Regulation of myelin proteolipid protein (Plp) gene expression is tightly controlled, both spatially and temporally. Previously, we have shown with transgenic mice that a Plp-lacZ fusion gene (which includes the entire sequence for Plp intron 1 DNA) is regulated in a similar manner to endogenous Plp gene expression. Furthermore, by deletion-transfection analyses using assorted Plp-lacZ constructs with partial deletion of Plp intron 1 sequences, we have shown that the first intron possesses an antisilencer region that is capable of overcoming repression mediated by two distinct regions located elsewhere within intron 1 DNA. Here, we report the ability of various fragments encompassing the antisilencer region to restore -galactosidase activity when inserted into Plp-lacZ constructs, which originally exhibited low levels of -galactosidase activity. Additional constructs were generated to test the effects of these antisilencer-containing fragments in constructs that are missing either one or both of the negative regulatory regions that are overridden during antisilencing. Transfection analyses, in conjunction with protein-DNA binding assays, suggest that several nuclear factors are necessary for derepression of Plp gene activity in an oligodendroglial cell line. Moreover, either the "core" or complete antisilencing region can act in an additive or synergistic fashion when multiple copies are inserted into the Plp-lacZ constructs.
The myelin proteolipid protein (Plp) gene is expressed in oligodendrocytes and encodes the most abundant protein found in mature CNS myelin. Expression of the gene is dynamic and peaks during the active myelination period of CNS development. The surge in Plp gene activity during this period has been purported to be mediated by a positive regulatory region located within the first intron. This region, designated ASE for antisilencer/enhancer, is located approximately 1 kb downstream of exon 1 sequences and encompasses nearly 100 bp. However, neither the critical nucleotides within this region, nor the associated DNA-binding proteins have been identified. In the present study, DNase I footprinting analysis demonstrated widespread protection of the region on both the coding and non-coding strands suggesting that multiple transcription factors are likely involved. Targeting of putative DNAprotein binding sites contained within the ASE by gel shift, transfection and mutagenesis studies revealed the importance of several AP-1-like binding sites in governing high levels of Plp gene expression in oligodendrocytes. Our results suggest that factors, which bind to these sites, form the core of a multiprotein complex that assembles on the ASE and ultimately affects the temporal regulation of the gene in oligodendrocytes.
A unique combined luminescence assay for firefly (Photinus pyralis) luciferase and beta-galactosidase (beta-gal) reporter gene products is described. Luciferase and beta-gal activities are determined with the same aliquot of cell lysate prepared from cells contransfected with both reporter genes, thereby reducing manual labor and increasing experimental accuracy. With the Dual-Light assay system, luciferase activity is measured first with an enhanced luciferase assay, followed by quantitation of beta-gal with Galacton-Plus chemiluminescent substrate and Sapphire-II enhancer. Highly sensitive detection of luciferase (2 fg) and beta-gal (8 fg) is achieved with a dynamic range over seven orders of magnitude of enzyme concentration. Comparative analysis of both independent and combined (Dual-Light) detection methods for cells contransfected with luciferase and beta-gal reporter genes is also described.
The myelin proteolipid protein (Plp) gene encodes the most abundant protein found in mature CNS myelin. Expression of the gene is regulated spatiotemporally, with maximal expression occurring in oligodendrocytes during the myelination period of CNS development. Plp gene expression is tightly controlled. Misregulation of the gene in humans can result in the dysmyelinating disorder Pelizaeus-Merzbacher disease, and in transgenic mice carrying a null mutation or extra copies of the gene can result in a variety of conditions, from late onset demyelination and axonopathy, to severe early onset dysmyelination. In this study we have examined the effects of Plp intron 1 DNA in mediating proper developmental expression of Plp-lacZ fusion genes in transgenic mice. Our results reveal the importance of Plp intron 1 sequences in instigating the expected surge in Plp-lacZ gene activity during (and following) the active myelination period of brain development. Transgene expression was also detected in the testis (Leydig cells), however, the presence or absence of Plp intron 1 sequences had no effect on the temporal profile in the testis. Surprisingly, expression of the transgene missing Plp intron 1 DNA was always higher in the testis, as compared to the brain, in all of the transgenic lines generated.
The use of immortalized cells has been instrumental as a tool in which to study gene regulation. However it is crucial to understand the status of a given cell line, especially when investigating the regulation of genes whose expression is developmentally regulated. Several immortalized cell lines have been derived from primary cultures of mouse oligodendrocytes. Two such cell lines – N20.1 and Oli-neu – were characterized here in terms of their relative expression of myelin genes at both the mRNA and protein level. Analysis of the splice isoforms expressed by the myelin proteolipid protein (Plp1), myelin basic protein (Mbp), and 2’,3’-cyclic nucleotide 3’-phosphodiesterase (Cnp) genes, along with the relative amount of protein expressed by these genes suggest that the cell lines are representative of immature oligodendrocytes, although Oli-neu cells appear to be further along the differentiation pathway compared to N20.1 cells. Previous studies have shown that the developmental increase in Plp1 gene expression that occurs during the active myelination period is governed by transcription regulatory elements present within the first intron. The responsiveness of one of these elements – the so-called antisilencer/enhancer (ASE) – was investigated in both cell lines. Results presented here suggest that the ASE has a much more potent effect in Oli-neu cells. Thus, the two cell lines appear to be at different stages and will be useful as a means to study transcription regulatory elements whose influence changes during development.
The myelin proteolipid protein (Plp) gene is expressed in oligodendrocytes and encodes the most abundant protein (approximately 50%) present in mature myelin from the central nervous system (CNS). Plp gene activity is low to nonexistent early in development but sharply increases, concurrently with the active myelination period of CNS development. Work from our laboratory suggests that the temporal regulation of Plp gene expression in mice is mediated by a positive regulatory element located within Plp intron 1 DNA. We have termed this regulatory element/region ASE (for antisilencer/enhancer). The ASE is situated approximately 1 kb downstream of exon 1 DNA and encompasses nearly 100 bp. To understand the mechanisms by which the ASE augments Plp gene expression in oligodendrocytes, Plp-lacZ constructs were generated and transfected into a mouse oligodendroglial cell line (N20.1). Results presented here demonstrate that upstream regulatory elements in the Plp promoter/5'-flanking DNA are not required for ASE activity; the ASE worked perfectly well when the thymidine kinase (TK) promoter was substituted for the Plp promoter. However, the relative location of the ASE appears to be important. When placed upstream of 2.4 kb of Plp 5'-flanking DNA, or downstream of the lacZ expression cassette, the ASE was no longer effective. Thus, the ASE might have to be in the context of the intron in order to function. To begin to identify the crucial nucleotides within the ASE, orthologous sequences from rat, human, cow, and pig Plp genes were swapped for the mouse sequence. Results presented here demonstrate that the orthologous sequence from rat can substitute for the mouse ASE, unlike those from human, cow, or pig.
The myelin proteolipid protein gene (Plp) is expressed primarily in oligodendrocytes. Yet how the gene remains repressed in nonexpressing cells has not been defined, and potentially could cause adverse effects in an organism if the mechanism for repression was impaired. Previous studies suggest that the first intron contains element(s), which suppress expression in nonexpressing cells, although the identity of these elements within the 8 kb intron was not characterized. Here we report the localization of multiple negative regulatory elements that repress Plp gene expression in nonexpressing cells (+/+ Li). Two of these elements (regions) correspond to those used by Plp expressing cells (N20.1), whilst another acts in a cell type-specific manner (i.e. operational in +/+ Li liver cells, but not N20.1 cells). By gel-shift and DNase I footprinting analyses, the factor(s) that bind to the cell type-specific negative regulatory region appear to be far more abundant in +/+ Li cells than in N20.1 cells. Thus, Plp gene repression is mediated through the combinatorial action of both ÔgeneralÕ and cell type-specific negative regulatory elements. Additionally, repression in +/+ Li cells cannot be overcome via an antisilencer/enhancer element, which previously has been shown to function in N20.1 cells.
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