Abstract
Random gene trapping is the application of insertional mutagenesis techniques that are conventionally used to inactivate protein-coding genes in mouse embryonic stem (ES) cells. Transcriptionally silent genes are not effectively targeted by conventional random gene trapping techniques, thus we herein developed an unbiased poly (A) trap (UPATrap) method using a Tol2 transposon, which preferentially integrated into active genes rather than silent genes in ES cells. To achieve efficient trapping at transcriptionally silent genes using random insertional mutagenesis in ES cells, we generated a new diphtheria toxin (DT)-mediated trapping vector, DTrap that removed cells, through the expression of DT that was induced by the promoter activity of the trapped genes, and selected trapped clones using the neomycin-resistance gene of the vector. We found that a double-DT, the dDT vector, dominantly induced the disruption of silent genes, but not active genes, and showed more stable integration in ES cells than the UPATrap vector. The dDT vector disrupted differentiated cell lineage genes, which were silent in ES cells, and labeled trapped clone cells by the expression of EGFP upon differentiation. Thus, the dDT vector provides a systematic approach to disrupt silent genes and examine the cellular functions of trapped genes in the differentiation of target cells and development.
Highlights
Mutagenesis in cells or animals is one of the genetic methodologies employed to elucidate the molecular functions of genes regulating biological processes
Random gene trapping is the application of insertional mutagenesis techniques that are conventionally used to inactivate protein-coding genes in mouse embryonic stem (ES) cells (Stanford, Cohn, & Cordes, 2001)
Moloney murine leukemia virus (MMLV) vectors were previously shown to preferentially integrate into transcriptionally active genes (Scherdin, Rhodes, & Breindl, 1990; Wu, Li, Crise, & Burgess, 2003), and we demonstrated that the unbiased poly (A) trap (UPATrap) retrovirus vector frequently integrated into active genes, but only approximately 10% of all trapped genes, which were transcriptionally silent in murine ES cells (Mayasari et al, 2012)
Summary
Random gene trapping is the application of insertional mutagenesis techniques that are conventionally used to inactivate protein-coding genes in mouse embryonic stem (ES) cells. Silent genes are not effectively targeted by conventional random gene trapping techniques, we developed an unbiased poly (A) trap (UPATrap) method using a Tol transposon, which preferentially integrated into active genes rather than silent genes in ES cells. To achieve efficient trapping at transcriptionally silent genes using random insertional mutagenesis in ES cells, we generated a new diphtheria toxin (DT)-mediated trapping vector, DTrap that removed cells, through the expression of DT that was induced by the promoter activity of the trapped genes, and selected trapped clones using the neomycin-resistance gene of the vector. KEYWORDS cell lineage ablation, diphtheria toxin, embryonic stem cells, gene trap, Tol transposon
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