Growth hormone and colorectal carcinoma: localization of receptors.

Growth hormone (GH) plays a crucial role in stimulating and controlling the growth, metabolism and differentiation of many mammalian cell types by modulating the synthesis of multiple mRNA species and a paracrine or autocrine mechanism of action has been proposed. These effects are mediated by the binding of GH to its membrane-bound receptor and involve a phosphorylation cascade that results in the modulation of numerous signaling pathways. To address the side/mode of action through which GH exerts its effects, a panel of well characterized monoclonal antibodies, directed against the hormone binding side of the receptor, was applied to immunohistochemically determine growth hormone receptor (GH-receptor) expression in poorly- moderate- to well differentiated col.orectal adenocarcinomas (n = 40) from the rectum, transverse-, ascending-, descending and sigmoid colons. Of five anti-growth hormone receptor monoclonal antibodies used, human GH- receptor specific Mab 263 consistently resulted in strong receptor expression in colorectal carcinoma tumour cells. Heterogeneity of immunoreactivity was found in primary and secondary tumour lesions with a variable range of positive cells. Staining was mainly intracellular, showing either a monotonous or granular pattern, with some nuclei also reactive. The presence of intracellular GH-receptors has been previously documented and is a result of endoplasmic reticulum and Golgi localization. Immunoreactivity in surface columnar cells, independent from pathological tissue, was weak to moderate. Epithelial cells from normal tissue, adjacent to tumour lesions, were of variable intensity. Goblet and mucous cells located at the crypt base immunostained faintly or were negative for the GH-receptors. Crypt base columnar cells strongly expressed the GH-receptor, but oligomucous cells were less reactive. In conclusion, this study indicates that receptor expression may be associated with malignancy of colorectal carcinoma and supports the hypothesis that GH may act locally in colorectal tissue. The demonstration of the presence of receptors for GH will be useful for site-specific studies of the evolution of gastrointestinal tract tumours, providing valuable information concerning cellular growth kinetics and tumour prognosis. It also raises questions regarding the administration of GH to cancer-induced cachexia patients and the possible oncogenic potential of the GH-receptor.

In utero cardiac gene transfer via intraplacental delivery of recombinant adenovirus.

BACKGROUND: The relationship among the maternal, placental, and uniquely shunted embryonic circulation was explored to provide access to the embryonic cardiovascular system in utero. Manipulation of gene expression in the developing heart would be particularly useful for studying the effects of altered gene expression on cardiac development and in the etiology of congenital cardiac anomalies. METHODS AND RESULTS: Dye studies demonstrated that intraplacental injection allows direct access to the embryonic cardiac and systemic circulation. To evaluate the efficacy of cardiac gene transfer using this approach, replication-deficient recombinant adenoviral vectors encoding luciferase or beta-galactosidase as reporter genes were injected intraplacentally into embryonic day (E)12.5 murine embryos, an age at which the mass of the heart was observed to be large compared with other organs. Embryos were assayed for transgene expression at E15.5 and at birth. Survival rates at these times were similar among vector-injected and control groups. At E15.5 and at birth, luciferase activity within the heart was 9- and 23-fold higher, respectively, than in the remainder of the embryo, although levels of expression were generally lower at birth than during embryonic life. Beta-galactosidase expression was observed within all regions of the embryonic heart and was localized to approximately 15% of atrial and ventricular cells. CONCLUSIONS: Intraplacental delivery of adenovirus at embryonic day 12.5 results in somatic gene transfer to the murine embryonic heart, which persists at least until birth. The combination of intraplacental injection to directly access the fetal coronary circulation and injection at E12.5 when the mass of the heart is large compared with other organs results in transgene expression in cardiac cells. Intraplacental injections early in embryonic life may thus be useful to study the effects of temporal manipulation of gene expression on cardiac development and disease.