IntroductionVertebrates that synchr

Introduction
Vertebrates that synchronize reproductive effort with seasonally-dependent environmental cues provide discrete time points to identify how natural cyclical variation in physiological mechanisms coordinate the performance of specific behaviors, such as vocalization, for successful reproduction. Though many species of fish generate sound in reproductive contexts, we focus on the plainfin midshipman fish, Porichthys notatus, which has proven to be an excellent model to identify neuroendocrine mechanisms underlying seasonal plasticity in vocal-acoustic social behavior, largely because the production and perception of sound is essential to its reproductive success during a restricted time of year ( Bass and McKibben, 2003, Forlano and Bass, 2011 and Sisneros, 2009). This review highlights recent studies that demonstrate neuroendocrine coupling of seasonal reproduction with adaptive plasticity in audition and vocal communication using the midshipman model.

2. Midshipman life history and reproductive behavior
Midshipman fish belong to a single order and family (Batrachoidiformes, Batrachoididae) of teleost fish known commonly as toadfishes (Greenfield et al., 2008). Midshipman can be found along the western coast of the United States from as far north as Sitka, Alaska to Magdalena Bay, Mexico (Walker and Rosenblatt, 1988). Intensive neuroethological studies over the last 25 years have focused on populations that reside close to nine months of the year in deep waters off the coasts of northern California and Washington state and then migrate into the rocky intertidal zone to spawn in late May to mid-August (Fig. 1A–C). This seasonal migration is quite remarkable as it requires adaptations to extreme changes in water depth and habitat which includes transitioning from the deep water benthos (down to 300 m) to rocky subtidal/intertidal shoreline (e.g., Tomales Bay, Puget Sound) where fish are often found within rocky nest shelters without water for several hours during low tide (Bass, 1996, DeMartini, 1988 and McIver et al., 2014). Little is known about specific environmental (abiotic or biotic) cues that induce the migration to shallow waters for spawning, although light/dark cycle has recently been demonstrated to change neural excitability/responsiveness of the vocal system (see below; Feng and Bass, 2014 and Rubow and Bass, 2009) and is thus a likely cue. Interestingly, Foran et al. (1997) showed that gonadotropin-releasing hormone mRNA in neurons of the ventrolateral thalamic nucleus is modulated by retinal input, and these neurons, which project back to the retina may in turn modulate the visual system in response to seasonal changes in environmental light conditions. Other factors, such as seasonal changes in temperature, upwelling and food abundance may also provide salient cues for gonadal recrudescence (below) and migratory behavior.