A c-erb-A binding site in rat growth hormone gene mediates trans-activation by thyroid hormone

Analysis of the human type I insulin-like growth factor receptor promoter region

We isolated genomic fragments containing the 5' region of the human type I insulin-like growth factor receptor gene. A unique transcription start site was identified, defining a 1038 bp 5'-untranslated region. No TATA or CCAAT elements were identified in the proximal 480 nucleotides of 5'-flanking region. The region surrounding the transcription start site was similar to a recently described "initiator" sequence. The 5'-flanking and 5'-untranslated regions were highly GC-rich, with numerous potential Sp1 binding sites. A potential AP-2 binding site was identified in the 5'-flanking region and a potential thyroid response element was identified in the 5'-untranslated region. The 5' region of the human gene was very similar to that of the rat gene, with conservation of many of the potential regulatory elements.

Transfection of avian vitamin D-dependent calbindin-D28K 5' flanking promoter sequence in primary chick kidney cells

Expression of the vitamin D induced calbindin-D28K protein is transcriptionally controlled by the steroid hormone 1,25-dihydroxyvitamin D3 (1,25(OH)2D3) in a tissue-specific manner in the intestine and kidney. In order to examine the cis-acting elements of the calbindin-D28K promoter and its modulation by 1,25-dihydroxyvitamin D3, chimeric plasmids containing 2.1 kb of 5' flanking region linked to the reporter gene chloramphenicol acetyl transferase (CAT) were transfected by lipofection into primary cultures of chick kidney cells. Transfected chick kidney cells exhibited a high basal expression of the chloramphenicol acetyl transferase gene, reflecting the strong activity of the calbindin-D28K promoter. Expression of the pCaBP2.1 reporter gene was increased 2-fold in the presence of the hormone 1,25(OH)2D3 in the primary kidney cells. Deletion of a 1.42 kb fragment ending -679 base pairs upstream from the transcription start site led to a 2-fold repression in the reporter gene activity by the hormone 1,25(OH)2D3 in primary chick kidney cultures. These preliminary results suggest that both positive and negative elements normally act to regulate the expression of the calbindin-D28K gene in primary chick kidney cells.

Isolation and characterization of a cDNA encoding a chicken beta thyroid hormone receptor

We have isolated and characterized a cDNA encoding a chicken beta homolog of c-erbA, or thyroid hormone receptor (TR). Chicken liver cDNA libraries were screened with a rat TR beta-1 cDNA probe, and several cDNA inserts were isolated and characterized. The sequence of one cDNA predicts a 369-amino-acid open reading frame (ORF), with a protein sequence that possesses 96% identity with that of rat TR beta-1, but only 88% identity with chicken TR alpha. These data indicate that the cDNA likely encodes a beta form of TR that has the expected putative DNA and T3 binding domains. The chicken TR beta (chTR beta) in vitro translated protein binds T3 with high affinity, and binds both the thyroid hormone response element (TRE) from the rat growth hormone gene and the Xenopus vitellogenin A2 gene estrogen response element (ERE), similarly to that of the rat TR beta-1. Northern blot analysis revealed the expression of a 7.0-kb RNA in several tissues including cerebellum, pituitary, kidney, and liver. This chicken liver TR beta cDNA sequence varies in both the 5' and 3' untranslated regions from the chicken kidney TR beta cDNA sequence recently reported (Forrest et al., 1990). The 5' untranslated cDNA sequence divergence occurs near a potential splice site junction of the human TR beta gene, suggesting that this chicken liver cDNA may represent an alternatively spliced RNA product of the chicken TR beta gene.

Ontogeny of the v-erbA oncoprotein from the thyroid hormone receptor: an alteration in the DNA binding domain plays a role crucial for v-erbA function

The avian erythroblastosis virus v-erbA oncogene is imprecisely derived from a cellular gene (c-erbA) encoding a thyroid hormone receptor: the v-erbA protein has sustained both small terminal deletions and internal amino acid sequence changes relative to c-erbA. We report here that one of these missense differences between v- and c-erbA proteins, located in a zinc finger DNA binding domain, has dramatic effects on the biological activities of the encoded protein. Back mutation of the viral coding sequence to resemble c-erbA at this site severely impairs erythroid transformation and produces subtle changes in DNA binding by the encoded protein, suggesting that differences in DNA binding by the viral and cellular proteins may be involved in the activation of v-erbA as an oncogene.

Transcriptional regulation of retinoic acid receptor beta in retinoic acid-sensitive and -resistant P19 embryocarcinoma cells

As in other embryocarcinoma (EC) cell lines retinoic acid (RA) rapidly induces expression of the nuclear retinoic acid receptor (RAR) beta in murine P19 EC cells, while RAR alpha is expressed constitutively. In the RA-resistant P19 EC-derived RAC65 cells, however, there is no such induction and an aberrant (smaller) RAR alpha transcript is expressed. RAR gamma 1 is expressed at low levels in both cell lines. To study the regulation of the RAR beta gene and the possible involvement of RAR alpha protein in transcriptional activation of the RAR beta gene we transfected these cells with a construct containing a 1.6 kb promoter fragment of the human RAR beta gene fused to the CAT gene. Upon transient assays in P19 EC cells CAT activity is enhanced rapidly by RA, to more than 100-fold in a concentration-dependent fashion. On the contrary no activity can be observed in the RA-resistant RAC65 cells; however, co-transfection of hRAR alpha, hRAR beta or hRAR gamma 1 restores the RA-dependent induction of CAT activity. These results clearly show that RAR alpha and RAR gamma 1 can transactivate the RAR beta gene; that RAR beta can stimulate its own expression and that resistance to RA in RAC65 cells is probably due to the altered RAR alpha transcript present in these cells.

Cellular binding proteins of thyroid hormones

Cellular binding proteins of thyroid hormones are present in the cell nucleus, cytosol, cell membrane, and mitochondria. While nuclear binding is proven to mediate hormone action, the exact roles of the other binding sites remain to be established. Nuclear receptor associates with DNA, core histone, and nuclear matrix and preferentially distributes in transcriptionally active chromatin due to interaction with H1 histone. Of particular importance is the binding of nuclear receptor to specific DNA sequences of target genes, termed thyroid-responsive elements. The binding is stabilized by non-receptor nuclear protein. Upon binding thyroid hormone, nuclear receptor is activated through alterations in the steric configuration, leading to changes in the rate of transcription of the target genes. Multiple nuclear receptor forms exist with likely distinct functional roles. Cytosolic thyroid hormone binding proteins are also heterogeneous. One form is under the control of cell metabolism (NADP and NADPH) and it may have a role in transport of the hormone to mitochondria and nucleus. Membrane-linked thyroid hormone binding proteins may have dual functional roles: one is to mediate hormone action and the other is to support active uptake of hormones by cells. Mitochondrial function may be regulated by thyroid hormone through mitochondrial binding sites in cooperation with nuclear receptor-mediated pathway. Further studies are required to elucidate the exact functional roles of non nuclear thyroid hormone binding proteins.

Analysis of oestrogen receptor dimerisation using chimeric proteins

Sequences essential for dimerisation have been identified in the hormone binding domain of the mouse oestrogen receptor by insertional and point mutagenesis and sequence comparisons reveal that equivalent residues may be conserved in other members of the nuclear hormone receptor superfamily. To assess functional compatibility of this region between members of the receptor superfamily, peptide sequences corresponding to the equivalent regions of the human androgen receptor and retinoic acid receptor have been substituted for the dimerisation domain of the mouse oestrogen receptor. The resulting chimeric proteins were analysed for high affinity DNA binding using a gel retardation assay and shown to bind with reduced affinity compared to the wild type oestrogen receptor. The reduction in DNA binding observed may result from the intramolecular incompatibility of functional elements within the hormone binding domain of nuclear hormone receptors.

Identification of ecdysone response elements by analysis of the Drosophila Eip28/29 gene

We have identified ecdysone-response elements (EcREs) by studying regulation of the steroid-responsive Drosophila Eip28/29 gene. First, functional assays of deletion mutants identified large sequence regions required for the response; then a blotting method using the specifically labeled steroid receptor as probe identified receptor-binding regions. Three short receptor-binding regions near Eip28/29 have been identified: Prox and Dist [521 and 2295 nucleotides, respectively, downstream of the poly(A) site] are probably required for the Eip28/29 response in cell lines; Upstream (-440) is unnecessary for that response. We have also demonstrated that an EcRE-containing region from hsp27 contains a receptor-binding site. Each of these four receptor-binding regions functions as an EcRE when placed upstream of an ecdysone nonresponsive promoter and each contains an imperfect palindrome, suggesting the consensus 5'-RG(GT)TCANTGA(CA)CY-3'. Furthermore, a synthetic 15-bp fragment containing an imperfect palindrome similar to the consensus is a fully functional EcRE. The presence of any of the EcREs leads, in the absence of hormone, to depressed gene expression. When hormone is added, it relieves this repression and causes additional activation. The similarity of the EcRE sequence to response elements for estrogen, thyroid hormone, and retinoic acid receptors suggests that the steroid receptors and their signal transduction mechanisms have been strongly and broadly conserved.

The effect of thyroid hormone and glucocorticoids on carp growth hormone-releasing factor (GRF)-induced growth hormone (GH) release in rainbow trout (Oncorhynchus mykiss)

1. The effect of thyroid hormone and glucocorticoids on carp growth hormone-releasing factor (GRF)-induced growth hormone (GH) secretion was studied on rainbow trout using a dispersed pituitary cell culture system. 2. A combined administration of lower doses (0.01 microM) of 3,5,3'-triiodo-L-thyronine (T3) and dexamethasone (Dex) significantly increased spontaneous as well as carp GRF-induced GH release. 3. Lower doses of Dex alone had no effect, and T3 had a marginal effect on GH release. Higher doses of either Dex or T3 potentially reduced GH release. 4. This study indicates an important role of thyroid hormone and/or glucocorticoids in the hypothalamic regulation of GH secretion in fish.

The viral erbA oncogene protein, a constitutive repressor in animal cells, is a hormone-regulated activator in yeast

The v-erbA oncogene is a retrovirus-transduced and altered copy of a cellular gene for a thyroid hormone receptor. In animal cells, the v-erbA protein fails to respond to hormone and acts as a dominant negative allele, inhibiting gene activation normally conferred by the wild-type thyroid hormone receptor. We report here that, unexpectedly, the v-erbA protein acts as a hormone-regulated transcriptional activator in S. cerevisiae. We suggest that the ability of v-erbA protein to function as a transcriptional repressor or an activator is determined by interaction with, or modification by, other cellular factors, and that this phenomenon may be relevant to understanding ligand regulation of the normal thyroid and steroid hormone receptors.

Multiple cell type-specific proteins differentially regulate target sequence recognition by the alpha retinoic acid receptor

Retinoic acid receptors appear to exert profound effects on vertebrate development by regulating the transcription of distinct sets of target genes within different cell types. Several lines of evidence are presented for the existence of multiple, cell type-specific nuclear proteins that function to differentially increase the binding affinity of the alpha retinoic acid receptor for a variety of response elements. These proteins, which we refer to as retinoic acid receptor coregulators, interact with the retinoic acid receptor via a common dimerization interface that overlaps with its ligand binding domain. These observations raise the intriguing possibility that coregulator proteins serve to restrict and/or direct the effects of retinoic acid receptors on patterns of gene expression during development.

The C'-terminal interaction domain of the thyroid hormone receptor confers the ability of the DNA site to dictate positive or negative transcriptional activity

To investigate mechanisms responsible for positive and negative transcriptional control, we have utilized two types of promoters that are differentially regulated by thyroid hormone (T3) receptors. Promoters containing the palindromic T3 response element TCAGGTCA TGACCTGA are positively regulated by the T3 receptor after the administration of T3, whereas otherwise identical promoters containing the estrogen response element TCAGGTCA CTG TGACCTGA can be regulated negatively; converse effects are observed with the estrogen receptor. We describe evidence that the transcriptional inhibitory effects of the T3 or estrogen receptors on the estrogen or T3 response elements, respectively, are imposed by amino acid sequences in the C'-terminal region that colocalize with dimerization and hormone-binding domains and that these sequences can transfer inhibitory functions to other classes of transcription factors. Removal of the C'-terminal dimerization and hormone-binding domains of either the alpha T3 or estrogen receptors permits each receptor to act constitutively to enhance transcription on both T3 and estrogen response elements. It is, therefore, suggested that protein-protein interactions between receptor C' termini limit the subset of DNA binding sites on which transcriptional activation occurs.

Ligand-activated thyroid hormone and retinoic acid receptors inhibit growth factor receptor promoter expression

Thyroid hormone (T3) and retinoic acid (RA) receptors mediate ligand-dependent inhibition of epidermal growth factor (EGF) receptor and c-erbB2/neu promoter activities. Ligand-activated T3 and RA receptors act via a 36 bp 5' fragment of the EGF receptor gene in vivo and, in the presence of nuclear extract, bind with high affinity to this region in vitro. Both ligand binding and DNA binding domains of T3 and RA receptors are required for promoter inhibition. When both receptors are expressed in the presence of a single ligand, inhibition is reversed, indicating that the hormone-activated receptor is competed by the unliganded receptor. These results suggest that ligand regulates transcriptional inhibitory functions of the T3 and RA receptors and describe novel regulation of growth factor receptor gene expression.

Thyroid hormone and DNA binding properties of a mutant c-erbA beta receptor associated with generalized thyroid hormone resistance

We have previously reported a family, Kindred A, with autosomal dominant generalized thyroid hormone resistance in which affected members were found to have a mutation in the carboxy-terminal domain of the c-erbA beta thyroid hormone receptor. In the current study, the thyroid hormone and DNA-binding properties of this mutant receptor were determined using c-erbA beta protein synthesized in vitro. Both the wild-type human placental c-erbA beta and Kindred A receptors bound [125I]-triiodothyronine, although the Kindred A receptor had decreased affinity for the hormone. The affinity for triiodothyronine was 4.5 x 10(9) M-1 and 2.3 x 10(10) M-1 for the mutant and wild-type receptors, respectively. No abnormality of DNA-binding was detected with the Kindred A receptor using a sensitive avidin-biotin DNA-binding assay with DNA fragments containing thyroid hormone response elements. The Kindred A mutant receptor which displays abnormal triiodothyronine-binding but normal DNA-binding activities in vitro acts as a dominant negative inhibitor of thyroid hormone action in man.

Identification of an estrogen response element upstream of the human c-fos gene that binds the estrogen receptor and the AP-1 transcription factor

Transcription of the proto-oncogene c-fos is stimulated by 17 beta-estradiol in estrogen responsive human and rat cells. To understand the molecular mechanisms of estrogen regulation of c-fos gene transcription, the human c-fos gene promoter, with 2.25 Kb of 5'-flanking DNA, was cloned upstream of the bacterial CAT gene and tested for estrogen regulation by transient transfection in HeLa cells. When an expression vector coding for the human estrogen receptor was co-transfected with the fos -CAT reporter, the promoter was found to respond to 17 beta-estradiol. An element responsible for estrogen induction was mapped in a 240 bp region localized 1060 to 1300 bases upstream of the startsite of transcription of the gene. Sequence analysis revealed, clustered in a 19 bp sub-region, a sequence corresponding to an imperfectly palindromic ERE: CGGCAGCGTGACC and two sequences: CTGAG and GTGAC, homologous to the core sequence of AP-1 transcription factor binding sites. A synthetic oligonucleotide reproducing this sub-region binds 'in vitro' both the estrogen receptor and AP-1 factor(s) and confers estrogen-responsivity to the HSV-tk gene promoter. Transcriptional activation by the estrogen receptor is prevented by mutations in the fos ERE that hamper binding of the receptor in vitro. Activation of the c-fos gene promoter in HeLa cells requires the DNA binding domain of the estrogen receptor, and can be achieved independently by the TAF-1 and the TAF-2 transcriptional activation functions of this molecule. A receptor mutant lacking the hormone binding domain can activate the c-fos gene promoter in the absence of estrogen.

Estrogen receptor binding to a DNA response element in vitro is not dependent upon estradiol

Gel shift assays were employed to distinguish between the contribution of 17 beta-estradiol (E2) and a short heating step to the ability of the rat uterine cytosolic estrogen receptor (ER) to bind to the estrogen response element (ERE) from the vitellogenin A2 gene (vitERE). Despite the popularity of models in which the ER is a ligand-activated DNA-binding protein, these studies find that estrogen does not significantly contribute to receptor-DNA complex formation. An avidin-biotin complex with DNA (ABCD) assay was utilized to obtain quantitative measurement of the affinities of the ER for the vitERE and a mutant sequence. Scatchard analysis gave a dissociation constant of 390 +/- 40 pM for the E2-occupied, heated ER to the vitERE. The data fit a one-site model and evidence for cooperatively was not observed. A dissociation constant of 450 +/- 170 pM was obtained for the unoccupied, heated ER, leading to the conclusion that estrogen was not necessary for specific binding to DNA. The percentage of ER capable of binding vitERE varied with each cytosol preparation, ranging from 60 to 100% and estrogen did not appear to affect this variation. Competition against the vitERE with a 2-bp mutant sequence showed a 250-fold lower relative binding affinity of the receptor for the mutant over the vitERE sequence. This ability of the ER to discriminate between target and nonspecific DNA sequences was also not dependent on the presence of estrogen.

The roles of three forms of human thyroid hormone receptor in gene regulation

We have expressed three forms of human thyroid hormone receptor (hTR alpha 1, alpha 2, and beta) in cultured cells by transient transfection. hTR alpha 1 and beta transfected cells showed increased triiodothyronine (T3) binding capacity, but hTR alpha 2 transfected cells did not. When hTR alpha 1 or beta was cotransfected with pUrGH(S), in which a portion of the rat GH 5' flanking region (-236/-147) was ligated into the CAT reporter plasmid (pUTKAT1), T3 increased CAT gene expression. When hTR alpha 2 was cotransfected with pUrGH(S), T3 did not alter CAT gene expression. When hTR alpha 1 or beta was cotransfected with pUrGH(O), in which a synthetic oligonucleotide representing the TRE from the rat GH 5' flanking region (-189/-160) was substituted for the natural enhancer in pUTKAT1, T3 increased CAT gene expression. When hTR alpha 1 and beta were cotransfected with pUrGH(O), induction by T3 was increased. When hTR alpha 2 was cotransfected with hTR alpha 1 or beta, induction by T3 was decreased. These results indicate that hTR alpha 1 and beta function as native TR, that hTR alpha 1 and beta can recognize the same TRE, that hTR alpha 1 and beta can function additively, and that hTR alpha 2 can inhibit the action of hTR alpha 1 and beta.

Tissue-specific expression of the rat growth hormone gene is due to the interaction of multiple promoter, not enhancer, elements

Expression of the rat growth hormone (rGH) gene is highly tissue-specific, being limited to a subset of cells in the anterior pituitary. DNA sequences within 237 bp of the transcription start site of the rGH gene play a major role in directing the expression of this gene in the pituitary. Transfection studies in cultured rat pituitary (GC) cells demonstrate that optimal expression of rGH requires the binding of at least two non-tissue-specific factors whose contribution to rGH expression is dependent on the binding of the pituitary-specific factor, Pit-1. Although the segment of DNA containing the elements to which these factors bind can direct pituitary-specific expression of a gene lacking upstream promoter elements, it cannot confer stimulation to either a heterologous or homologous promoter when placed downstream from the coding sequences. These results suggest that expression of the rGH gene exclusively in the pituitary is due to the activity of a tissue-specific promoter element, not an enhancer.

The lack of transcriptional activation of the v-erbA oncogene is in part due to a mutation present in the DNA binding domain of the protein

Using a transient co-transfection system we have demonstrated that response elements for estrogen (ER), thyroid hormone (TR) and retinoic acid receptors (RAR) are closely related. Thyroid hormone-induced activation of transcription was observed in CV1 cells and not in HeLa cells, suggesting the existence of cell-specific transcription factors necessary for the response. By contrast to its cellular counterpart (c-erbA/cTR alpha) the oncogene protein gag v-erbA is unable to activate gene transcription from different response elements derived from the rat growth hormone (rGH) gene promoter. A chimeric construct consisting of the ER in which the DNA binding domain has been replaced by that of cTR alpha was able to stimulate the reporter gene. In contrast, a construct in which ER DNA binding domain has been replaced by that of gag v-erbA did not activate gene transcription. These results lead us to the conclusion that the mutated DNA binding domain of v-erbA is in part responsible for the lack of transcriptional activation and in repression of gene expression. This is due in large part to the Gly73----Ser mutation which corresponds to the position of one of the three discriminating amino acids that are thought to interact with a specific base of the response element.

Triiodothyronine inhibits transcription from the human growth hormone promoter

Three DNA constructs, the natural human growth hormone gene (hGH-hGH) its 500 bp promoter linked to the chloramphenicol acetyl transferase reporter gene (hGH-CAT), and its structural part linked to the herpes virus thymidine kinase promoter (TK-hGH) were introduced into rat pituitary GC cells by DEAE-dextran transfection. Transient expression was followed as a function of triiodothyronine (T3) concentration. The hGH-CAT expression was specifically inhibited by T3 following a typical dose-response curve while hGH-GH gene expression was not significantly modified. The transient expression of TK-hGH increased as a function of T3 concentration. These results indicate that T3 exerts two opposite effects on hGH gene expression. First, it down-regulates expression by acting on the promoter; second, it up-regulates expression by acting on the structural part of the gene. These action could be due to regulation of transcription and mRNA stabilization, respectively.

Modular structure of a chicken lysozyme silencer: involvement of an unusual thyroid hormone receptor binding site

Silencer elements, by analogy to enhancer elements, function independently of their position and orientation. We show that the chicken lysozyme silencer S-2.4 kb has many other characteristics in common with enhancer elements. The silencer is comprised of modules that independently repress gene activity--repression being increased synergistically when different or identical modules are combined. Repression is effective both on a complete and on a minimal promoter consisting of a TATA box only. One silencer module is bound in vitro by a 75-93 kd protein, termed NeP1; the other can be bound either by the product of the oncogene v-erbA or by the thyroid hormone receptor. This erbA binding site is unusual in that the palindromic sequence is inverted.

Human c-erb A protein expressed in Escherichia coli: changes in hydrophobicity upon thyroid hormone binding

The human c-erb A beta gene sequence was inserted in an Escherichia coli expression vector plasmid. The E. coli cells transformed with this plasmid produced proteins with molecular masses of 52 and 50 kDa. These products bound 3,5,3'-triiodo-L-thyronine (T3) with an affinity constant of 4.3 x 10(9) liter/mol. The order of affinity for iodothyronine analogs was triiodothyroacetic acid greater than T3 greater than 3,5,3'-triiodo-D-thyronine greater than L-thyroxine. Affinity labeling experiments showed that the 50 kDa protein was covalently labeled with [125I]T3, and this was competed by triiodothyroacetic acid, T3, and L-thyroxine (from potent to weaker competitor). The c-erb A protein bound to calf thymus DNA-cellulose and the binding was inhibited by 0.3 M KCl or 10 mM pyridoxal 5'-phosphate. Aqueous two-phase partitioning studies showed that the c-erb A product became less hydrophobic upon T3 or triiodothyroacetic acid binding. The same finding was obtained when T3 bound to partially purified rat liver nuclear thyroid hormone receptor. However, thyroxine binding globulin became more hydrophobic upon T3 binding. Since the T3 molecule partitioned preferentially into the upper polyethylene glycol-rich phase, the alteration of partitioning behavior of thyroxine binding globulin was explained by a simple additive effect of T3. In contrast, the alteration of partitioning behavior of the c-erb A product or receptor reflected a conformational transition upon T3 binding. The c-erb A protein expressed in E. coli showed various characteristics similar to classical thyroid hormone receptor and may be useful in studying the structure and function of the thyroid hormone receptor.

Thyroid hormone receptors from IM-9 cells but not HeLa cells bind to promoters of triiodothyronine-responsive genes

We have used thyroid hormone receptors from two different human cell lines to investigate receptor binding to the promoters of thyroid hormone-responsive genes. Receptors extracted from IM-9 cells or HeLa cells displayed virtually identical affinity and specificity for [125I]triiodothyronine binding. The cells expressed a c-erbA alpha gene in the same relative proportions as the receptor concentrations. Both receptors were bound to DNA-cellulose and could be displaced with increasing concentrations of calf thymus DNA or pBR322 DNA. Relative to pBR322 DNA (designated as 1), binding to the hGH gene promoter was 8.1 +/- 1.1 using the IM-9 cell receptor. With the HeLa cell receptor relative binding was only 1.1 +/- 0.2. Similar relative differences were obtained with the mouse glandular kallikrein gene, mGK-6. In heat stability studies the IM-9 cell receptor was more resistant to heat inactivation than the HeLa receptor. Triiodothyronine receptors with identical hormone binding patterns may require the presence of an unidentified factor(s) which allows correct recognition of regulation sequences within responsive genes.

Role of thyroid hormones in apolipoprotein A-I gene expression in rat liver

To study the regulation of hepatic apo A-I gene expression, we measured synthesis and abundance of cellular apo A-I mRNA and its nuclear precursors in livers of hypothyroid and hyperthyroid rats. In hypothyroid animals, both synthesis and abundance of apo A-I mRNA was reduced to half of control values. After injection of a receptor-saturating dose of triiodothyronine into euthyroid rats, apo A-I gene transcription increased at 20 min, reached a maximum of 179% of control (P less than 0.01) at 3.5 h, and remained elevated for up to 48 h. The abundance of nuclear and total cellular apo A-I mRNA increased at 1 and 2 h, respectively, and exceeded the levels expected from enhanced transcription more than two fold at 24 h after hormone injection. Upon chronic administration of thyroid hormones, levels of nuclear and cytoplasmic apo A-I mRNA remained elevated but transcription of the apo A-I gene fell to 42% of control (P less than 0.01). Thus, thyroid hormones rapidly stimulate apo A-I gene transcription. Posttranscriptional events leading to increased stability of nuclear apo A-I RNA precursors become the principal mechanism for enhanced gene expression in chronic hyperthyroidism and may cause feedback inhibition of apo A-I gene transcription. Our results furthermore imply that the majority of hepatic nuclear apo A-I RNA precursors are degraded in euthyroid animals.

Thyroid hormone induction of Na(+)-K(+)-ATPase and its mRNAs in a rat liver cell line

The expression of mRNAs encoding the alpha- and beta-subunits of Na(+)-K(+)-ATPase (Na(+)-K+ pump) was examined in a rat liver cell line, Clone 9, in various thyroidal states. Northern blot analysis of total RNA isolated from cells incubated in hypothyroid serum-containing medium revealed the expression of mRNAs encoding Na(+)-K(+)-ATPase alpha 1-(mRNA alpha 1) and beta- (mRNA beta) subunits; mRNAs encoding the alpha 2- and alpha 3-subunits were undetectable. There was a discrepancy in the abundance of mRNA alpha 1 relative to mRNA beta such that mRNA alpha 1 exceeded the sum of the multiple mRNA beta bands by approximately 35-fold. 3,3',5-Triiodothyronine (T3) produced a coordinate augmentation of mRNA alpha 1 and mRNA beta contents that was demonstrable within 2 h and preceded the stimulation of Na(+)-K(+)-ATPase activity. After incubation of cells with T3 for 48 h, Na(+)-K(+)-ATPase activity was stimulated by 1.32-fold, whereas mRNA alpha 1 and mRNA beta abundances were increased 1.46- and 2.87-fold, respectively. Treatment of cells for 6 h with 10 micrograms/ml cycloheximide, a concentration sufficient to inhibit protein synthesis by 95%, elicited a 3.5- and 5.1-fold increase in mRNA alpha 1 and mRNA beta content, respectively. Cycloheximide abrogated the stimulatory effect of T3 on mRNA beta abundance, whereas the T3-induced increase in mRNA alpha 1 content was not prevented.(ABSTRACT TRUNCATED AT 250 WORDS)

Sequence-specific DNA binding by the v-erbA oncogene protein of avian erythroblastosis virus

The v-erbA oncogene, a transduced copy of a thyroid hormone receptor, plays an important role in establishment of the transformed cell phenotype induced by avian erythroblastosis virus. The ability of thyroid hormone receptors to bind to specific sites on chromatin and to thereby modify the expression of adjacent target genes is a crucial element in their mechanism of action in the normal cell. The v-erbA protein also bound at high affinity to a set of DNA fragments recognized by the rat thyroid hormone receptor, but the relative affinity of the v-erbA protein for the different binding sites was distinct from that previously reported for the thyroid hormone receptors.

Thyroid hormones induce hemopoietic pluripotent stem cell differentiation toward erythropoiesis through the production of pluripoietin-like factors

We have previously reported that E pluripoietins are produced in mice after a single 20-mg injection of cytosine arabinoside (Ara-C) and that they are able to initiate the determination of hemopoietic pluripotent stem cells (CFU-S) toward the erythrocytic lineage. However, the mechanism of E pluripoietin release is still unclear. Since the stimulating effect of thyroid hormone on erythropoiesis is well known, we postulated a link between this hormone and the E pluripoietins. In previous papers we demonstrated that L-triiodothyronine (LT3) exhibits the capacity of inducing CFU-S differentiation toward erythropoiesis in vitro. Two series of data presented here suggest that LT3 acts indirectly on CFU-S determination by promoting the release of E pluripoietin-like factors. First, the Ara-C injection which induces the production of E pluripoietins in mice also promotes an increase in the LT3 plasma level. Second, medium conditioned with bone marrow cells exposed in vitro for 90 min to LT3 (even though this medium does not contain LT3) has E pluripoietin-like effects, inducing CFU-S differentiation toward the erythrocytic lineage.

Two chicken erythrocyte band 3 mRNAs are generated by alternative transcriptional initiation and differential RNA splicing

The erythrocyte anion transport protein (band 3) mediates two distinct cellular functions: it provides plasma membrane attachment sites for the erythroid cytoskeletal network, and it also functions as the anion transporter between the erythrocyte cytoplasm and extracellular milieu. We previously showed that two chicken band 3 polypeptides are encoded by two different mRNAs with different translation initiation sites. Here we show that these two band 3 mRNAs are transcribed from two separate promoters within a single gene. In addition, the two pre-mRNAs are differentially spliced, leading to fusion with coding exons used in common in the two mRNAs. The chicken erythrocyte band 3 gene is therefore the first example of a gene that has two promoters within a single locus which function equally efficiently in one cell type at the same developmental stage.