Organismal development is a highly regulated process; its dysregulation can lead to disease. Yet, it is also flexible to make it responsive to the environment. One aspect of the environment is the social interactions among organisms. Whereas it is generally understood that these are important, the specific ways in which they affect organisms remain substantially unknown. Recent estimates, however, suggest that the impact of social interactions could be comparable in magnitude to the effect of genes. This necessitates the development of tractable model systems in which to study this problem. We addressed this challenge by studying the effects of social signals on development of a well-established model organism, C. elegans. We found that signals produced by males powerfully affect development and reproductive physiology of hermaphrodites, which are effectively female. Specifically, sensing the male presence makes hermaphrodites progress through puberty faster and increase the commitment to production of gametes. Our experiments have uncovered that these processes are controlled by largely distinct mechanisms that rely on highly conserved neuroendocrine signals that include steroids, insulins, and serotonin. Taking advantage of the specific strengths of our model system and these preliminary findings we will investigate: (1) How the male signals alter the temporal regulation of development and specifically the progression of puberty; (2) How sensory neurons integrate multiple signals and communicate them to the gonad, where they affect the germline development; and (3) The role of the sexual identity of specific cells in producing and responding to sex-appropriate signals. Importantly, although we study these problems in C. elegans, strikingly similar phenomena have been documented in all animals studied so far, including mammals. Moreover, defects in the timing of puberty, neuroendocrine control of reproduction, and sexual identity of cells have been implicated in numerous human disease conditions. This raises a possibility that social signals might play a role in their pathology. Regardless, a better mechanistic understanding of these processes would lead to a better understanding of the underlying biology of these disease states. Because all molecular components we identified so far are highly conserved among all animals, we expect our work will offer insights for further research on the role of social signals in regulation of development and physiology. It may thus prove useful for a better understanding and, ultimately, treatment of relevant disease states in humans.
Social signals exchanged by animals can alter the course of normal development and are an important factor in modifying health and disease, yet the mechanisms of these effects remain largely unexplored. Using a well-established model organism C. elegans, we developed a powerful paradigm to study how specific signals sent by males alter several aspects of female development. We expect our findings to reveal the basic mechanisms controlling developmental timing and germline proliferation in all animals, including humans, with potential implications for congenital abnormalities and effects of social environment on disease states.