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Site-specific recombination. Site-specific recombination alters gene order, which would not happen during general recombination. Site-specific recombination. Site-specific recombination moves specialized nucleotide sequences (mobile genetic elements) between nonhomologous sites within a genome.
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Site-specific recombination Site-specific recombination alters gene order, which would not happen during general recombination.
Site-specific recombination • Site-specific recombination moves specialized nucleotide sequences (mobile genetic elements) between nonhomologous sites within a genome. • All types of mobile genetic elements occasionally move or rearrange neighboring DNA sequences of the host cell genome.
Site-specific recombination • The relics of site-specific recombination (repeated DNA sequences) can be found in many vertebrate chromosomes (45% in human). • The translocation of mobile genetic elements gives rise to spontaneous mutations in organisms.
Site-specific recombination • Site-specific recombination is guided by recombination enzymes that recognize short, specific nucleotide sequences present on one or both of the recombining DNA molecules.
There are two types of site-specific recombination • Transpositional site-specific recombination does not involve the formation of heteroduplex DNA between mobile DNA segments and its host, so a short homologous sequence is not required. • Conservative site-specific recombination requires the formation of heteroduplex DNA so a short homologous sequence is required.
Transpositional site-specific recombination Most transposons move only very rarely (10-5)
DNA-only transposon • DNA-only transposons exist as DNA throughout its life cycle. The translocating DNA segment is directly cut out of the donor DNA and joined to the target site by a transposase.
DNA-only transposons : cut-and-paste transposition (dimer) NHEJ or HEJ Because staggered breaks were generated during insertion
Some DNA-only transposons use replicative transposition, a variation of the cut-and-paste mechanism
Retroviral-like retrotransposons Retrovirus and retroviral-like retrotransposons use the same mechanism to move themselves.
The propagation of retroviral-like retrotransposons transcription
Integrase made the integration of retroviral-like retrotransposons
Nonretroviral retrotransposons The RNA and reverse transcriptase have a much direct role in the recombination event for nonretroviral retrotransposons.
Nonretroviral retrotransposons • Nonretroviral retrotransposons left large number of repeated sequences in human genome. These repeats are mostly mutated and truncated so they cannot transpose anymore. • L1element (LINE, long interspersed nuclear element) belongs to this group. It carries its own reverse transcriptase and endonuclease.
The transposition of nonretroviral retrotransposons (this part is not fully understood yet)
Nonretroviral retrotransposons • Other nonretroviral retrotransposons like Alu element lacks reverse transcriptase or endonuclease can still propagate themselves by using those enzymes from host or other nonretroviral retrotransposons.
Genomes of eukaryotic organisms are littered with relics of transposons
Genomes of eukaryotic organisms are littered with relics of transposons • In human, DNA-only and retroviral-like transposons have been inactive in the human lineage since very long ago. In contrast, some of the nonretroviral retrotransposons are still moving (2%). • In mouse, both types of retrotransposons are still moving and are responsible for 10 percent of new mutations.
Conservative site-specific recombination The best example of the conservative site-specific recombination is bacteriophage lambda.
Because integrase remained bound with DNA just like topoisomerase, the action of lambda integrase does not require ATP.
