Repetitive sequences in complex genomes: structure and evolution

J Jurka, VV Kapitonov, O Kohany… - Annu. Rev. Genomics …, 2007 - annualreviews.org
J Jurka, VV Kapitonov, O Kohany, MV Jurka
Annu. Rev. Genomics Hum. Genet., 2007annualreviews.org
Eukaryotic genomes contain vast amounts of repetitive DNA derived from transposable
elements (TEs). Large-scale sequencing of these genomes has produced an
unprecedented wealth of information about the origin, diversity, and genomic impact of what
was once thought to be “junk DNA.” This has also led to the identification of two new classes
of DNA transposons, Helitrons and Polintons, as well as several new superfamilies and
thousands of new families. TEs are evolutionary precursors of many genes, including RAG1 …
Abstract
Eukaryotic genomes contain vast amounts of repetitive DNA derived from transposable elements (TEs). Large-scale sequencing of these genomes has produced an unprecedented wealth of information about the origin, diversity, and genomic impact of what was once thought to be “junk DNA.” This has also led to the identification of two new classes of DNA transposons, Helitrons and Polintons, as well as several new superfamilies and thousands of new families. TEs are evolutionary precursors of many genes, including RAG1, which plays a role in the vertebrate immune system. They are also the driving force in the evolution of epigenetic regulation and have a long-term impact on genomic stability and evolution. Remnants of TEs appear to be overrepresented in transcription regulatory modules and other regions conserved among distantly related species, which may have implications for our understanding of their impact on speciation.
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