Single thyroid hormone receptor monomers are competent for co-activator-mediated transactivation.

Thyroid hormone receptor (T(3)R) belongs to the superfamily of nuclear receptors containing highly related transcription factors that transform an incoming signal in the form of a lipophilic hormone into an activation of the basal transcriptional machinery. Like many other nuclear receptors, T(3)R acts preferentially as a heterodimer with retinoid X receptor (RXR) but it also has the unique property of binding as a monomer to DNA. This study demonstrates that T(3)R monomers bind preferentially to AGGTCA binding motifs and are able to co-exist with T(3)R-RXR heterodimers in the presence of limiting amounts of RXR. DNA-bound T(3)R monomers efficiently contact all three members of the p160 co-activator family, which in turn boost T(3)R monomer-mediated transactivation. In solution T(3)R monomers take only one agonistic conformation (c2(LPD)), whereas bound to DNA they also stabilize, like T(3)R-RXR heterodimers, a second agonistic conformation (c1(LPD)). Conformation c2(LPD) seems to be of lower ligand sensitivity (10 nM), whereas, both in T(3)R-RXR heterodimers and in DNA-bound T(3)R monomers, c1(LPD) is already activated at a ligand concentration of 1 nM. Taken together, these results suggest that single T(3)R monomers are fully competent for ligand-induced transactivation and that their role in gene regulation by thyroid hormone might have been underestimated.