Thyroid hormone induces differentiation of many different tissues in mammals, birds, and amphibians. The different tissues all differentiate from proliferating precursor cells, and the normal cell cycle is suspended while cells undergo differentiation. We have investigated how thyroid hormone affects the expression of the E2F-1 protein, a key transcription factor that controls G1- to S-phase transition. We show that during thyroid hormone-induced differentiation of embryonic carcinoma cells and of oligodendrocyte precursor cells, the levels of E2F-1 mRNA and E2F-1 protein decrease. This is caused by the thyroid hormone receptor (TR) regulating the transcription of the E2F-1 gene. The TR binds directly to a negative thyroid hormone response element, called the Z-element, in the E2F-1 promoter. When bound, the TR activates transcription in the absence of ligand but represses transcription in the presence of ligand. In addition, liganded TR represses transcription of the S-phase-specific DNA polymerase alpha, thymidine kinase, and dihydropholate reductase genes. These results suggest that thyroid hormone-induced withdrawal from the cell cycle takes place through the repression of S-phase genes. We suggest that this is an initial and crucial step in thyroid hormone-induced differentiation of precursor cells.
Previous studies have shown that thyroid hormone receptors can form homo- and heterodimeric complexes when binding to response elements. We report here the binding characteristics of thyroid hormone receptor (TR) homo- and heterodimers binding to synthetic oligonucleotides with directly and palindromically repeated consensus motifs (AGGTCA). Binding assays showed that TR homodimer formation on DNA had a low specificity and cooperativity, and very fast off rates. In contrast, TRs and retinoic acid receptors readily formed heterodimers with higher specificity and affinity on direct repeats of the AGGTCA motif spaced by four or five nucleotides, although these heterodimer/DNA complexes were only moderately stable when compared to DNA-bound TR/retinoid X receptor heterodimers. Also, TR/retinoic acid receptor heteromeric binding to other elements, including the synthetic T3RE-pal element, was of low specificity. These biochemical results suggest that TRs are unlikely to regulate transcription as homodimers in vivo, and that TR heterodimers mediate the effects of thyroid hormone.
Previous studies have shown that thyroid hormone receptors can form homo- and heterodimeric complexes when binding to response elements. We report here the binding characteristics of thyroid hormone receptor (TR) homo- and heterodimers binding to synthetic oligonucleotides with directly and palindromically repeated consensus motifs (AGGTCA). Binding assays showed that TR homodimer formation on DNA had a low specificity and cooperativity, and very fast off rates. In contrast, TRs and retinoic acid receptors readily formed heterodimers with higher specificity and affinity on direct repeats of the AGGTCA motif spaced by four or five nucleotides, although these heterodimer/DNA complexes were only moderately stable when compared to DNA-bound TR/retinoid X receptor heterodimers. Also, TR/retinoic acid receptor heteromeric binding to other elements, including the synthetic T3RE-pal element, was of low specificity. These biochemical results suggest that TRs are unlikely to regulate transcription as homodimers in vivo, and that TR heterodimers mediate the effects of thyroid hormone.
The thyroid hormone receptor (TR) regulates the transcription of its target genes by interacting with specific hormone response elements consisting usually of directly repeated half-sites with the consensus sequence AGGTCA. To investigate the role of the spacer sequences separating the half-sites, heterodimers formed by TRalpha and the retinoid-X receptor (RXR) were used in a PCR based selection and amplification assay. The TRalpha/RXR heterodimer selected for elements with directly repeated half-sites having a spacer of 4 nucleotides (DR4). Preferences for nucleotides in the TR binding half-site motif as well as for the 4 nucleotides separating the two half-sites were found. DNA binding and transfection studies using DR4 elements with different spacer sequences showed the importance of these nucleotides for the activity of the response element: some spacer sequences allowed little or no transactivation from the element, whereas other sequences supported strong transactivation. A pyrimidine nucleotide in position three of the spacer enhanced TRalpha binding and transactivation. Additional experiments showed that heterodimers between RXR and other putative receptors exhibited a similar but distinct specificity for the spacer sequence. Our results thus suggest that the four nucleotides separating the two half-sites in hormone response elements have a major role in determining induction of hormone responsive genes.
The thyroid hormone receptors interact with several different cofactors when activating transciption. In this study, we show that the adenovirus E1A oncoprotein functions as a strong coactivator for the thyroid hormone receptor (TR), and that TR and E1A synergistically activate transcription via direct (DR4) or palindromic (IRO) hormone-responsive sites. Cotransfection experiments using different isoforms of the chicken TR and E1A show synergistic, ligand-enhanced transactivation. This transactivation is accomplished through a direct, ligand-independent interaction between TR and E1A. The interaction domains in TR are localized to the DNA-binding domain and to the carboxy-terminal part of the ligand-binding domain. In E1A, the regions of interactions are localized to the conserved regions 1 and 3. Both of these domains in E1A are required for a 40-fold enhancement of TR-mediated activation in transfection experiments. Taken together, we show that E1A strongly enhances transcriptional activation, which suggests that it serves as a bridging factor between the receptor and other components of the transcription machinery.
The thyroid hormone receptors interact with several different cofactors when activating transciption. In this study, we show that the adenovirus E1A oncoprotein functions as a strong coactivator for the thyroid hormone receptor (TR), and that TR and E1A synergistically activate transcription via direct (DR4) or palindromic (IRO) hormone-responsive sites. Cotransfection experiments using different isoforms of the chicken TR and E1A show synergistic, ligand-enhanced transactivation. This transactivation is accomplished through a direct, ligand-independent interaction between TR and E1A. The interaction domains in TR are localized to the DNA-binding domain and to the carboxy-terminal part of the ligand-binding domain. In E1A, the regions of interactions are localized to the conserved regions 1 and 3. Both of these domains in E1A are required for a 40-fold enhancement of TR-mediated activation in transfection experiments. Taken together, we show that E1A strongly enhances transcriptional activation, which suggests that it serves as a bridging factor between the receptor and other components of the transcription machinery.
The oncogenic counterpart of thyroid hormone receptor-alpha (TRRalpha), denoted P75gag-v-erbA, has served as a paradigm for the ability of TRs to repress basal levels of transcription. We show here that the retinoid X receptor (RXR), when activated by its specific ligand SR11237, is repressed by both the normal TRalpha and the P75gag-v-erbA. The repression caused by the two proteins is distinct and dependent on both the cell type and the hormone-response element through which RXR acts. In HeLa cells only TR repressed efficiently through the palindromic 2xIR0 element, whereas the proteins were equally efficient in JEG cells. This demonstrates that proteins distinct in the two cell types mediate the repression. RXR-dependent induction via the natural response element of the cellular retinol-binding protein (CRBPII) gene was likewise (> or = 50%) repressed by TR, whereas P75gag-v-erbA did not repress during the same conditions. Furthermore, P75gag-v-erbA and its variants v-erbAtd359 (lacking repressing activity on TR) and v-erbAr12 (a highly active repressor of TR) efficiently repressed induction by a hybrid protein consisting of the DNA- binding domain of Gal4 and the ligand-binding region of RXR. The viral proteins did not, however, associate with RXR unless the two partners were allowed to heterodimerize upon binding to a specific response element, such as the 2xIR0 element or that of the CRBPII gene. In conclusion, we suggest that the efficient repression seen with the the 2xIR0 element is due to heterodimerization of TR or the viral oncoproteins with RXR and a concomitant inhibition of binding of the RXR-specific ligand that results in an inability of RXR to attract a cell type-specific cofactor. In addition, the data suggest that the interaction between RXR and P75gag-v-erbA on the CRBPII element is too weak to inhibit RXR from binding a ligand and therefore also to repress.
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