A nuclear factor that enhances binding of thyroid hormone receptors to thyroid hormone response elements

Recent studies from this laboratory have demonstrated the presence of thyroid hormone response elements (TREs) in the 5'-flanking region of the rat alpha and TSH beta subunit genes. Using an avidin-biotin complex DNA binding assay, we have shown that these TREs bind the thyroid hormone (T3) receptor present in nuclear extracts of GH3 cells, as well as the in vitro synthesized Hc-erbA beta, which has been identified as a member of the family of T3 receptors. The binding of Hc-erbA beta to the alpha subunit TRE can be enhanced 3-4-fold by including GH3 nuclear extract in the binding assay. Binding to the TRE present in the TSH beta gene or the rat growth hormone gene was similarly enhanced, although to a lesser degree. The enhanced binding activity is trypsin-sensitive and heat labile, and is not reproduced by the addition of histones, bovine serum albumin, or cytosol instead of nuclear extract. Gel exclusion chromatography suggests a molecular size of approximately 65,000 Da. This protein, which is present in several different cell types, is also able to complement binding of the rat erbA alpha-1 and the pituitary-specific erbA beta-2 forms of the receptor. These data suggest that the binding of the T3 receptor to a TRE is augmented by another nuclear protein, which may be involved in the mechanism of action of thyroid hormone.     

Effects of varying the position of thyroid hormone response elements within the rat growth hormone promoter: implications for positive and negative regulation by 3,5,3'-triiodothyronine

The thyroid hormone response element (T3RE) of the rat GH (rGH) promoter is located at -188 to -165 relative to the mRNA start site (TSS). Similar sites have been identified in other genes regulated by T3. We have investigated some of these T3REs in positions within the rGH promoter to assess the relative influences of DNA-binding site and position on positive and negative regulation by T3. Synthetic oligonucleotides were used with sequences from the rGH T3RE and proposed negative T3REs (nT3RE) from the rat and human alpha-subunit and rat beta TSH genes. The nT3REs were placed in the background of the wild-type rGH promoter in two positions, at -55 and down-stream of the TSS, with up- and down-mutations of the rGH T3RE. Rat GH T3RE elements were placed 700 basepairs up-stream of a basal rGH promoter and some also at the -55 and TSS positions. Constructions were tested in a transient transfection assay in rat pituitary tumor cells. Two copies of the rGHPAL (palindromic T3RE) placed 700 basepairs up-stream of the rGH promoter conferred 10-fold T3 induction. In the -55 position, the rGHPAL increased T3 induction compared to that in controls, whereas a fragment from the rat and human alpha-subunit gene in the same position reduced induction. Negative T3REs from rat beta TSH and human alpha-subunit reduced T3 induction 50% when placed at the TSS position of a rGH promoter containing an up-mutant T3RE. The T3REPAL placed at the same site increased T3 induction.(ABSTRACT TRUNCATED AT 250 WORDS)     

3,5,3'-triiodothyronine receptor auxiliary protein (TRAP) enhances receptor binding by interactions within the thyroid hormone response element.

We have previously demonstrated that binding of in vitro synthesized thyroid hormone receptor (TR) to thyroid hormone response elements (TREs) is enhanced by the addition of nuclear extracts from several different cell types, suggesting that binding of TR is partially dependent on a T3 receptor auxiliary protein (TRAP). We have used the avidin-biotin complex DNA-binding assay to discriminate between regions of TREs that bind TR alone and sites that are influenced by interactions with TRAP. Mutations in the TREs from rat GH and glycoprotein hormone alpha-subunit genes show that a specific DNA sequence is required for TRAP-mediated enhancement of TR binding. Mutations in the B half-site of the rat GH TRE or in similar sequences [(T/A)GGGA] in the alpha-subunit TRE ablate the enhancement of TR binding by TRAP. Furthermore, binding of TR to a natural half-site in the TSH beta-subunit gene (bases -16 to 6), which lacks an additional AGGGA-like sequence, is not enhanced by the addition of TRAP. Binding of TR to TREs was also tested at physiological salt concentrations in the avidin-biotin complex DNA-binding assay. Binding of human TR beta to TREs decreases dramatically at 140 mM KCl compared to binding at 50 mM KCl; however, the addition of TRAP enhances the binding to almost 4-fold of basal binding, suggesting that TRAP may be important for stabilization of TR binding to TREs in the cell.     

Functional characterization of the rat growth hormone promoter elements required for induction by thyroid hormone with and without a co-transfected beta type thyroid hormone receptor

We have extensively characterized the sequences of the rat growth hormone (rGH) promoter required for induction by T3 (thyroid hormone, 3,5,3'-L-triiodothyronine) in a transient transfection system. Oligonucleotides containing portions of the rGH promoter sequence with various deletions and point mutations were placed upstream of the first 137 base pairs of the rGH promoter or the heterologous herpes virus thymidine kinase promoter in chloramphenicol acetyltransferase expression vectors. The rGH137 and thymidine kinase promoters show no or minimal response to T3 in the basal state. The constructs were tested in GH4C1 rat pituitary cells and COS cells (functionally deficient in thyroid hormone receptor) with and without a co-transfected plasmid expressing a beta type c-erbA gene coding for a functional T3 receptor. Oligonucleotides containing the T3 receptor binding site confer hormone-dependent induction in a manner that is independent of either orientation or variation in position on the helix relative to the promoter. Point mutations in the sequence -189 to -173 result in loss of T3 induction, and bases between -173 and -167 were also required for a full T3 response. The minimal length to confer T3 induction to the rGH promoter was 23 base pairs (-190 to -167). Point mutations creating a perfect duplication of 7 base pairs within the receptor binding site conferred 12-fold T3 response to the rGH137 promoter, 3-fold greater than the wild type rGH237 construct. T3 inductibility was also transferred to the thymidine kinase promoter by an oligonucleotide containing the sequence -200 to -157, demonstrating that cell type specific elements located 3' to 157 of the rGH promoter are not required for thyroid hormone responsiveness.     

Sequences required for cell-type specific thyroid hormone regulation of rat growth hormone promoter activity

We have located sequences within the rat growth hormone (rGH) promoter region which are required for pituitary cell-type specific responsiveness to T3 (thyroid hormone, 3,5,3'-L-triiodothyronine). Transient transfections with a series of plasmids containing as few as 202 nucleotides upstream of the start site of the rat growth hormone mRNA showed specific induction by T3 in rat pituitary cell lines. Both the magnitude and the kinetics of this response were similar to those of the endogenous rGH gene, showing a strong early induction followed by a decline in T3 effect. Deletion of an additional 19 base pairs (to -183 relative to the start site) eliminated this induction. Plasmids containing sequences up to -237 or -202 showed significant promoter activity but no T3 responsiveness in transfections of mouse fibroblasts or monkey kidney cells. The presence of high affinity nuclear T3 binding proteins was demonstrated in both cell types. These results show that sequences between -183 and -202 are required for pituitary cell specific T3 regulation of the rGH promoter. The lack of T3 responsiveness in non-pituitary cells suggests that such regulation may be mediated by factors present in pituitary cells and absent in other cells.     

Identification of nuclear factors that enhance binding of the thyroid hormone receptor to a thyroid hormone response element

Using a gel shift assay, we analyzed the binding of in vitro translated alpha- and beta-thyroid hormone (T3) receptors to a T3-response element (TRE) derived from the rat GH gene. No receptor-TRE complexes were observed when translated receptor alone was incubated with the TRE. However, addition of a nuclear extract from liver to the translational products resulted in the formation of two receptor-DNA complexes for both the alpha- and beta-receptors. These complexes were shown to contain translated receptor by comigration of 32P-labeled TRE and 35S-labeled receptor in the gel shift assay. A competition experiment demonstrated that formation of the complexes was sequence specific. Preincubation of the liver nuclear extract at 60 C abolished formation of both complexes indicating that receptor-TRE binding required a heat-labile nuclear factor. Phosphocellulose chromatography of the nuclear extract resulted in separation of the activities required for formation of the two complexes. Analysis of nuclear extracts from different tissues revealed that one complex formed in the presence of all extracts, whereas the second complex appeared predominantly with a nuclear extract from liver. Addition of T3 to the binding reaction had no effect on receptor-TRE complex formation. We suggest that nuclear factors interact with the T3 receptor to enhance hormone-independent binding to a TRE.