The Otx2 homeoprotein regulates expression from the gonadotropin-releasing hormone proximal promoter

The GnRH gene is expressed exclusively in a highly restricted population of approximately 800 neurons in the mediobasal hypothalamus in the mouse. The Otx2 homeoprotein has been shown to colocalize with GnRH in embryonic mouse brain. We have identified a highly conserved bicoid-related Otx target sequence within the proximal promoter region of the GnRH gene from several species. This element from the rat GnRH promoter binds baculovirus-expressed Otx2 protein and Otx2 protein in nuclear extracts of a hypothalamic GnRH-expressing neuronal cell line, GT1-7. Transient transfection assays indicate that the GnRH promoter Otx/bicoid site is required for specific expression of the GnRH gene in GT1-7 cells and that it can confer specificity to a neutral Rous sarcoma virus (RSV) promoter in GT1-7 cells but not in NIH3T3 cells. Overexpression of mouse Otx2 in GT1-7 cells induces expression of a GnRH promoter plasmid, an effect that is dependent upon the Otx binding site. Thus, the GnRH proximal promoter is regulated by the Otx2 homeoprotein. Finally, we have now demonstrated the presence of Otx2 protein in the GnRH neurons of the adult mouse hypothalamus. These data suggest that Otx2 is important in the development of the GnRH neuron and/or in the maintenance of GnRH expression in the adult mouse hypothalamus.     

The protein kinase C pathway acts through multiple transcription factors to repress gonadotropin-releasing hormone gene expression in hypothalamic GT1-7 neuronal cells

The GnRH gene uses two well-defined regions to target expression to a small population of hypothalamic GnRH neurons: a 173-bp proximal promoter and a 300-bp enhancer localized at approximately -1800 to -1500 bp from the start site. Interaction of multiple factors with the GnRH enhancer and promoter is required to confer neuron-specific expression in vivo and in cells in culture. In addition, the expression of the GnRH gene is regulated by numerous neurotransmitters and hormones. Several of these effectors act through membrane receptors to trigger the protein kinase C pathway, and 12-O-tetradecanoyl phorbol-13-acetate (TPA), a modulator of this pathway, has been shown to suppress GnRH gene expression through the promoter. We find that TPA suppresses expression through the GnRH enhancer as well as the promoter. In the enhancer, an Oct-1 binding site, a Pbx/Prep binding site, Msx/Dlx binding sites, and a previously unidentified protein-binding element at -1793, all contribute to TPA suppression. TPA treatment leads to decreased binding of Oct-1 and Pbx1a/Prep to their sites. However, a complex formed by GT1-7 nuclear extracts on the -1793 site is not affected by TPA treatment. It is known that cooperative interaction among multiple factors is necessary for GnRH gene expression; thus, one mechanism by which TPA suppresses GnRH gene expression is to disengage some of these factors from their cis-regulatory elements.     

Cloning of GT box-binding proteins: a novel Sp1 multigene family regulating T-cell receptor gene expression.

Analysis of a T-cell antigen receptor (TCR) alpha promoter from a variable gene segment (V) revealed a critical GT box element which is also found in upstream regions of several V alpha genes, TCR enhancer, and regulatory elements of other genes. This element is necessary for TCR gene expression and binds several proteins. These GT box-binding proteins were identified as members of a novel Sp1 multigene family. Two of them, which we term Sp2 and Sp3, were cloned. Sp2 and Sp3 contain zinc fingers and transactivation domains similar to those of Sp1. Like Sp1, Sp2 and Sp3 are expressed ubiquitously, and their in vitro-translated products bind to the GT box in TCR V alpha promoters. Sp3, in particular, also binds to the Sp1 consensus sequence GC box and has binding activity similar to that of Sp1. As the GT box has also previously been shown to play a role in gene regulation of other genes, these newly isolated Sp2 and Sp3 proteins might regulate expression not only of the TCR gene but of other genes as well.     

Episodic activation of the rat GnRH promoter: role of the homeoprotein oct-1

Recent reports demonstrate that the rat GnRH promoter is activated in an episodic fashion in immortalized GnRH neurons, but little information is available on molecular processes that contribute to this phenomenon. In this study, we dissected the regions of the rat GnRH promoter that mediate these effects by testing a series of 5' deletion luciferase reporter constructs on the pattern of photonic emissions from single, living GT1-7 GnRH neuronal cells. Deletion analysis revealed that the region -2012/-1597 that contains the neuron-specific enhancer (NSE) was required for the elaboration of pulses of GnRH promoter activity. The importance of this region was supported by observations that episodic reporter activity could be transferred to a neutral nonpulsatile promoter (Rous sarcoma virus, RSV(180)). Immunoneutralization of Oct-1 as well as mutation of an octamer binding site located at -1787/-1783 (AT-a site) blocked the pulsatile GnRH promoter activity in GT1-7 neuronal cells. Taken together, our findings indicate that episodic GnRH gene expression is a promoter-dependent phenomenon, which is mediated by Oct-1 interaction with regulatory elements in the NSE region.     

Analysis of a tissue-specific enhancer: ARF6 regulates adipogenic gene expression.

The molecular basis of adipocyte-specific gene expression is not well understood. We have previously identified a 518-bp enhancer from the adipocyte P2 gene that stimulates adipose-specific gene expression in both cultured cells and transgenic mice. In this analysis of the enhancer, we have defined and characterized a 122-bp DNA fragment that directs differentiation-dependent gene expression in cultured preadipocytes and adipocytes. Several cis-acting elements have been identified and shown by mutational analysis to be important for full enhancer activity. One pair of sequences, ARE2 and ARE4, binds a nuclear factor (ARF2) present in extracts derived from many cell types. Multiple copies of these elements stimulate gene expression from a minimal promoter in preadipocytes, adipocytes, and several other cultured cell lines. A second pair of elements, ARE6 and ARE7, binds a separate factor (ARF6) that is detected only in nuclear extracts derived from adipocytes. The ability of multimers of ARE6 or ARE7 to stimulate promoter activity is strictly adipocyte specific. Mutations in the ARE6 sequence greatly reduce the activity of the 518-bp enhancer. These data demonstrate that several cis- and trans-acting components contribute to the activity of the adipocyte P2 enhancer and suggest that ARF6, a novel differentiation-dependent factor, may be a key regulator of adipogenic gene expression.     

Numerous nuclear proteins bind the long control region of human papillomavirus type 16: a subset of 6 of 23 DNase I-protected segments coincides with the location of the cell-type-specific enhancer.

The long control region of the human papillomavirus type 16 genome is 856 base pairs (bp) long. It contains a cell-type-specific enhancer, a glucocorticoid response element, and sequences mediating the response to the viral gene products of open reading frame E2; all three regulate the promoter P97. We mapped binding sites of trans-acting proteins relevant for the cell-type-specific enhancer and other cis-acting elements by DNase I footprint experiments with nuclear extracts from HeLa cells. Throughout the human papillomavirus type 16 long control region 23 footprints protect 557 of 900 bp. Nine footprints fall into a 400-bp segment that was previously identified to contain the cell-type-specific enhancer. Variations of the protein concentration in the footprint reaction do not affect six of these nine footprints. At high protein concentrations, three footprints fuse to a 106-bp protected region, suggesting that this segment specifically binds several proteins of lower affinity or abundance. Unexpectedly, extracts from human MCF7 and mouse 3T3 cells, in which the enhancer is inactive, give footprints identical to those obtained with HeLa extracts. Seven footprints contain the sequence 5'-TTGGC-3'. Footprint competition experiments suggest that factor NFI binds to these seven motifs. Competition with cloned oligonucleotides in transfections suggests that these elements contribute to the enhancer function. Subcloning identifies a 232-bp fragment between positions 7524 and 7755 as sufficient for full enhancer activity. Several of the six footprinted elements on this segment may cooperate functionally, since subclones of this region show decreased or no cell-type-specific enhancer function.     

The myosin light chain enhancer and the skeletal actin promoter share a binding site for factors involved in muscle-specific gene expression.

The myosin light chain (MLC) 1/3 enhancer (MLC enhancer), identified at the 3' end of the skeletal MLC1/3 locus, contains a sequence motif that is homologous to a protein-binding site of the skeletal muscle alpha-actin promoter. Gel shift, competition, and footprint assays demonstrated that a CArG motif in the MLC enhancer binds the proteins MAPF1 and MAPF2, previously identified as factors interacting with the muscle regulatory element of the skeletal alpha-actin promoter. Transient transfection assays with constructs containing the chloramphenicol acetyltransferase reporter gene demonstrated that a 115-bp subfragment of the MLC enhancer is able to exert promoter activity when provided with a silent nonmuscle TATA box. A point mutation at the MAPF1/2-binding site interferes with factor binding and abolishes the promoter activity of the 115-bp fragment. The observation that an oligonucleotide encompassing the MAPF1/2 site of the MLC enhancer alone cannot serve as a promoter element suggests that additional factor-binding sites are necessary for this function. The finding that MAPF1 and MAPF2 recognize similar sequence motifs in two muscle genes, simultaneously activated during muscle differentiation, implies that these factors may have a role in coordinating the activation of contractile protein gene expression during myogenesis.