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Gene Conversion02:08

Gene Conversion

Other than maintaining genome stability via DNA repair, homologous recombination plays an important role in diversifying the genome. In fact, the recombination of sequences forms the molecular basis of genomic evolution. Random and non-random permutations of genomic sequences create a library of new amalgamated sequences. These newly formed genomes can determine the fitness and survival of cells. In bacteria, homologous and non-homologous types of recombination lead to the evolution of new...
Gene Conversion02:08

Gene Conversion

Other than maintaining genome stability via DNA repair, homologous recombination plays an important role in diversifying the genome. In fact, the recombination of sequences forms the molecular basis of genomic evolution. Random and non-random permutations of genomic sequences create a library of new amalgamated sequences. These newly formed genomes can determine the fitness and survival of cells. In bacteria, homologous and non-homologous types of recombination lead to the evolution of new...
Exon Recombination02:32

Exon Recombination

The evolution of new genes is critical for speciation. Exon recombination, also known as exon shuffling or domain shuffling, is an important means of new gene formation. It is observed across vertebrates, invertebrates, and in some plants such as potatoes and sunflowers. During exon recombination, exons from the same or different genes recombine and produce new exon-intron combinations, which might evolve into new genes. 
Exon shuffling follows “splice frame rules.” Each exon has three reading...
Conservative Site-specific Recombination and Phase Variation02:53

Conservative Site-specific Recombination and Phase Variation

Because the DNA segments are cut and reorganized in a direction-specific manner, site-specific recombination has emerged as an efficient genetic engineering technique. Flippase and Cyclization recombinases or Flp and Cre, respectively, are two members of the tyrosine recombinase family derived from bacteriophages, that are used to mediate site-specific DNA insertions, deletions, and targeted expression of proteins in mammalian cell lines.
The recognition sites for Cre recombinase called LoxP...
Viral Recombination00:57

Viral Recombination

Cells are sometimes infected by more than one virus at once. When two viruses disassemble to expose their genomes for replication in the same cell, similar regions of their genomes can pair together and exchange sequences in a process called recombination. Alternatively, viruses with segmented genomes can swap segments in a process called reassortment.
Overview of Transposition and Recombination02:13

Overview of Transposition and Recombination

Transposons make up a significant part of genomes of various organisms. Therefore, it is believed that transposition played a major evolutionary role in speciation by changing genome sizes and modifying gene expression patterns. For example, in bacteria, transposition can lead to conferring antibiotic resistance. Movement of transposable elements within the genetic pool of pathogenic bacteria can aid in transfer of antibiotic-resistant genetic elements. In eukaryotes, transposons can carry out...

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Related Experiment Video

Updated: Jun 14, 2026

Molecular Evolution of the Tre Recombinase
12:02

Molecular Evolution of the Tre Recombinase

Published on: May 29, 2008

Mutation and the evolution of recombination.

N H Barton1

  • 1Institute of Science and Technology, , Am Campus 1, A-3400 Klosterneuburg, Austria. n.barton@ed.ac.uk

Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences
|March 24, 2010
PubMed
Summary

Selection for recombination is driven by mutation and random genetic drift. Random drift can maintain genetic variation and promote adaptation by breaking negative linkage disequilibrium, even in large populations.

Area of Science:

  • Evolutionary biology
  • Population genetics

Background:

  • Classical view posits selection depends on mutation for adaptation.
  • Standing genetic variation relies on a balance between selection and mutation.
  • Recombination is favored if it resolves negative associations among selected alleles.

Purpose of the Study:

  • To investigate the role of mutation and random drift in driving selection for recombination.
  • To explore mechanisms maintaining genetic variation and facilitating adaptation.
  • To compare deterministic and stochastic explanations for recombination rates.

Main Methods:

  • Analysis of interactions between beneficial and deleterious mutations at unlinked loci.
  • Application of the infinitesimal model to theoretical population genetics.

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Following the Dynamics of Structural Variants in Experimentally Evolved Populations
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Following the Dynamics of Structural Variants in Experimentally Evolved Populations

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Last Updated: Jun 14, 2026

Molecular Evolution of the Tre Recombinase
12:02

Molecular Evolution of the Tre Recombinase

Published on: May 29, 2008

Following the Dynamics of Structural Variants in Experimentally Evolved Populations
04:52

Following the Dynamics of Structural Variants in Experimentally Evolved Populations

Published on: February 3, 2023

  • Comparison of deterministic and stochastic models of selection and mutation.
  • Main Results:

    • Random drift, not solely mutation rate, can generate negative linkage disequilibria.
    • Selection for recombination can occur even in large populations due to random drift.
    • Local selection fluctuations and gene flow can drive adaptation via recombination.

    Conclusions:

    • Random drift is a significant factor in promoting recombination and adaptation.
    • The genomic mutation rate alone may not fully explain observed recombination rates.
    • Understanding linkage disequilibrium dynamics is crucial for evolutionary adaptation.