There is extensive plasticity of the song behavior of birds and the neuroendocrine circuit that regulates this behavior in adulthood. One of the most pronounced examples of plasticity, found in every species of seasonally breeding bird examined, is the occurrence of large seasonal changes in the size of song control nuclei and in their cellular attributes. This seasonal plasticity of the song circuits is primarily regulated by changes in the secretion and metabolism of gonadal testosterone (T). Both androgenic and estrogenic sex steroids contribute to seasonal growth of the song system. These steroids act directly on the forebrain song nucleus HVC, which then stimulates growth of its efferent target nuclei transsynaptically. Seasonal growth and regression of the song circuits occur rapidly and sequentially following changes in circulating T and its metabolites. As the neural song circuits change across seasons, there are changes in different aspects of song behavior, including the structural stereotypy of songs, their duration, and the rate of production. The burden of evidence supports a model in which changes in song behavior are a consequence rather than a cause of the changes in the song circuits of the brain. Seasonal plasticity of the song system may have evolved as an adaptation to reduce the energetic demands imposed by these regions of the brain outside the breeding season, when the use of song for mate attraction and territorial defense is reduced or absent. The synaptic plasticity that accompanies seasonal changes in the song system may have acted as a preadaptation that enabled the evolution of adult song learning in some species of birds.