniques. Changes in plasma concentrations of ghrelin, leptin, insulin, and glucose were assessed using radioimmunoassay analysis and enzyme-linked immunosorbent assays. Preneoplastic markers of colon carcinogenesis (aberrant crypt foci [ACFs]), in response to AOM, were measured in a subset of obese versus lean GAS-KO mice and were compared with the markers in WT mice. RESULTS: Increases in visceral adiposity were evident by age 2 months in GAS-KO mice, resulting in macroscopic obesity by age 7 months. Hyperinsulinemia and insulin:glucose ratios were increased significantly in GAS-KO mice as young as 1 month and preceded alterations in nonfasting leptin and ghrelin levels. The number of ACFs per mouse colon were increased significantly in the following order: obese GAS-KO mice > lean GAS-KO mice > WT mice. Fasting plasma insulin levels were 0.88 +/- 0.1 ng/mL, 1.45 +/- 0.3, and 2.76 +/- 0.9 ng/mL in the WT, GAS-KO lean, and GAS-KO obese mice, respectively. CONCLUSIONS: The current results suggest the novel possibility that loss of amidated gastrins may increase adipogenesis, hyperinsulinemia, and colon carcinogenesis in GAS-KO mice. The increase in colon carcinogenesis may be due in part to hyperinsulinemia, increased obesity, and other associated hormone changes that were measured in GAS-KO mice.

Synergistic effects of antiprogestins and iNOS or aromatase inhibitors on establishment and maintenance of pregnancy.

Progesterone is known to be involved in many steps in female reproduction including control of implantation and uterine-cervical function during pregnancy. Our studies in rats and guinea pigs indicate that progesterone inhibits uterine contractility and cervical softening during pregnancy. Progesterone levels or actions decline near the end of pregnancy leading to the onset of labor. Treatment with progestin agonists prolongs pregnancy and inhibits cervical softening, whereas treatment with antiprogestins (mifepristone or onapristone) stimulates uterine contractility, cervical softening and premature delivery. Thus the effect of progesterone receptor modulators in the uterus and cervix depend up on the degree of intrinsic agonistic/antagonistic activities. Our recent studies show that progesterone interacts with nitric oxide (NO) to maintain pregnancy and that administration of progesterone antagonists with NO synthase inhibitors act synergistically to stimulate labor. In addition our studies show that combinations of progesterone antagonists with aromatase inhibitors act synergistically to induce labor. Similarly antiprogestins interact with NO synthase or aromatase inhibitors to block implantation through action on the endometrium. These studies suggest new applications for combined therapies of progestin receptor modulators with aromatase inhibitors or agents that modify NO production for contraception, stimulation of labor, estrogen-dependent diseases and improved outcomes in pregnancy.

Binding of cationic cell-permeable peptides to plastic and glass.

Cell-penetrating peptides derived from hydrophilic regions of the homeoprotein Antennapedia (Antp) or the transcription-regulating factor Tat have been used to transport several peptide and oligonucleotide cargoes into the interior of cells. Such vector peptides penetrate cells, in part, because they contain multiple lysine and arginine residues. Using radiolabeled peptide cargoes covalently linked to Antp- or Tat-related vectors, or to D-Arg heptamers, we found that a significant amount of the label remained tightly bound to plastic and glass surfaces. Binding of the labeled conjugates was due entirely to the cationic vector moieties. Under certain conditions, such non-specific binding could be mistaken for cellular penetration.

Deletion of functional gastrin gene markedly increases colon carcinogenesis in response to azoxymethane in mice.

BACKGROUND & AIMS: We recently reported that transgenic mice overexpressing progastrin were at a higher risk for developing colon cancers in response to azoxymethane (AOM), whereas mice overexpressing gastrin-17 were at a reduced risk. To examine further the role of gastrins in colon carcinogenesis, we generated gastrin gene knockout mice (GAS-KO). METHODS: The height and proliferative index (PI) of colonic crypts were similar in GAS-KO and wild-type (WT) mice, suggesting that the absence of gastrins in GAS-KO mice did not significantly affect the growth of colonic mucosa. GAS-KO and WT mice were treated with AOM for 3-4 weeks; control mice received saline. RESULTS: Colonic proliferation in response to AOM was significantly increased in GAS-KO vs. WT mice. Aberrant crypt foci (ACFs) were similarly increased significantly by approximately 2-5-fold in GAS-KO vs. WT mice after 2 weeks of AOM treatment. Female GAS-KO mice developed adenomas (Ads) and adenocarcinomas (AdCAs) at earlier times ( approximately 10 months) than the male GAS-KO mice and the male and female WT mice ( approximately 12 months). The total numbers of Ads and AdCAs were significantly higher in GAS-KO than in WT mice. CONCLUSIONS: These results suggest the novel possibility that loss of gastrin expression (and hence amidated gastrins) significantly increases susceptibility to colon carcinogenesis in response to AOM. Previous studies with FVB/N transgenic mice similarly suggested a protective role of amidated gastrins against colon carcinogenesis, which supports the present findings of an increase in colon carcinogenesis in GAS-KO mice lacking normal physiological levels of amidated gastrins.