Role, mechanism of action and application of gonadoliberins in reproductive processes.

Gonadoliberin (gonadotropin releasing hormone, GnRH) plays a central role in the regulation of reproductive functions as it regulates the release of both luteinizing hormone (LH) and follicle stimulating hormone (FSH). The isolation and structure determination of GnRH opened the possibility of its use for influencing reproductive processes. This possibility initiated a rapid development in the design of potent and long-acting GnRH agonists and antagonists. The most important structural modifications of GnRH leading to superagonists are the D-amino acid substitutions in position 6 combined with Pro9-ethylamide or azaGly10 at the C-terminus. We have synthesized several superagonists of GnRH according to these substitution principles. Furthermore, our L-isoaspartyl modification in position 6, as a new approach to GnRH agonist design, also resulted in superactive analogs. The recently discovered sequences of non-mammalian GnRH-s opened new routes for us to synthesize species specific GnRH agonists. All three groups of the above mentioned GnRH analogs have been successfully used for the treatment of sexual disorders of different animals (cattle, pigs, rabbits, etc.). Ovulation synchronization and a 30% increase in the fertility rate could be achieved by using GnRH agonists in cattle breeding. Analogs derived from species specific sequences could be applied for the induced artificial propagation of fish even out of the spawning season. It is known that superactive GnRH analogs can suppress the growth of certain hormone-dependent tumours. In vitro and in vivo tests of our analogs showed promising antitumour activity in breast cancer which might be explained by the mechanism of desensitization. Almost a hundred antagonist analogs of GnRH have been developed in our laboratory. The most effective ones contain 4 or 5 D-amino acids, and one of them is even orally active. The inhibition of ovulation can also be achieved by the administration of GnRH superagonists. This phenomenon might also be explained by the desensitization of LH-release. Radioactive analogs specifically labeled with tritium in different amino acid residues have been synthesized and used for studying tissue distribution and biodegradation of gonadoliberins. Analogs containing a photoreactive group have been prepared and applied for the trials of GnRH receptor isolation.