Negative and positive transcriptional regulation by thyroid hormone receptor isoforms.

Multiple forms of human thyroid hormone (T3) receptor have been identified, including true receptors that bind T3 (alpha 1 and beta) and a splicing variant (alpha 2) that does not bind T3. The alpha 1- and beta-receptors activate transcription through interactions with positive thyroid response elements (TREs). The alpha 2 variant is unable to activate transcription and has been reported to inhibit alpha 1 or beta stimulation of positive TREs, a property referred to as dominant negative activity. In this report we have performed studies to assess the functional properties of different members of the thyroid receptor family with regard to both positive and negative transcriptional regulation. The alpha 1-, alpha 2-, and beta-receptors were each coexpressed in JEG-3 cells with either TreTKCAT (CAT = chloramphenicol acetyltransferase), a reporter gene that contains a positive TRE, or TSH alpha CAT, a negatively regulated reporter gene. The alpha 1 and beta isoforms stimulated transcription of TreTKCAT and inhibited TSH alpha CAT transcription in a T3-dependent manner, whereas the alpha 2 variant was inactive. When coexpressed with alpha 1- or beta-receptors, alpha 2 inhibited regulation of positive TREs, but the effects of alpha 2 were modest and only occurred when relatively high doses of receptor were transfected. The alpha 2-receptor variant did not affect negative regulation by alpha 1- or beta-receptors. Thus, in both positive and negative regulation, thyroid hormone receptor isoforms that bind T3 (alpha 1, beta) are functional, whereas the alpha 2 isoform, which does not bind T3, is not functional.(ABSTRACT TRUNCATED AT 250 WORDS)

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