Faculty Bibliography

Thyroid hormone receptors are cellular homologues (c-erbAs) of the v-erbA oncoprotein of the avian erythroblastosis virus. Exclusive of the viral gag region, v-erbA differs from the chick c-erbA-alpha receptor by two amino acid changes N-terminal of the DNA binding domain, two amino acid changes in the DNA binding domain, nine amino acid changes in the C-terminal region corresponding to the ligand binding domain of c-erbA, and a nine-amino acid deletion near the C terminus. v-erbA does not bind thyroid hormone and when expressed in cells inhibits the activity of wild-type thyroid hormone receptors. We reported previously that mutants of chick c-erbA/thyroid hormone receptor which lack the DNA binding domain (DBD-) inhibit transcriptional activition by wild-type thyroid hormone and retinoic acid receptors (Forman, B. M., Yang, C.-R., Au, M., Casanova, J., Ghysdael, J., and Samuels, H. H. (1989) Mol. Endocrinol. 3, 1610-1626). This dominant negative activity mapped to a series of hydrophobic heptad motifs which are conserved in the C terminus of these receptors and have been suggested to play a role in receptor dimerization. In this study we show that unlike DBD- c-erbA, DBD- v-erbA does not block receptor activity, suggesting that v-erbA acts by competing for DNA response elements rather than by formation of nonfunctional v-erbA/c-erbA heterodimers. This difference in activity was localized to a single Pro to Ser change in v-erbA just N-terminal of the last heptad motif. Introduction of this Pro to Ser change into DBD- c-erbA resulted in a protein which was inactive both functionally and in blocking receptor dimer formation in vitro

A 1466 base pair cDNA for rabbit prothrombin has been isolated and partially sequenced. The deduced amino acid sequence shows considerable homology with the sequences of human and bovine prothrombin. The cDNA extends from the equivalent of nucleotide 516 in the bovine sequence through the coding region and 99 nucleotides in the 3' non-coding region

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)

Several hormones, including insulin, glucagon, and glucocorticoids, regulate the expression of the rate-limiting gluconeogenic enzyme, phosphoenolpyruvate carboxykinase [GTP: oxaloacetate carboxy-lyase (transphosphorylating); EC 4.1.1.32; PEPCK] in liver. In this report we demonstrate that retinoic acid (RA) also regulates PEPCK expression by inducing a 3-fold increase in the rate of transcription of the PEPCK gene. A RA response element located between -468 and -431 in the PEPCK promoter mediates a 7-fold increase in expression of a chimeric construct containing the basal PEPCK promoter ligated to the chloramphenicol acetyltransferase reporter gene. This element confers RA responsiveness through the heterologous thymidine kinase promoter and functions relatively independent of position and orientation. An 18-base-pair core sequence (-451 to -434) (i) mediates an effect of RA on PEPCK gene expression and contains motifs found in two other RA response elements; (ii) corresponds to AF1, an accessory factor element that is an integral component of the complex glucocorticoid response unit in the PEPCK gene promoter; (iii) is in a region involved in the developmental expression of the PEPCK gene; and (iv) shows homology to elements involved in the tissue-specific regulation of genes, including the hepatic apolipoprotein genes and the alpha 1-antitrypsin gene

We present evidence that T3 can alter the ADP-ribosylation of chromatin associated proteins. Nuclei from GH1 cells were incubated with [adenylate-32P]NAD and the radioactivity incorporated into histone and non-histone proteins was quantitated and analyzed by gel electrophoresis and autoradiography. Incubation of GH1 cells for 24 h with T3 lowered by 40-70% the [32P]ADP-ribose incorporated into nuclear proteins. However, incubation for 3 h with T3 resulted in a stimulation instead of a decrease of in vitro [32P]ADP-ribose incorporation. The major ADP-ribosylated component electrophoresed as a 120,000 molecular mass non-histone protein, and radiolabeled histones were also observed. The same protein species were observed for all the experimental groups and T3 affected the extent of ADP-ribosylation but did not alter the sedimentation of the [32P]ADP-ribosylated components excised from chromatin after micrococcal nuclease digestion

In the epidermis, retinoids regulate the expression of keratins, the intermediate filament proteins of epithelial cells. We have cloned the 5' regulatory regions of four human epidermal keratin genes, K#5, K#6, K#10, and K#14, and engineered constructs in which these regions drive the expression of the CAT reporter gene. By co-transfecting the constructs into epithelial cells along with the vectors expressing nuclear receptors for retinoic acid (RA) and thyroid hormone, we have demonstrated that the receptors can suppress the promoters of keratin genes. The suppression is ligand dependent; it is evident both in established cell lines and in primary cultures of epithelial cells. The three RA receptors have similar effects on keratin gene transcription. Our data indicate that the nuclear receptors for RA and thyroid hormone regulate keratin synthesis by binding to negative recognition elements in the upstream DNA sequences of the keratin genes. RA thus has a twofold effect on epidermal keratin expression: qualitatively, it regulates the regulators that effect the switch from basal cell-specific keratins to differentiation-specific ones; and quantitatively, it determines the level of keratin synthesis within the cell by direct interaction of its receptors with the keratin gene promoters

The nuclear hormone receptors comprise a superfamily of ligand-modulated transcription factors that regulate homeostasis, reproduction, development, and differentiation. Three amino acids within the zinc finger DNA binding motif determine target gene specificity. Groups of receptors exist with similar DNA binding specificity. A complex carboxy terminal region mediates ligand binding, dimerization, and hormone-relieved transcriptional inactivation. We summarize the current understanding of these phenomena and suggest a novel model that structurally and functionally links these events. This 'regulatory zipper model' may explain the mechanism by which ligand activates nuclear hormone receptors

Studies were conducted to determine whether the trans-acting protein Pit-1/GHF-1 can bind to and activate promoter elements in both the GH and PRL genes that are necessary for cell-specific expression. Four pituitary cell lines that differentially express the endogenous GH and PRL genes were examined for their ability to activate GH and PRL promoter constructs containing sequences necessary for cell-specific expression (CSEs). Plasmids containing one CSE, -96 PRL and -104 GH, were similarly expressed in each of the four cell lines. Of the plasmids containing two CSEs, -173 PRL was always activated to a greater extent than -145 GH, with this relative activation being stronger in GC and GH1 cells than in 235-1 and GH4C1 cells. Protein-DNA binding assays were used to show that the GH and PRL CSEs specifically bound two highly abundant nuclear proteins (31 and 33 kDa). The two proteins were present at similar levels in all four pituitary cell lines and were recognized by a Pit-1/GHF-1 antibody. In contrast, HeLa and Rat2 cells did not activate transfected GH or PRL plasmids and did not contain nuclear proteins that specifically bound to the GH and PRL CSEs. However, cotransfection of these cells with the expression vector RSV-Pit-1/GHF-1 resulted in the activation of -173 PRL and -145 GH (PRL greater than GH). HeLa cells transfected with RSV-Pit-1/GHF-1 also contained 31- and 33-kDa nuclear proteins that bound to the GH and PRL CSEs. These results show that Pit-1/GHF-1 is present at levels in pituitary cell lines that are sufficient to activate the minimal elements in both the GH and PRL promoters necessary for cell-specific expression of these genes

The nuclear hormone receptors comprise a superfamily of ligand-modulated transcription factors that regulate homeostasis, reproduction, development, and differentiation. The DNA-binding domain of the nuclear hormone receptors contains two zinc finger motifs and binds to response elements composed of two-half-sites separated by a variably sized gap. DNA binding specificity is accomplished by a combination of mechanisms. First, discrimination among half-site sequences is mediated by three amino acids within the first zinc finger. Second, response elements with different half-site spacing can be discriminated by five amino acids in the second zinc finger, which may act as a dimerization interface. A second dimerization signal is embedded within the ligand-binding domain of several receptors. Ligand binds to sequences adjacent to this region and enhances dimerization. It is possible that dimerization of these receptors could account for certain physiologic and pathologic conditions observed in vivo