During the course of the current project we have shown, for the first time in a living, conscious vertebrate, synchronized activity of migrating GnRH neurons. These studies, impossible to perform in mammals, reveal a completely new form of communication between migrating GnRH cells and suggest a new pathway for the regulation of GnRH circuit development. This synchronization is extremely robust and is present both within the GnRH cells in a single hemisphere as well as between the cells of the two hemispheres. Moreover, instead of being driven by external inputs, the observed synchronization is mediated within the GnRH circuit. Perturbing the synchronization (generally, by expressing botulinum toxin in GnRH cells, or by knocking-down GnRH expression) causes significant migration defects. This notion of an independent, isolated, self-regulated circuit contributes to the evolutionary robustness of the circuit that controls the critical process of reproduction.
By monitoring calcium dynamics in zebrafish gonadotropes we have succeded, for the first time in any organism, to simultaneously record spontaneous and stimulated activity patterns of FSH and LH cells in situ. We describe different spontaneous activity patterns and coupling dynamics between the two types of gonadotropes that underlie their differential mode of their secretion.
Due to the promising initial results, we have decided to continue the project beyond the current funding period. The study now concentrates on identifying the molecular signals that are used by the GnRH cells to communicate and identifying the reproductive consequences of impaired GnRH migration in fish. In gonadotropes we are concentrating on understanding how different GnRH patterns elicit LH or FSH-specific responses.
Our results pave the way for the development of new tools to control reproduction in fish through manipulating GnRH neuronal migration and deepen our understanding of the secretion patterns of LH and FSH in fish. These insights will be used in the future to design better strategies for controlling and manipulating reproduction in commercially important species. In addition, we revealed a new mechanism for the regulation of GnRH cell migration that sheds light on the evolution of the reproductive axis in vertebrates.