The beta-subunit gene of TSH is specifically expressed in thyrotrope cells of the anterior pituitary gland. To define the particular TSH beta-subunit gene sequences responsible for tissue-specific expression, TSH beta promoter fragments were assessed for promoter activity by gene transfer into TSH-expressing thyrotropic tumor cells (TtT-97). Previous studies have shown that the murine TSH beta gene promoter was more efficiently used in TtT-97 cells compared to other pituitary-derived cells or nonpituitary fibroblasts and that a 191-basepair DNA sequence of the 5' flanking region between -271 and -80 was sufficient for maximal promoter activity in thyrotropes. Further deletional analysis within this region has localized the area responsible for expression in thyrotropes to a 37-basepair region between -117 and -80 up-stream of the major transcriptional initiation site. DNase-I protection assays demonstrated that this functionally defined 5' flanking area, in addition to the adjacent sequences immediately up-stream and down-stream, interacts with protein factors present in nuclear extracts from TtT-97 tumor cells. When fused to a heterologous promoter, fragments derived from the region between -271 and -80 exhibited cell-specific activity, although this was not conferred solely by the TSH beta promoter fragment from -117 to -80. Heterologous promoter activity was further stimulated when fragments containing the areas from -271 or -201 to -77 were used, suggesting combinatorial cis interactions between these regions of the TSH beta promoter. DNase-I protection studies suggest that there are multiple protein-binding domains in the mouse TSH beta 5' flanking sequence. Only the more proximal domains, which encompass important promoter elements, appear to be required for efficient expression in thyrotropes, whereas other more up-stream sites of protein interaction may be involved in regulatory aspects of TSH beta gene expression.
Expression of the rat PRL (rPRL) gene is highly restricted to pituitary lactotroph cells and is induced by the cAMP-dependent protein kinase A (PKA) pathway. Current data indicate that this PKA effect requires at least one of the redundant pituitary-specific elements of the proximal rPRL promoter, suggesting the involvement of the pituitary-specific transcription factor, GHF-1/Pit-1. To directly determine whether GHF-1 is necessary and sufficient to mediate the PKA activation of the rPRL promoter, we established a cotransfection reconstitution assay whereby the activity of an intact and site-specific mutants of the (-425 to +73) rPRL promoter-luciferase reporter gene was reconstituted by cotransfecting expression vectors encoding for either the PKA beta catalytic subunit, GHF-1, or both, into HeLa nonpituitary cells. Cotransfection of PKA beta alone significantly stimulated rPRL promoter activity in HeLa cells in a GHF-1-independent manner, and this PKA beta effect was mapped to the most proximal GHF-1 site [footprint (FP) I; -67/-36]. Site-specific alterations of either FP II (-130/-120), or of the basal transcription element (BTE; -112/-80), did not significantly affect the PKA beta response. As expected, the transactivation effect of cotransfected GHF-1 mapped to the GHF-1/Pit-1 binding sites, FP I and/or FP III, of the rPRL promoter. Finally, cotransfection of PKA beta and GHF-1 resulted in a marked synergistic response of the rPRL promoter, and this response also localized to the FP I site. These data confirm not only that GHF-1/Pit-1 and the FP I site are involved in mediating the PKA response, but also imply that a distinct and possibly ubiquitous factor is involved by binding to FP I and functionally interacting with GHF-1 to modulate PKA beta regulation of the rPRL promoter.
Expression of the TSH beta subunit gene is restricted to the thyrotroph cells of the anterior pituitary. Previously we identified several AT-rich DNA elements within the murine (m) TSH beta 5'-flanking region, denoted as D1 (-253 to -227), P4 (-142 to -131), P3 (-126 to -112), P2 (-106 to -98), and P1 (-76 to -68) which bind thyrotroph-specific factor(s). These sites are related to, but distinct from GHF-1 and LSF-1 binding sites, which restrict GH and PRL gene expression to pituitary somatotrophs and lactotrophs, respectively. To determine whether different pituitary cell types contain related factors capable of activating the mTSH beta promoter, cell-free transcription studies were performed using extracts from GH4 rat pituitary somatomammotroph cells. AI-through the endogenous mTSH beta gene is not expressed in GH4 cells, in vitro transcription of the mTSH beta promoter, normalized to the Rous sarcoma virus internal control, revealed faithful transcription initiation from the authentic mTSH beta CAP sites in GH4 but not in HeLa cell extracts. Cell-free transcription analysis of mTSH beta 5'-deletion mutants revealed consistent promoter activity with deletion to position -46 but complete loss of activity when deleted to position -9. To better define the specific factors in pituitary somatomammotrophs which interact with and activate the mTSH beta promoter, DNase I protection and gel-shift studies were performed using extracts from GC rat pituitary somatomammotroph cells and DNA affinity-purified lactotroph-specific transcription factor, LSF-1, required for rat PRL promoter activity, and purified from GC cells. These cells contain a factor(s) which binds to thyrotroph-specific elements of the mTSH beta promoter. These studies also show that LSF-1 binds the D1 and proximal thyrotroph-specific elements of the mTSH beta promoter and is capable of reconstituting the trans-activation of the mTSH beta promoter in HeLa nonpituitary cell extracts in vitro. Conversely, nuclear factors present in TtT-97 murine thyrotrophs bind the proximal lactotroph-specific elements on the rPRL promoter. This in vitro transcription assay provides a means to biochemically dissect the trans-activation of the mTSH beta promoter and to determine the functional overlap of distinct pituitary cell-specific factors in regulating GH, PRL, and TSH beta gene expression.
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