Thyroid hormone receptors (TRs) are nuclear proteins that regulate gene expression through interactions with specific DNA sequences. It is well known that thyroid hormones have critical functions in the control of normal brain development. In the rat brain, at least three mRNA species are generated by differential processing of the TR alpha transcript. Only one of the isoforms, TR alpha-1, is a transcriptional activator, while the regulatory roles of the carboxy-terminal variants TR alpha-2 and TR alpha-2v remain unclear. In this study we have used polymerase chain reaction amplification of total RNA to compare TR alpha-1, TR alpha-2, and TR alpha-2v mRNA levels in the brainstem, cerebellum, cerebrum, midbrain, and olfactory bulbs of developing neonatal brains in rats. RNA was collected 5, 10, 15, 20, and 25 days after birth from both normal and hypothyroid animals. Coordinate expression of all three isoforms was observed in most tissues during development, with TR alpha-2 generally maintaining the highest level of expression, and TR alpha-1 the lowest. In hypothyroid tissues, TR alpha-1 message was generally increased, while TR alpha-2 was not. To explore the possible roles of the TR alpha isoforms, we have compared their DNA-binding activities. We report that compared to TR alpha-1, the carboxy-terminal variants TR alpha-2 and TR alpha-2v show different binding patterns with a thyroid hormone response element, suggesting that they bind only poorly as monomers. The varying ratios of the TR alpha isoform expression together with their distinct binding patterns and reported repressor functions suggest that TR alpha isoforms have important roles during brain development and function, and may serve to fine-tune the biological responses to thyroid hormone.