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14.11: Coping with the Dangers of Rampant Transpositions

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    Most organisms do not have the high transposon load that we have. Given a general tendency of transposons to insert at random into new DNA loci, how come we exist at all? Isn’t the danger of transposition into essential gene sequences magnified by the possibility of multiple simultaneous transpositions of elements that have been generated by cut-and-paste and (especially) replicative mechanisms? Indeed, transposons have been found in genes that have been rendered inactive as a result. An obvious explanation for how we have survived transposon activity is that most transposition occurs in the greater-than-90% of the genome that does not code for proteins. Another explanation is that eukaryotic organisms have two copies of every gene, so if one is inactive, the other may sustain us. Beyond this, several mechanisms exist to silence a transposon after transposition has occurred, mitigating the dangers of rampant transposition. If a transposition is not lethal (e.g., its integration does not disrupt an activity essential to life), the cell and organisms can survive the event. In time, mutations at the ends of transposons or in the genes needed for transposition would eventually render them inactive.

    Finally, there may be more direct curbs on transposition. Recall that the piRNAs we encountered earlier participate in silencing transposons by blocking their export from the nucleus and silencing transposon genes. There is also evidence that siRNAs target transposon transcripts for destruction. In sum, transposition effects are limited by inherent mutations and, more directly, by mechanisms that limit transposition and thus genetic damage.

    Nevertheless, many species tolerate high transposon loads; if they were ipso facto deleterious, we wouldn’t see them. Some of these transposons have evolved gene regulatory functions, but setting these aside, a high transposition count in eukaryotes is largely neutral, simply increasing a pool of diversity that, over time, could support the selection of new genotypes and phenotypic characteristics. Thus, mobile DNA elements may be neither selfish nor junk. Check out Not Junk After All? and Eulogy for Junk DNA and the link below for more.

    256 Transposons - Junk or Not?

    This page titled 14.11: Coping with the Dangers of Rampant Transpositions is shared under a not declared license and was authored, remixed, and/or curated by Gerald Bergtrom.

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