Science exchange logo white
  • Solutions
      Buyers

      We are making R&D services readily available to every organization that seeks to make scientific impact. Learn More

      Providers

      We are changing the way providers access and engage customers to streamline the sale and delivery of R&D services. Learn More

      Industries Agriscience Animal Health Basic Research Biopharmaceutical Chemicals Consumer Health Food Science Medical Devices
      Reproducibility

      We believe that good experiments can and should be independently replicated and validated. Learn More

  • Resources
    Innovation Blog
    Customer Stories
    Events
    Industry Trends
    News
    Product Updates
    Help Center
  • About
    About
    Our Story
    Leadership
    Partners
    Join the Team
  • Contact
  • Log In Sign Up
  • Get a Demo
  • Recent LTR retrotransposon insertion contrasts with waves of non-LTR insertion since speciation in Drosophila melanogaster.

    Proc Natl Acad Sci U S A. 104(27):11340-5. doi: 10.1073/pnas.0702552104. July 3, 2007. View on PubMed.
  • Authors

    Casey Bergman and Bensasson D
  • Abstract

    LTR and non-LTR retrotransposons exhibit distinct patterns of abundance within the Drosophila melanogaster genome, yet the causes of these differences remain unknown. Here we investigate whether genomic differences between LTR and non-LTR retrotransposons reflect systematic differences in their insertion history. We find that for 17 LTR and 10 non-LTR retrotransposon families that evolve under a pseudogene-like mode of evolution, most elements from LTR families have integrated in the very recent past since colonization of non-African habitats ( approximately 16,000 years ago), whereas elements from non-LTR families have been accumulating in overlapping waves since the divergence of D. melanogaster from its sister species, Drosophila simulans ( approximately 5.4 Mya). LTR elements are significantly younger than non-LTR elements, individually and by family, in regions of high and low recombination, and in genic and intergenic regions. We show that analysis of transposable element (TE) nesting provides a method to calculate transposition rates from genome sequences, which we estimate to be one to two orders of magnitude lower than those that are based on mutation accumulation studies. Recent LTR integration provides a nonequilibrium alternative for the low population frequency of LTR elements in this species, a pattern that is classically interpreted as evidence for selection against the transpositional increase of TEs. Our results call for a new class of population genetic models that incorporate TE copy number, allele frequency, and the age of insertions to provide more powerful and robust inferences about the forces that control the evolution of TEs in natural populations.

Science exchange logo white

  • Facebook
  • Twitter
  • LinkedIn

Solutions

  • Buyers
  • Providers
  • Reproducibility

Industries

  • Agriscience
  • Animal Health
  • Basic Research
  • Biopharmaceutical
  • Chemicals
  • Consumer Health
  • Food Science
  • Medical Devices

Resources

  • Innovation Blog
  • Customer Stories
  • Events
  • Industry Trends
  • News
  • Product Updates

About

  • Our Story
  • Leadership
  • Partners
  • Join the Team

Support

  • Contact Us
  • Help Center
  • Trust
  • Terms of Use
  • Privacy Policy

Copyright © 2021 Science Exchange, Inc. All rights reserved.