Gene Targeting Using a Promoterless Gene Trap Vector ("Targeted Trapping") Is an Efficient Method to Mutate a Large Fraction of Genes

A powerful tool for postgenomic analysis of mammalian gene function is gene targeting in mouse ES cells. We report that homologous recombination using a promoterless gene trap vector ("targeting trapping") yields targeting frequencies averaging above 50%, a significant increase compared wi...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2005-09, Vol.102 (37), p.13188-13193
Main Authors: Friedel, Roland H., Plump, Andrew, Lu, Xiaowei, Spilker, Kerri, Jolicoeur, Christine, Wong, Karen, Venkatesh, Tadmiri R., Yaron, Avraham, Hynes, Mary, Chen, Bin, Okada, Ami, McConnell, Susan K., Rayburn, Helen, Tessier-Lavigne, Marc
Format: Article
Language:English
Subjects:
Animals
Antibiotic resistance
Biological Sciences
Cell lines
Embryo, Mammalian - cytology
Exons
Gene expression
Gene Expression Profiling
Gene targeting
Gene Targeting - methods
Genes
Genetic screening
Genetic Vectors
Genetics
Genomes
Genomics - methods
Introns
Methods
Mice
Mutagenesis, Insertional - methods
Mutation
Recombination, Genetic
Stem Cells - metabolism
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Summary:A powerful tool for postgenomic analysis of mammalian gene function is gene targeting in mouse ES cells. We report that homologous recombination using a promoterless gene trap vector ("targeting trapping") yields targeting frequencies averaging above 50%, a significant increase compared with current approaches. These high frequencies appear to be due to the stringency of selection with promoterless constructs, because most random insertions are silent and eliminated by drug selection. The promoterless design requires that the targeted gene be expressed in ES cells at levels exceeding a certain threshold (which we estimate to be ≈1% of the transferrin receptor gene expression level, for the secretory trap vector used here). Analysis of 127 genes that had been trapped by random (nontargeted) gene trapping with the same vector shows that virtually all are expressed in ES cells above this threshold, suggesting that targeted and random trapping share similar requirements for expression levels. In a random sampling of 130 genes encoding secretory proteins, about half were expressed above threshold, suggesting that about half of all secretory genes are accessible by either targeted or random gene trapping. The simplicity and high efficiency of the method facilitate systematic targeting of a large fraction of the genome by individual investigators and large-scale consortia alike.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0505474102