23 research outputs found
Knocking down gene expression for growth hormone-releasing hormone inhibits proliferation of human cancer cell lines
Splice Variant 1 (SV-1) of growth hormone-releasing hormone (GHRH) receptor, found in a wide range of human cancers and established human cancer cell lines, is a functional receptor with ligand-dependent and independent activity. In the present study, we demonstrated by western blots the presence of the SV1 of GHRH receptor and the production of GHRH in MDA-MB-468, MDA-MB-435S and T47D human breast cancer cell lines, LNCaP prostate cancer cell line as well as in NCI H838 non-small cell lung carcinoma. We have also shown that GHRH produced in the conditioned media of these cell lines is biologically active. We then inhibited the intrinsic production of GHRH in these cancer cell lines using si-RNA, specially designed for human GHRH. The knocking down of the GHRH gene expression suppressed the proliferation of T47D, MDA-MB-435S, MDA-MB-468 breast cancer, LNCaP prostate cancer and NCI H838 non-SCLC cell lines in vitro. However, the replacement of the knocked down GHRH expression by exogenous GHRH (1–29)NH2 re-established the proliferation of the silenced cancer cell lines. Furthermore, the proliferation rate of untransfected cancer cell lines could be stimulated by GHRH (1–29)NH2 and inhibited by GHRH antagonists MZ-5-156, MZ-4-71 and JMR-132. These results extend previous findings on the critical function of GHRH in tumorigenesis and support the role of GHRH as a tumour growth factor
A method for evaluation of activity of antagonistic analogs of growth hormone-releasing hormone in a superfusion system.
Antagonistic analogs of growth hormone-releasing hormone (GHRH) are being synthesized in our laboratory for various clinical applications, including treatment of certain endocrine disorders and insulin-like growth factor I-dependent tumors. To evaluate the endocrine effect of these GHRH antagonists, a sensitive dynamic in vitro system has been developed. The concentration causing 50% inhibition (IC50) of the standard GHRH antagonist human [N-Ac-Tyr1,D-Arg2]GHRH-(1-29)-NH2 is 4.5 x 10(-8) M in our dispersed pituitary cell superfusion system. This value is 11 times less than that measured in earlier static pituitary cell cultures. This reliable dynamic system is simple, fast, and inexpensive and not only makes it possible to obtain quantitative data on the inhibitory capacity of the antagonists but also provides information about the intrinsic GHRH activity of the analog. The dynamic interactions of the GHRH antagonist, the GHRH receptors, and GH release can also be evaluated by this superfusion system. The pulsatile GH release induced by 10(-9) M human GHRH-(1-29)-NH2 was inhibited by two modes of application, preincubation and simultaneous administration of the GHRH antagonist (10(-9) to 10(-6) M). The reduction in GHRH-stimulated GH response was more pronounced when the cells were preincubated with the antagonist prior to GHRH infusion than for simultaneous application. The inhibitory effect of the antagonist was dose-dependent, temporary, and of the competitive type. GH release induced by nonspecific stimulus (100 mM potassium chloride) was not influenced by the GHRH antagonist. This sensitive dynamic in vitro system appears to be a suitable method for screening the biological activity of various GHRH antagonists and eliminates the drawbacks of static pituitary cell culture
Synthesis and biological activities of highly potent antagonists of growth hormone-releasing hormone.
In the search for antagonists of human growth hormone-releasing hormone (hGHRH) with high activity, 22 analogs were synthesized by solid-phase methods, purified, and tested biologically. Within the N-terminal sequence of 28 or 29 amino acids of hGHRH, all the analogs contained D-Arg2, Phe(4-Cl)6 (para-chlorophenylalanine), Abu15 (alpha-aminobutyric acid), and Nle27 and most of them had Agm29 (agmatine) substituents. All the peptides, except one, were acylated at the N terminus with different hydrophobic acids--e.g., isobutyric acid (Ibu) or 1-naphthylacetic acid (Nac) in order to study the effect of N-terminal acylation on the antagonistic activity. In the superfused rat pituitary cell system, all the analogs inhibited more powerfully the GHRH-induced growth hormone (GH) release than the standard GHRH antagonist [Ac-Tyr1,D-Arg2]hGHRH-(1-29)NH2. Antagonists [Ibu0,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]hGHRH-(1-28) Agm (MZ-4-71), [Nac0,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]hGHRH-(1-28) Agm (MZ-4-243), [Nac0,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]hGHRH-(1-29) NH2 (MZ-4-169), [Nac0-His1,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]-hGH RH-(1-29)NH2 (MZ-4-181), and [Nac0,D-Arg2,Phe(4-Cl)6,Abu15,Nle27,Asp28]hGH RH-(1-28)Agm (MZ-4-209) inhibited GH release at 3 x 10(-9) M. Among these peptides, MZ-4-243, MZ-4-169, and MZ-4-181 were also long acting in vitro. Antagonist MZ-4-243 inhibited GH release 100 times more powerfully than the standard antagonist and was the most potent in vitro among GHRH antagonists synthesized. Analogs with high inhibitory effects in vitro were also found to have high affinities to rat pituitary GHRH receptors. In experiments in vivo, antagonists [Ibu0,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]-hGHRH-(1-28 )Agm (MZ-4-71), [Nac0,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]hGHRH-(1-29) NH2 (MZ-4-169), and [Nac0-His1,D-Arg2,Phe(4-Cl)6,Abu15,Nle27]hGHR H-(1-29)NH2 (MZ-4-181) induced a significantly greater inhibition of GH release than the standard antagonist. In view of their high antagonistic activity and prolonged duration of action, some of these antagonists of GHRH may find clinical applications, including treatment of certain endocrine disorders and insulin-like growth factor I-dependent tumors