Molecular mechanisms of crosstalk between thyroid hormones and estrogens

Purpose of review Novel analyses of the relations between thyroid hormone receptor signaling and estrogen receptor—dependent mechanisms are timely for two sets of reasons. Clinically, both affect mood and foster neuronal growth and regeneration. Mechanistically, they overlap at the levels of DNA recognition elements, coactivators, and signal transduction systems. Crosstalk between thyroid hormone receptors and estrogen receptors is possibly important to integrate external signals to transcription within neurons. Recent findings It has been shown that reproductive functions, including behaviors, driven by estrogens can be antagonized by thyroid hormones, and it has been argued that such crosstalk is biologically adaptive to ensure optimal reproduction. Transcriptional facilitation during transient transfunction studies show that the interactions between thyroid receptor isoforms and estrogen receptor isoforms depend on cell type and promoter context. Overall, this pattern of interactions assures multiple and flexible means of transcriptional regulation. Surprisingly, in some brain areas, thyroid hormone actions can synergize with estrogenic effects, particularly when nongenomic modes of action are considered, such as kinase activation, which, as has been reported, affect later estrogen receptor—induced genomic events. Summary In summary, recent work with nerve cells has contributed to a paradigm shift in how the molecular and behavioral effects of hormones which act through nuclear receptors are viewed.

Thyroid hormones regulate anxiety in the male mouse

Thyroid hormone levels are implicated in mood disorders in the adult human but the mechanisms remain unclear partly because, in rodent models, more attention has been paid to the consequences of perinatal hypo and hyperthyroidism. Thyroid hormones act via the thyroid hormone receptor (TR) alpha and beta isoforms, both of which are expressed in the limbic system. TR's modulate gene expression via both unliganded and liganded actions. Though the thyroid hormone receptor (TR) knockouts and a transgenic TRalpha1 knock-in mouse have provided us valuable insight into behavioral phenotypes such as anxiety and depression, it is not clear if this is because of the loss of unliganded actions or liganded actions of the receptor or due to locomotor deficits. We used a hypothyroid mouse model and supplementation with tri-iodothyronine (T3) or thyroxine (T4) to investigate the consequences of dysthyroid hormone levels on behaviors that denote anxiety. Our data from the open field and the light-dark transition tests suggest that adult onset hypothyroidism in male mice produces a mild anxiogenic effect that is possibly due to unliganded receptor actions. T3 or T4 supplementation reverses this phenotype and euthyroid animals show anxiety that is intermediate between the hypothyroid and thyroid hormone supplemented groups. In addition, T3 but not T4 supplemented animals have lower spine density in the CA1 region of the hippocampus and in the central amygdala suggesting that T3-mediated rescue of the hypothyroid state might be due to lower neuronal excitability in the limbic circuit.

Activation of G-protein-coupled receptor 30 is sufficient to enhance spatial recognition memory in ovariectomized rats

In ovariectomized rats, administration of estradiol, or selective estrogen receptor agonists that activate either the alpha or beta isoforms, have been shown to enhance spatial cognition on a variety of learning and memory tasks, including those that capitalize on the preference of rats to seek out novelty. Although the effects of the putative estrogen G-protein-coupled receptor 30 (GPR30) on hippocampus-based tasks have been reported using food-motivated tasks, the effects of activation of GPR30 receptors on tasks that depend on the preference of rats to seek out spatial novelty remain to be determined. Therefore, the aim of the current study was to determine if short-term treatment of ovariectomized rats with G-1, an agonist for GPR30, would mimic the effects on spatial recognition memory observed following short-term estradiol treatment. In Experiment 1, ovariectomized rats treated with a low dose (1mug) of estradiol 48h and 24h prior to the information trial of a Y-maze task exhibited a preference for the arm associated with the novel environment on the retention trial conducted 48h later. In Experiment 2, treatment of ovariectomized rats with G-1 (25mug) 48h and 24h prior to the information trial of a Y-maze task resulted in a greater preference for the arm associated with the novel environment on the retention trial. Collectively, the results indicated that short-term treatment of ovariectomized rats with a GPR30 agonist was sufficient to enhance spatial recognition memory, an effect that also occurred following short-term treatment with a low dose of estradiol.