Photoaffinity labelling of the rat liver nuclear thyroid hormone receptor with [125I]triiodothyronine.

[125I]Triiodothyronine (T3) was used as a photoreactive probe for the thyroid hormone nuclear receptor in photoaffinity labelling experiments. Autoradiograms of photolysis products electrophoresed on either one or two-dimensional gels showed that [125I]T3 covalently, but nonspecifically, labelled many proteins in the partially purified receptor preparations used. However, one of these proteins with an estimated molecular weight of 47,000 and an isoelectric point of approximately 6.2 +/- 0.5 pH units appears to be the thyroid hormone receptor, since, in contrast to the other proteins, its photoinduced labelling was blocked by concentrations of T3 and thyroxine (T4) similar to those that inhibit binding of [125I]T3 by the receptor in equilibrium binding assays. In addition, the isoelectric point of the photolabelled protein agrees with that determined in separate equilibrium isoelectric focusing studies. These results indicate that [125I]T3 can serve as a photoreactive probe for the thyroid hormone nuclear receptor, and they suggest that this receptor is a single polypeptide chain of molecular weight 47,000 with an isoelectric point of 6.2 +/- 0.5 pH units.

Processing of the primary transcript for the rat growth hormone gene in vivo.

Processing of the rat growth hormone (rGH) gene primary transcript and the effects of thyroid and glucocorticoid hormones on rGH pre-mRNA levels have been studied using subcloned radiolabeled DNA fragments from each of the four introns of this gene as probes. Blot-hybridization analysis of poly(A)+RNA from GC cells, GH3 cells, and normal pituitary gland indicates that processing of intron sequences from the precursor transcript takes place in a qualitatively similar fashion in each of these cell types. The data indicate that, in general, those introns closest to the termini of the primary transcript are removed first followed by removal of the internal introns. The suggested order of removal is IA, ID, IC, and IB. This process is unaffected qualitatively by thyroid or glucocorticoid hormones, both of which increase the rate of transcription of the gene. In addition to the primary transcript and the partially processed intermediate transcripts, GC and GH3 cells were found to contain a heterogenous group of intron-containing polyadenylated rGH gene transcripts which cannot be accounted for by any combination of intron deletions. These transcripts could arise either from internal start sites in the gene, premature termination of transcription, or inefficient processing of rGH mRNA precursors in the transformed cells. Thyroid hormone rapidly increases the levels of intron C-containing transcripts with kinetics that parallel the binding of thyroid hormone receptor to nuclei, but does not alter the ratio of primary to partially processed transcripts. These data suggest that most of the stimulatory activity of this hormone is due to effects on rGH gene transcription and not on pre-mRNA processing.(ABSTRACT TRUNCATED AT 250 WORDS)

Interactions of the nuclear thyroid hormone receptor with core histones.

These studies concern the interactions of the rat liver thyroid hormone nuclear receptor with histones and factors influencing the receptor's assay and stability. Heating certain crude receptor preparations at 50 degrees C produces a selective loss of triiodothyronine (T3) but not thyroxine (T4) binding activity, whereas, with more purified preparations, such heating decreases both T3 and T4 binding. The selective T3-binding loss in crude preparations was found to be due to the simultaneous denaturation of the receptor's high-affinity hormone-binding activity for both T3 and T4 and generation of new low-affinity T4-binding sites. The fraction in which T4 binding can be activated could be separated from the receptors by Sephadex G-100 chromatography. Core histones stimulated both T3- and T4-binding activity of 6-fold-purified receptor preparations, and data from several different experimental approaches suggest that this stimulation is due to the capability of the core histones to prevent the receptor from binding to or being denatured by Sephadex G-25 assay columns. The core histones were also found to stabilize 500-fold-purified but not 6-fold-purified or crude receptor preparations. A number of other acidic or basic proteins had little or none of these stimulatory effects, whereas a few proteins (such as the insulin B chain and histone H1) did have activity, although it was less than that of the core histones. There were no significant differences between the purified core histone subfractions (H2A, H2B, H3, and H4). That core histones can interact with the thyroid hormone receptors was demonstrated more directly by the finding that the receptors bind to histone-Sepharose but not Sepharose or insulin- or ovalbumin-Sepharose columns and that this binding was blocked by core histones at concentrations suggestive of an affinity for the receptor-core histone interaction of around 3 microM at 0.15 M salt concentration. The results demonstrate the utility of the histones in the assay and stabilization of purified thyroid hormone receptors, but they fail to support our previous hypothesis of a receptor subunit where T3- but not T4-binding activity is regulated selectively by histones. However, the results indicate that histones may interact with the receptors with some degree of specificity, and they raise the possibility that the histones participate in the nuclear localization of the receptors.