Sequences in the proximal 5′ flanking region of the rat neuron-specific enolase (NSE) gene are sufficient for cell type-specific reporter gene expression

We investigated the regulation of the rat neuron-specific enolase gene using a transient transfection approach. Recent transgenic mouse studies have shown that a 1.8-kb segment of the ratNSE gene 5′ flanking region, including the first (noncoding) exon but not the first intron, is able to drive expression of a reporter gene in parallel with endogenousNSE. These data suggest thatcis-acting elements responsible for the spatial and temporal pattern ofNSE gene expression are located within the proximal 1.8 kb of the 5′ flanking sequence. To further investigate this region, we joined the 1.8-kb regulatory cassette to thecat reporter gene and generated a number of constructs in which the flanking sequence was progressively deleted from the 5′ end. These constructs were tested by transient transfection into neuronal and nonneuronal cells, followed by an assay for CAT activity. We found that as little as 255 bp of 5′ flanking sequence was able to confer cell type-specificity on the reporter gene. Further truncation to 120 bp of 5′ sequence resulted in a sharp downregulation of reporter activity in PC12 cells but a significant rise in both Neuro-2A neuroblastoma cells and nonneuronal Ltk- cells, indicating thatcis-acting elements controlling the regulation ofNSE in Ltk-, Neuro-2A, and PC12 cells may lie within the 135 bp region covered by this deletion. This region contains an AP-2 site and an element similar in sequence and position to a motif identified in the proximal promoter region of the neuron-specific peripherin gene. Reduction to 95 bp of 5′ sequence resulted in a slight downregulation of CAT activity in all cell lines tested, and further truncation to 65 bp of 5′ sequence caused a universal reduction to background levels of CAT activity, concomitant with the disruption of the basalNSE promoter. Our results show that the 5′ flanking region of theNSE gene is capable of conferring cell type-specificity on a heterologous gene in transfected cells and that elements responsible for this are located within the proximal 255 bp.     

Cooperative dimerization of the POU domain protein Brn-2 on a new motif activates the neuronal promoter of the human aromatic L-amino acid decarboxylase gene

The neuronal promoter of the human aromatic L-amino acid decarboxylase (AADC) gene contains a perfectly palindromic element (TB) that conforms to the structure of a POU domain protein binding site of the MORE+2 type. The TB motif (located at nts -900/-872 relative to the neuronal cap site) bears striking similarities with the dimeric Pit-1 binding site from growth hormone gene promoter (GH-1), and it enhanced the activity of the minimal tk promoter in transfected SK-N-BE neuroblastoma cells. In transfected COS-7 cells, the expression of a 3xTB-tk-luc was stimulated up to 11-fold by the overexpressed Brn-2 protein. In AADC gene neuronal promoter, we previously characterized a bipartite regulatory element (ONF for octamer-like/NF-Y, nts -86/-57) that binds Brn-2 and NF-Y proteins in a cooperative manner. We now show that both TB and ONF sites participate in the activation of the neuronal promoter by Brn-2. EMSA experiments showed that the recombinant Brn-2 POU domain dimerized on the TB element in a cooperative manner. By site directed mutagenesis of the POU domain of Brn-2, the dimerization interface on the TB element was localized to the hydrophobic pocket of the POU specific domain and the C-terminal part of the POU homeodomain.     

Three different states of the chromatin structure of the mouse peripherin gene

The chromatin structure of the mouse peripherin gene domain was analyzed in peripherin-positive and -negative cell lines. At least nine DNase I hypersensitive sites (HSS) are present within the 20-kb peripherin domain in the mouse neuroblastoma cell lines which express peripherin. Three of them are situated in intron I and intron III, the others being distributed within the 5′ flanking region up to −5.5 kb. The presence of these sites was also investigated in the peripherin chromatin domain of peripherin-negative cell lines. Two other types of HSS distribution were observed along the peripherin gene according to the category of cell considered: constantly peripherin-negative cells, or negative cells arising from transiently peripherin-expressing precursors. From comparison of HSS patterns in these cell lines with those of neuroblastoma cells, it can be predicted that HSS located in the region −1500/+800 bp participate in cell-specific expression of the mouse peripherin gene. © 1996 Wiley-Liss, Inc.