PuSH - Publication Server of Helmholtz Zentrum München

Vierl, F. ; Kaur, M.* ; Götz, M.

Non-codon optimized PiggyBac transposase induces developmental brain aberrations: A call for in vivo analysis.

Front. Cell Dev. Biol. 9:698002 (2021)
Publ. Version/Full Text Research data DOI
Open Access Gold
Creative Commons Lizenzvertrag
In this perspective article, we briefly review tools for stable gain-of-function expression to explore key fate determinants in embryonic brain development. As the piggyBac transposon system has the highest insert size, a seamless integration of the transposed sequence into the host genome, and can be delivered by transfection avoiding viral vectors causing an immune response, we explored its use in the murine developing forebrain. The original piggyBac transposase PBase or the mouse codon-optimized version mPB and the construct to insert, contained in the piggyBac transposon, were introduced by in utero electroporation at embryonic day 13 into radial glia, the neural stem cells, in the developing dorsal telencephalon, and analyzed 3 or 5 days later. When using PBase, we observed an increase in basal progenitor cells, often accompanied by folding aberrations. These effects were considerably ameliorated when using the piggyBac plasmid together with mPB. While size and strength of the electroporated region was not correlated to the aberrations, integration was essential and the positive correlation to the insert size implicates the frequency of transposition as a possible mechanism. We discuss this in light of the increase in transposing endogenous viral vectors during mammalian phylogeny and their role in neurogenesis and radial glial cells. Most importantly, we aim to alert the users of this system to the phenotypes caused by non-codon optimized PBase application in vivo.
Altmetric
Additional Metrics?
Edit extra informations Login
Publication type Article: Journal article
Document type Review
Keywords Cortex Development ; Genome Integration ; Gyrification ; Neural Stem Cells ; Transposon ; Viral Vectors; Endogenous Retroviruses; Lentiviral Vectors; Cerebral-cortex; Radial Glia; Stem; Cells; Pax6; Polymicrogyria; Transcription; Integration
ISSN (print) / ISBN 2296-634X
e-ISSN 2296-634X
Quellenangaben Volume: 9, Issue: , Pages: , Article Number: 698002 Supplement: ,
Publisher Frontiers
Publishing Place Lausanne
Reviewing status Peer reviewed
Grants ERC