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Molecular Evolution 2 Recombination & Transposition
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Recombination larger scale chromosome rearrangements
Recombination is an integral part of evolution which allows favourable & unfavourable mutations to be separated by shuffling the genes
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Outline Recombination Homologous recombination
Non-homologous recombination Site-specific recombination Transposition DNA transposition RNA trnasposition
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Recombination Homologous recombination
exchange between homologous DNA sequences; accomplished by a set of enzymes function: meiosis I of eukaryotic cell division, double-strand break repair, telomere maintenance replication is an integral part of the reaction, allowing reformation of functional replication forks after any fork blocking event
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Homologous recombination
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Outline Non-homologous recombination
strand exchange between DNA sequences with very little homology Site-specific recombination Transposition
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Site-specific recombination
accomplished by specific recombinases that catalyse the breaking and rejoining of DNA segments function: controlling gene expression, increase genetic diversity replication is NOT part of the reaction
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Site-specific recombination (SSR)
Important distinguishing Feature Conservative SSR process involves Protein-DNA covalent intermediates
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Site-specific recombination
Fig1 from Site-specific recombination by Anca Segall [
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Site-specific recombination (SSR)
2 structurally unrelated families Tyrosine recombinases (l integrase family) Serine recombinases (resolvase-DNA invertase recombinases) Site-specific recombination by David J Sherratt [
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Site-specific recombination
Recombination core sites of S and Y recombinases FIG 1: Site-specific recombination by David J Sherratt [
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Site-specific recombination
Serine recombinase tyrosine recombinase FIG 3: Site-specific recombination by David J Sherratt [
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Transposition Discrete sequences (transposable elements or TEs) in the genome that have the ability to translocate or copy itself across to other parts of the genome without any requirement for sequence homology
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Transposable elements move from place to place in the genome
1930s Marcus Rhoades and 1950s Barbara McClintock – transposable elements in corn 1983 McClintock received Nobel Prize Found in all organisms Most 50 – 10,000 bp May be present hundreds of times in a genome
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TEs can generate mutations in adjacent genes
TE in Maize Figure 13.25 Fig Genes VII by B. Lewin
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Transposition can occur via
RNA intermediate Class I TEs - transpose via a RNA intermediate Retroposons retrotransposons DNA intermediate - transpose via a DNA intermediate Class II TEs - catalysed by the enzyme transposase
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DNA intermediate Class II TEs IS elements and transposons
bounded by terminal inverted repeats (TIR) Prokaryotic IS elements (e.g. IS10, Ac/Ds, mariner) encode only transposase sequences eukaryotic transposons encode additional genes such as antibiotic resistance genes
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DNA intermediate
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Transposons encode transposase enzymes that catalyze events of transposition
Figure a Fig a
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RNA intermediate Class I TEs – transpose via a RNA intermediate
Retroposons are structurally similar to mRNA retrotransposons are structurally similar to retroviruses and are bound by long terminal repeats (LTR)
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Class I TEs encode a reverse transciptase-like enzyme
Retroposon Poly-A tail at 3’ end of RNA-like DNA strand retrotransposon Long terminal repeat (LTRs) oriented in same direction on either end of element Figure a Fig a
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Figure b Fig b
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Transposons are now classified into 5 families
On the basis of their transposase proteins 1) DDE-transposases 2) RT/En transposases (reverse transcriptase/endonuclease) 3) Tyrosine (Y) transposases 4) Serine (S) transposases 5) Rolling circle (RC) or Y2 transposases Nature Rev Mol. Cell Biol (Nov2003) 4(11):865-77)
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DDE-transposases Fig1 from Nature Rev Mol. Cell Biol (Nov2003) 4(11):865-77)
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RT/En transposases (reverse transcriptase/endonuclease
Fig1 from Nature Rev Mol. Cell Biol (Nov2003) 4(11):865-77)
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Tyrosine (Y) transposases
Fig1 from Nature Rev Mol. Cell Biol (Nov2003) 4(11):865-77)
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Serine (S) transposases
Fig1 from Nature Rev Mol. Cell Biol (Nov2003) 4(11):865-77)
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Rolling circle (RC) or Y2 transposases
Fig1 from Nature Rev Mol. Cell Biol (Nov2003) 4(11):865-77)
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Common mechanism of transposition
Transposase required Regulation of transposase expression controls transposition Catalytic domain of transposase involved in transphosphorylation step that initiates DNA cleavage & strand transfer.
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Common mechanism of transposition
2 sequential steps Site specific cleavage of DNA at the end of TE Complex of transposase-element ends brought to DNA target where strand transfer is carried out by covalent joining of 3’end of TE to target DNA
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Figure b
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Common mechanism of transposition
Fig 15.14 Fig 15.10
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