Jd. Safer et al., DEFECTIVE RELEASE OF COREPRESSOR BY HINGE MUTANTS OF THE THYROID-HORMONE RECEPTOR FOUND IN PATIENTS WITH RESISTANCE TO THYROID-HORMONE, The Journal of biological chemistry, 273(46), 1998, pp. 30175-30182
On positive thyroid hormone response elements (pTREs), thyroid hormone
receptor (TR) binding to DNA in the absence of ligand (thyroid hormon
e, T-3) decreases transcription (silencing). Silencing is due to a fam
ily of recently described nuclear corepressor proteins (NCoR and SMRT)
which bind to the CoR box in the hinge region of TR. Ligand-dependent
activation of TR is associated with displacement of corepressors and
recruitment of coactivating proteins. Resistance to thyroid hormone (R
TH) is due to mutations in the beta isoform of the thyroid hormone rec
eptor (TR-beta). To date, three RTH mutations reportedly with near-nor
mal T-3 binding (A234T, R243Q, and R243W) have been described in or ne
ar the CoR box. To determine the mechanism of RTH caused by these muta
nts, the interaction of wild type (wt) and mutant TRs with the corepre
ssor, NCoR, and the coactivator, SRC-1, was tested in gel-shift assays
. As expected, NCoR bound wt TR in the absence of T-3 and dissociated
from TR with increasing T-3 concentration. SRC-1 failed to bind wt TR
in the absence of T-3, but bound to TR with increasing avidity as T-3
concentrations rose. At no T-3 concentration did both NCoR and SRC-1 b
ind to wt TR, indicating that their binding to TR was mutually exclusi
ve. Hinge mutants bound NCoR normally in the absence of T-3; however,
dissociation of NCoR and recruitment of SRC-1 was markedly impaired ex
cept at very high T-3 concentrations. Importantly, hinge mutant TRs wh
en complexed to DNA bound T-3 poorly despite their near normal T-3 bin
ding in solution. These binding studies correlated with functional ass
ays showing defective transactivation of pTREs by hinge mutants except
at high T-3 concentrations. Thus, we describe a novel mechanism of RT
H whereby TR hinge mutants selectively affect T-3 binding when complex
ed to DNA, and prevent NCoR dissociation from TR. Our data also sugges
t that solution T-3 binding by RTH mutants may not accurately reflect
physiologically relevant T binding by TR when bound to DNA.