Seasonal-like variation in song control system volume of wild zebra finches.

Zebra finches have been extensively used as a model system for studying the underlying neuroplasticity that allows for song learning during development. Zebra finches are considered age-limited or close-ended learners, in which fixed songs are learned within a certain window of time during development. In addition, they breed more or less continuously in laboratory conditions. As a consequence, less attention has been paid to potential neuroplasticity in adults. We present data on free-living zebra finches from two populations in Australia (one just beginning a period of breeding and another during a non-breeding period) that show a distinct difference in the volumes of two song system nuclei (HVC and Area X) depending on reproductive state. This is the first study to measure song system volumes in wild zebra finches, and suggests that the potential for neuroplasticity remains in adult zebra finches.

Physiological trade-offs in self-maintenance: plumage molt and stress physiology in birds.

Trade-offs between self-maintenance processes can affect life-history evolution. Integument replacement and the stress response both promote self-maintenance and affect survival in vertebrates. Relationships between the two processes have been studied most extensively in birds, where hormonal stress suppression is down regulated during molt in seasonal species, suggesting a resource-based trade-off between the two processes. The only species found to differ are the rock dove and Eurasian tree sparrow, at least one of which performs a very slow molt that may reduce resource demands during feather growth, permitting investment in the stress response. To test for the presence of a molt-stress response trade-off, we measured hormonal stress responsiveness during and outside molt in two additional species with extended molts, red crossbills (Loxia curvirostra) and zebra finches (Taeniopygia guttata). We found that both species maintain hormonal stress responsiveness during molt. Further, a comparative analysis of all available species revealed a strong relationship between molt duration and degree of hormonal suppression. Though our results support trade-off hypotheses, these data can also be explained by alternative hypotheses that have not been formally addressed in the literature. We found a strong relationship between stress suppression and seasonality of breeding and evidence suggesting that the degree of suppression may be either locally adaptable or plastic and responsive to local environmental conditions. We hypothesize that environmental unpredictability favors extended molt duration, which in turn allows for maintenance of the hormonal stress response, and discuss implications of a possible trade-off for the evolution of molt schedules.

Potential roles for GNIH and GNRH-II in reproductive axis regulation of an opportunistically breeding songbird.

The ability to breed at any time of year enables opportunistically breeding species to respond to good conditions whenever they occur. We investigate the neuroendocrine basis for this relatively unusual reproductive pattern in the avian world. One proposed mechanism for year-round breeding ability is tonic activation of gonadotropin-releasing hormone-I (GnRH-I) production that is flexibly modified by gonadotropin-inhibitory hormone (GnIH) production during unfavorable conditions. GnIH could inhibit GnRH secretion from the hypothalamus and/or inhibit GnRH action on the anterior pituitary gland. We studied neuroendocrine patterns in wild Australian zebra finches (Taeniopygia guttata) sampled during a breeding period in Southern Australia, a non-breeding period in central Australia, and in juvenile males in the latter location. We asked whether patterns in immunoreactivity of three neuropeptides important for reproductive axis regulation, GnRH-I, GnRH-II and GnIH, during periods of breeding and non-breeding reflect this flexibility. We found that the numbers and sizes of immunoreactive (-ir) GnRH-I cells did not vary between breeding stages and ages. Contrary to our predictions, irGnIH cell number and size, as well as the synthesis of GnIH mRNA were similar in breeding and non-breeding conditions. However, breeding males had more and larger irGnRH-II cells in the midbrain compared to non-breeding males. Hence, while changes in irGnIH cells are not associated with fluctuations in gonadotropin secretion or gonad volume, the regulation of irGnRH-II cells might represent a previously-unidentified mechanism by which reproductive flexibility can be achieved; namely via behavioral neurotransmitter actions of GnRH-II rather than through the typical sensory-CNS integration-GnRH-I route.