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.
Although the myelin proteolipid protein gene (Plp1) is highly expressed in the central nervous system encoding the most abundant myelin protein in oligodendrocytes, it is also expressed in other tissues, including testis. Transgenic studies with mice that harbor Plp1-lacZ fusion genes suggest that Leydig cells are the source of Plp1 gene expression in testis. However, virtually nothing is known about Plp1 gene regulation in Leydig cells, which is the focus of this study. The first intron contains both positive and negative regulatory elements that are important in regulating Plp1 gene expression in oligodendrocytes. To test whether these elements are functional in Leydig cells, a battery of Plp1-lacZ fusion genes with partial deletion of Plp1 intron 1 sequence was transfected into the mouse Leydig cell line, TM3. Results presented here suggest an enhancer, which is very potent in oligodendrocytes, is only nominally active in TM3 cells. The intron also contains several negative regulatory elements that are operative in TM3 cells. Moreover a new exon (exon 1.2) was identified within the first ‘intron’ resulting in novel splice variants in TM3 cells. Western blot analysis suggests that these splice variants, along with those containing another alternatively spliced exon (exon 1.1) derived from intron 1 sequence, give rise to multiple Plp1 gene products in the mouse testis.
Myelin proteolipid protein gene (Plp1) expression is temporally regulated in brain, which peaks during the active myelination period of CNS development. Previous studies with Plp1-lacZ transgenic mice demonstrated that (mouse) Plp1 intron 1 DNA is required for high levels of expression in oligodendrocytes. Deletion-transfection analysis revealed the intron contains a single positive regulatory element operative in the N20.1 oligodendroglial cell line, which was named ASE (antisilencer/enhancer) based on its functional properties in these cells. To investigate the role of the ASE in vivo, the element was deleted from the native gene in mouse using a Cre/lox strategy. While removal of the ASE from Plp1-lacZ constructs profoundly decreased expression in transfected oligodendroglial cell lines (N20.1 and Oli-neu), the element was dispensable to achieve normal levels of Plp1 gene expression in mouse during development (except perhaps at postnatal day 15) and throughout the remyelination period following cuprizone-induced (acute) demyelination. Thus, it is possible that the ASE is nonfunctional in vivo, or that loss of the ASE from the native gene in mouse can be compensated for by the presence of other regulatory elements within the Plp1 gene.
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