An Evolutionarily Conserved Region in the Second lntron of the Human Nestin Gene Directs Gene Exmession to CNS Progenitor Cells and to Early Neural Ciest Cells

Authors

  • Carina Lothian,

    1. Department of Cell and Molecular Biology, Medical Nobel Institute, Karolinska Institute, S-17177 Stockholm, Sweden.
    2. Department of Woman and Child Health, Karolinska Institute, S-17177 Stockholm, Sweden
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  • Urban Lendahl

    Corresponding author
    1. Department of Cell and Molecular Biology, Medical Nobel Institute, Karolinska Institute, S-17177 Stockholm, Sweden.
    • U. Lendahl, as above

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Abstract

Central nervous system (CNS) progenitor cells transiently proliferate in the embryonic neural tube and give rise to neurons and glial cells. A characteristic feature of the CNS progenitor cells is expression of the intermediate filament nestin and it was previously shown that the rat nestin second intron functions as an enhancer, directing gene expression to CNS progenitor cells. In this report we characterize the nestin enhancer in further detail. Cloning and sequence analysis of the rat and human nestin second introns revealed local domains of high sequence similarity in the 3′ portion of the introns. Transgenic mice were generated with the most conserved 714 bp in the 3′ portion of the intron, or with the complete, 1852 bp, human second intron, coupled to the reporter gene lacZ. The two constructs gave a very similar nestin-like expression pattern, indicating that the important control elements reside in the 714 bp element. Expression was observed starting in embryonic day (E)7.5 neural plate, and at E10.5 CNS progenitor cells throughout the neural tube expressed lacZ. At E12.5, lacZ expression was more restricted and confined to proliferating regions in the neural tube. An interesting difference, compared to the rat nestin second intron, was that the human intron at E10.5 mediated lacZ expression also in early migrating neural crest cells, which is a site of endogenous nestin expression. In conclusion, these data show that a relatively short, evolutionarily conserved region is sufficient to control gene expression in CNS progenitor cells, but that the same region differs between rodents and primates in its capacity to control expression in neural crest cells.

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