PLoS ONE (Jan 2012)

Application of a novel strategy of engineering conditional alleles to a single exon gene, Sox2.

  • Nikolaos Mandalos,
  • Marannia Saridaki,
  • Jessica Lea Harper,
  • Anastasia Kotsoni,
  • Peter Yang,
  • Aris N Economides,
  • Eumorphia Remboutsika

DOI
https://doi.org/10.1371/journal.pone.0045768
Journal volume & issue
Vol. 7, no. 9
p. e45768

Abstract

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BackgroundThe Conditional by Inversion (COIN) method for engineering conditional alleles relies on an invertible optimized gene trap-like element, the COIN module, for imparting conditionality. The COIN module contains an optimized 3' splice site-polyadenylation signal pair, but is inserted antisense to the target gene and therefore does not alter transcription, until it is inverted by Cre recombinase. In order to make COIN applicable to all protein-coding genes, the COIN module has been engineered within an artificial intron, enabling insertion into an exon.Methodology/principal findingsTherefore, theoretically, the COIN method should be applicable to single exon genes, and to test this idea we engineered a COIN allele of Sox2. This single exon gene presents additional design challenges, in that its proximal promoter and coding region are entirely contained within a CpG island, and are also spanned by an overlapping transcript, Sox2Ot, which contains mmu-miR1897. Here, we show that despite disruption of the CpG island by the COIN module intron, the COIN allele of Sox2 (Sox2(COIN)) is phenotypically wild type, and also does not interfere with expression of Sox2Ot and miR1897. Furthermore, the inverted COIN allele of Sox2, Sox2(INV) is functionally null, as homozygotes recapitulate the phenotype of Sox2(βgeo/βgeo) mice, a well-characterized Sox2 null. Lastly, the benefit of the eGFP marker embedded in the COIN allele is demonstrated as it mirrors the expression pattern of Sox2.Conclusions/significanceOur results demonstrate the applicability of the COIN technology as a method of choice for targeting single exon genes.